jcuny/These_linjie_JC
1
0
Fork 0
Code Issues Pull Requests Projects Releases Wiki Activity
e993d2ba3a
These_linjie_JC/thesis/thesis.bbl

2979 lines
120 KiB
Plaintext
Raw Blame History

This file contains invisible Unicode characters

This file contains invisible Unicode characters that are indistinguishable to humans but may be processed differently by a computer. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

\begin{thebibliography}{100}
\bibitem{Cotton1964}
{\sc F~A Cotton, NF~Curtis, CB~Harris, BFG Johnson, SJ~Lippard, JT~Mague,
WR~Robinson, and JS~Wood}.
\newblock {\bf Mononuclear and polynuclear chemistry of rhenium (III): its
pronounced homophilicity}.
\newblock {\em Science}, {\bf 145}(3638):1305--1307, 1964.
\bibitem{Haberland2013}
{\sc Hellmut Haberland}.
\newblock {\em Clusters of atoms and molecules: theory, experiment, and
clusters of atoms}, ~{\bf 52}.
\newblock Springer Science \& Business Media, 2013.
\bibitem{Schmid1988}
{\sc G{\"u}nter Schmid}.
\newblock {\bf Metal clusters and cluster metals}.
\newblock {\em Polyhedron}, {\bf 7}(22-23):2321--2329, 1988.
\bibitem{Hakkinen2002}
{\sc Hannu H{\"a}kkinen, Michael Moseler, and Uzi Landman}.
\newblock {\bf Bonding in Cu, Ag, and Au clusters: relativistic effects,
trends, and surprises}.
\newblock {\em Phys. Rev. Lett.}, {\bf 89}(3):033401, 2002.
\bibitem{Dahl1963}
{\sc L.~F. Dahl and R.~E. Rundle}.
\newblock {\bf The crystal structure of dimanganese decacarbonyl
Mn$_2$(CO)$_{10}$}.
\newblock {\em Acta Crystallogr.}, {\bf 16}(5):419--426, 1963.
\bibitem{Fucugauchi1994}
{\sc L~Fucugauchi, S~Millan, A~Mondragon, and M~Solache-Rios}.
\newblock {\bf Chemical effects of (n, $\gamma$) nuclear reaction on
(Mo$_6$Cl$_8$)Cl$_4$}.
\newblock {\em J. Radioanal. Nucl. Chem.}, {\bf 178}(2):437--442, 1994.
\bibitem{Sutton2016}
{\sc Paul~W. Sutton and Lawrence~F. Dahl}.
\newblock \href{https://doi.org/10.1021/ja00978a016}{{\bf The Molecular
structure of Co$_3$(CO)$_9$CCH$_3$. A tricyclic organocobalt complex
containing a metal-coordinated triply bridging aliphatic carbon atom}}.
\newblock {\em J. Am. Chem. Soc.}, {\bf 89}(2):261--268, 1967.
\newblock PMID: 22175962.
\bibitem{Schnepf2002}
{\sc Andreas Schnepf and Hansgeorg Schnöckel}.
\newblock {\bf Metalloid aluminum and gallium clusters: element modifications
on the molecular scale?}
\newblock {\em Angew. Chem. Int. Ed.}, {\bf 41}(19):3532--3554, 2002.
\bibitem{Fassler2004}
{\sc Thomas~F. F{\"a}ssler and Stephan~D. Hoffmann}.
\newblock
\href{https://onlinelibrary.wiley.com/doi/abs/10.1002/anie.200460427}{{\bf
Endohedral zintl ions: intermetalloid clusters}}.
\newblock {\em Angew. Chem. Int. Ed.}, {\bf 43}(46):6242--6247, 2004.
\bibitem{Stegmaier2011}
{\sc Saskia Stegmaier and Thomas~F Fässler}.
\newblock {\bf A Bronze Matryoshka: The Discrete Intermetalloid Cluster
[Sn@Cu$_{12}$@Sn$_{20}$]$_{12}^-$ in the Ternary Phases
A$_{12}$Cu$_{12}$Sn$_{21}$ (A= Na, K)}.
\newblock {\em J. Am. Chem. Soc.}, {\bf 133}(49):19758--19768, 2011.
\bibitem{Farges1981}
{\sc J~Farges, MF~De~Feraudy, B~Raoult, and G~Torchet}.
\newblock {\bf Structure and temperature of rare gas clusters in a supersonic
expansion}.
\newblock {\em Surf. Sci.}, {\bf 106}(1-3):95--100, 1981.
\bibitem{Kroto1991c60}
{\sc Harry~W Kroto, AW~Allaf, and SP~Balm}.
\newblock {\bf C$_{60}$: Buckminsterfullerene}.
\newblock {\em Chem. Rev.}, {\bf 91}(6):1213--1235, 1991.
\bibitem{Blase2008}
{\sc X~Blase, A~San~Miguel, A~Perez, et~al.}
\newblock {\bf Cluster assembled silicon networks}.
\newblock In {\em Nanosilicon}, pages 79--113. Elsevier, 2008.
\bibitem{Siedschlag2004}
{\sc Christian Siedschlag and Jan-Michael Rost}.
\newblock {\bf Small rare-gas clusters in soft x-ray pulses}.
\newblock {\em Phys. Rev. Lett.}, {\bf 93}(4):043402, 2004.
\bibitem{Rapacioli2005stacked}
{\sc M~Rapacioli, Florent Calvo, Fernand Spiegelman, C~Joblin, and DJ~Wales}.
\newblock {\bf Stacked clusters of polycyclic aromatic hydrocarbon molecules}.
\newblock {\em J. Phys. Chem. A}, {\bf 109}(11):2487--2497, 2005.
\bibitem{Zhen2018}
{\sc Junfeng Zhen, Tao Chen, and Alexander~GGM Tielens}.
\newblock {\bf Laboratory photochemistry of pyrene clusters: An efficient way
to form large PAHs}.
\newblock {\em Astrophys. J.}, {\bf 863}(2):128, 2018.
\bibitem{Dyson2000}
{\sc Paul~J Dyson and J~Scott McIndoe}.
\newblock {\em Transition metal carbonyl cluster chemistry}, ~{\bf 2}.
\newblock CRC Press, 2000.
\bibitem{Colton1965}
{\sc R~Colton and R.~L. Martin}.
\newblock {\bf Magnetic evidence for trinuclear clusters in rhenium (IV)
chloride}.
\newblock {\em Nature}, {\bf 205}(4968):239--240, 1965.
\bibitem{Yoon2020}
{\sc Jiho Yoon, Edouard Lesne, Kornelia Sklarek, John Sheckelton, Chris Pasco,
Stuart S.~P. Parkin, Tyrel~M. McQueen, and Mazhar~N. Ali}.
\newblock {\bf {Anomalous thickness-dependent electrical conductivity in van
der Waals layered transition metal halide, Nb$_3$Cl$_8$}}.
\newblock {\em J. Phys. Condens. Matter}, {\bf {32}}({30}), {JUL 15} {2020}.
\bibitem{Berden1996}
{\sc Giel Berden, W~Leo Meerts, Michael Schmitt, and Karl Kleinermanns}.
\newblock {\bf High resolution UV spectroscopy of phenol and the hydrogen
bonded phenol-water cluster}.
\newblock {\em J. Chem. Phys.}, {\bf 104}(3):972--982, 1996.
\bibitem{Buck2000}
{\sc Udo Buck and Friedrich Huisken}.
\newblock {\bf Infrared spectroscopy of size-selected water and methanol
clusters}.
\newblock {\em Chem. Rev.}, {\bf 100}(11):3863--3890, 2000.
\bibitem{Harris1984}
{\sc IA~Harris, RS~Kidwell, and JA~Northby}.
\newblock {\bf Structure of charged argon clusters formed in a free jet
expansion}.
\newblock {\em Phys. Rev. Lett.}, {\bf 53}(25):2390, 1984.
\bibitem{Ayuela1993}
{\sc A~Ayuela, JM~L{\'o}pez, JA~Alonso, and V~Luana}.
\newblock {\bf Theoretical study of NaCl clusters}.
\newblock {\em Z. Phys. D}, {\bf 26}(1):213--215, 1993.
\bibitem{Calvo2018}
{\sc Florent Calvo}.
\newblock {\bf Melting and structural transitions}.
\newblock {\em Frontiers of Nanoscience}, {\bf 12}:295--331, 2018.
\bibitem{Alonso2000}
{\sc JA~Alonso}.
\newblock {\bf Electronic and atomic structure, and magnetism of
transition-metal clusters}.
\newblock {\em Chem. Rev.}, {\bf 100}(2):637--678, 2000.
\bibitem{Margenau2013}
{\sc Henry Margenau and Neil~R Kestner}.
\newblock {\em Theory of Intermolecular Forces: International Series of
Monographs in Natural Philosophy}, ~{\bf 18}.
\newblock Elsevier, 2013.
\bibitem{Kimura1991}
{\sc Keisaku Kimura}.
\newblock {\bf Magnetic properties of iron: from clusters to bulk}.
\newblock {\em Physics Letters A}, {\bf 158}(1-2):85--88, 1991.
\bibitem{Jortner1992}
{\sc Joshua Jortner}.
\newblock {\bf Cluster size effects}.
\newblock {\em Z. Phys. D}, {\bf 24}(3):247--275, 1992.
\bibitem{Boulon2014}
{\sc Julien Boulon, Isabelle Braud, S{\'e}bastien Zamith, Pierre Labastie, and
Jean-Marc LHermite}.
\newblock {\bf Experimental nanocalorimetry of protonated and deprotonated
water clusters}.
\newblock {\em J. Chem. Phys.}, {\bf 140}(16):164305, 2014.
\bibitem{Schmidt2012}
{\sc M~Schmidt and B~von Issendorff}.
\newblock {\bf Gas-phase calorimetry of protonated water clusters}.
\newblock {\em J. Chem. Phys.}, {\bf 136}(16):164307, 2012.
\bibitem{Hock2009}
{\sc C~Hock, M~Schmidt, R~Kuhnen, C~Bartels, L~Ma, H~Haberland, and B~v
Issendorff}.
\newblock {\bf Calorimetric observation of the melting of free water
nanoparticles at cryogenic temperatures}.
\newblock {\em Phys. Rev. Lett.}, {\bf 103}(7):073401, 2009.
\bibitem{Faraday1857}
{\sc Michael Faraday}.
\newblock {\bf The Bakerian Lecture.—Experimental relations of gold (and
other metals) to light}.
\newblock {\em Philosophical Transactions of the Royal Society of London}, {\bf
147}:145--181, 1857.
\bibitem{Kulmala2000}
{\sc Markku Kulmala, Liisa Pirjola, and Jyrki~M M{\"a}kel{\"a}}.
\newblock {\bf Stable sulphate clusters as a source of new atmospheric
particles}.
\newblock {\em Nature}, {\bf 404}(6773):66--69, 2000.
\bibitem{Wang2008}
{\sc Hui Wang, Ned~S Wingreen, and Ranjan Mukhopadhyay}.
\newblock {\bf Self-organized periodicity of protein clusters in growing
bacteria}.
\newblock {\em Phys. Rev. Lett.}, {\bf 101}(21):218101, 2008.
\bibitem{Depalma2014}
{\sc Joseph~W DePalma, Douglas~J Doren, and Murray~V Johnston}.
\newblock {\bf Formation and growth of molecular clusters containing sulfuric
acid, water, ammonia, and dimethylamine}.
\newblock {\em J. Phys. Chem. A}, {\bf 118}(29):5464--5473, 2014.
\bibitem{Katakuse1985}
{\sc I~Katakuse, T~Ichihara, Y~Fujita, T~Matsuo, T~Sakurai, and H~Matsuda}.
\newblock {\bf Mass distributions of copper, silver and gold clusters and
electronic shell structure}.
\newblock {\em Int. J. Mass Spectrom. Ion Processes}, {\bf 67}(2):229--236,
1985.
\bibitem{Posthumus2009}
{\sc Jan Posthumus}.
\newblock {\em Molecules and clusters in intense laser fields}.
\newblock Cambridge University Press, 2009.
\bibitem{Castleman2009}
{\sc AW~Castleman~Jr and SN~Khanna}.
\newblock {\bf Clusters, superatoms, and building blocks of new materials}.
\newblock {\em J. Phys. Chem. C}, {\bf 113}(7):2664--2675, 2009.
\bibitem{Henglein1989}
{\sc Arnim Henglein}.
\newblock {\bf Non-metallic silver clusters in aqueous solution: stabilization
and chemical reactions}.
\newblock {\em Chem. Phys. Lett.}, {\bf 154}(5):473--476, 1989.
\bibitem{Korobeishchikov2005}
{\sc NG~Korobeishchikov, AE~Zarvin, V~Zh Madirbaev, and RG~Sharafutdinov}.
\newblock {\bf Condensation of argon, monosilane and their mixtures in a pulse
free jet}.
\newblock {\em Plasma Chem. Plasma Process.}, {\bf 25}(4):319--349, 2005.
\bibitem{Xu2020}
{\sc Qiaofei Xu, Baijie Xu, Hui Kong, Peipei He, Jiawei Wang, Thirumurthy
Kannan, Pengtao Ma, Jingping Wang, and Jingyang Niu}.
\newblock {\bf {Synthesis and Characterization of a Crown-Shaped 36-Molybdate
Cluster and Application in Catalyzing Knoevenagel Condensation}}.
\newblock {\em {Inorg. Chem.}}, {\bf {59}}({15}):{10665--10672}, {AUG 3}
{2020}.
\bibitem{Tian2018}
{\sc Tian Xiao-Lin, Zhao Yu-Hong, Tian Jin-Zhong, and Hou Hua}.
\newblock {\bf {Effects of interatomic potential on precipitation sequences of
medium Al concentration in Ni75AlxV25-x alloys}}.
\newblock {\em {Acta Phys. Sin.}}, {\bf {67}}({23}), {DEC 5} {2018}.
\bibitem{Deng2018}
{\sc Y.~H. Deng, D.~D. Wen, Y.~Li, J.~Liu, and P.~Peng}.
\newblock {\bf {Local atomic structures of amorphous Pd$_{80}$Si$_{20}$ alloys
and their configuration heredity in the rapid solidification}}.
\newblock {\em {Philos. Mag.}}, {\bf {98}}({31, A}):{2861--2877}, {NOV 2}
{2018}.
\bibitem{Rapacioli2019}
{\sc Mathias Rapacioli, Fernand Spiegelman, and Nathalie Tarrat}.
\newblock {\bf {Evidencing the relationship between isomer spectra and melting:
the 20-and 55-atom silver and gold cluster cases}}.
\newblock {\em {Phys. Chem. Chem. Phys.}}, {\bf {21}}({45}):{24857--24866},
{DEC 7} {2019}.
\bibitem{Castleman1978}
{\sc A.~W CASTLEMAN and P.~M. HOLLAND}.
\newblock {\bf Molecular-properties of small clusters and their relationship to
understanding nucleation phenomena}.
\newblock In {\em Abstracts of papers of the american chemical society}, ~{\bf
175}, pages 74--74. Am. Chem. Soc. 1155 16TH ST, NW, WASHINGTON, DC 20036,
1978.
\bibitem{Castleman1978the}
{\sc AW~Castleman~Jr, Paul~M Holland, and Robert~G Keesee}.
\newblock {\bf The properties of ion clusters and their relationship to
heteromolecular nucleation}.
\newblock {\em J. Chem. Phys.}, {\bf 68}(4):1760--1767, 1978.
\bibitem{Zhong2000}
{\sc Q~Zhong and AWa Castleman}.
\newblock {\bf An ultrafast glimpse of cluster solvation effects on reaction
dynamics}.
\newblock {\em Chem. Rev.}, {\bf 100}(11):4039--4058, 2000.
\bibitem{Pinkard2018}
{\sc Andrew Pinkard, Anouck~M Champsaur, and Xavier Roy}.
\newblock {\bf Molecular clusters: nanoscale building blocks for solid-state
materials}.
\newblock {\em Acc. Chem. Res.}, {\bf 51}(4):919--929, 2018.
\bibitem{Asuka2013}
{\sc Asuka Fujii and Kenta Mizuse}.
\newblock \href{https://doi.org/10.1080/0144235X.2012.760836}{{\bf Infrared
spectroscopic studies on hydrogen-bonded water networks in gas phase
clusters}}.
\newblock {\em Int. Rev. Phys. Chem.}, {\bf 32}(2):266--307, 2013.
\bibitem{Luo2016}
{\sc Zhixun Luo, A.~W. Castleman, and Shiv~N. Khanna}.
\newblock \href{https://doi.org/10.1021/acs.chemrev.6b00230}{{\bf Reactivity of
metal clusters}}.
\newblock {\em Chem. Rev.}, {\bf 116}(23):14456--14492, 2016.
\newblock PMID: 27960263.
\bibitem{Wang2016}
{\sc Lai-Sheng Wang}.
\newblock \href{https://doi.org/10.1080/0144235X.2016.1147816}{{\bf
Photoelectron spectroscopy of size-selected boron clusters: from planar
structures to borophenes and borospherenes}}.
\newblock {\em Int. Rev. Phys. Chem.}, {\bf 35}(1):69--142, 2016.
\bibitem{Jiang2019}
{\sc Shuai Jiang, Xiaoli Zhang, Xiucheng Zheng, and Xiangtao Kong}.
\newblock {\bf Structures, energetics, and infrared spectra of the cationic
monomethylamine clusters}.
\newblock {\em Chemical Physics}, {\bf 523}:7--11, 2019.
\bibitem{Meot1984}
{\sc Michael Meot-Ner}.
\newblock {\bf The ionic hydrogen bond and ion solvation. 2. Solvation of onium
ions by one to seven H2O molecules. Relations between monomolecular,
specific, and bulk hydration}.
\newblock {\em J. Am. Chem. Soc}, {\bf 106}(5):1265--1272, 1984.
\bibitem{Castleman1994}
{\sc A.~W. Castleman and S.~Wei}.
\newblock \href{https://doi.org/10.1146/annurev.pc.45.100194.003345}{{\bf
Cluster Reactions}}.
\newblock {\em Annual Review of Physical Chemistry}, {\bf 45}(1):685--719,
1994.
\bibitem{Castleman1996}
{\sc A.~W. Castleman and K.~H. Bowen}.
\newblock \href{https://doi.org/10.1021/jp961030k}{{\bf Clusters: Structure,
energetics, and dynamics of intermediate states of matter}}.
\newblock {\em J. Phys. Chem.}, {\bf 100}(31):12911--12944, 1996.
\bibitem{Farrar1988}
{\sc James~M Farrar, William~Hundley Saunders, et~al.}
\newblock {\em Techniques for the study of ion-molecule reactions}.
\newblock John Wiley \& Sons, 1988.
\bibitem{Mayer2002}
{\sc Paul~M Mayer}.
\newblock {\bf Ion rearrangement at the beginning of cluster formation:
isomerization pathways and dissociation kinetics for the ionized
dimethylamine dimer}.
\newblock {\em International J. Mass Spectrom.}, {\bf 218}(1):1--10, 2002.
\bibitem{Wales1997}
{\sc David~J Wales and Jonathan~PK Doye}.
\newblock {\bf Global optimization by basin-hopping and the lowest energy
structures of Lennard-Jones clusters containing up to 110 atoms}.
\newblock {\em J. Phys. Chem. A}, {\bf 101}(28):5111--5116, 1997.
\bibitem{Wales1998}
{\sc David~J Wales and Matthew~P Hodges}.
\newblock {\bf Global minima of water clusters (H$_2$O)$_n$, n $\leqslant$ 21,
described by an empirical potential}.
\newblock {\em Chem. Phys. Lett.}, {\bf 286}(1-2):65--72, 1998.
\bibitem{Wales1999}
{\sc David~J Wales and Harold~A Scheraga}.
\newblock {\bf Global optimization of clusters, crystals, and biomolecules}.
\newblock {\em Science}, {\bf 285}(5432):1368--1372, 1999.
\bibitem{James2005}
{\sc Tim James, David~J Wales, and Javier Hern{\'a}ndez-Rojas}.
\newblock {\bf Global minima for water clusters (H$_2$O)$_n$, n$\leqslant$ 21,
described by a five-site empirical potential}.
\newblock {\em Chem. Phys. Lett.}, {\bf 415}(4-6):302--307, 2005.
\bibitem{Korchagina2017}
{\sc Kseniia Korchagina, Aude Simon, Mathias Rapacioli, Fernand Spiegelman,
Jean-Marc LHermite, Isabelle Braud, S{\'e}bastien Zamith, and
J{\'e}r{\^o}me Cuny}.
\newblock {\bf Theoretical investigation of the solid--liquid phase transition
in protonated water clusters}.
\newblock {\em Phys. Chem. Chem. Phys.}, {\bf 19}(40):27288--27298, 2017.
\bibitem{Hada2003}
{\sc Yasuhiro Hada}.
\newblock {\bf A molecular dynamics simulation of cluster dissociation process
under cluster ion implantation}.
\newblock {\em Phys. Rev. B Condens. Matter}, {\bf 340}:1036--1040, 2003.
\bibitem{Chakraborty2020}
{\sc Debdutta Chakraborty, Hans Lischka, and William~L Hase}.
\newblock {\bf Dynamics of Pyrene-Dimer Association and Ensuing Pyrene-Dimer
Dissociation}.
\newblock {\em J. Phys. Chem. A}, {\bf 124}(43):8907--8917, 2020.
\bibitem{Zamith2020threshold}
{\sc S{\'e}bastien Zamith, Jean-Marc Lhermite, L{\'e}o Dontot, Linjie Zheng,
Mathias Rapacioli, Fernand Spiegelman, and Christine Joblin}.
\newblock {\bf Threshold collision induced dissociation of pyrene cluster
cations}.
\newblock {\em J. Chem. Phys.}, {\bf 153}(5):054311, 2020.
\bibitem{Zheng2021}
{\sc Linjie Zheng, S{\'e}bastien Zamith, and Mathias Rapacioli}.
\newblock {\bf Dynamical simulation of collision-induced dissociation of pyrene
dimer cation}.
\newblock {\em Theor. Chem. Acc.}, {\bf 140}(2):1--14, 2021.
\bibitem{Tibshirani2005}
{\sc Robert Tibshirani and Guenther Walther}.
\newblock {\bf Cluster validation by prediction strength}.
\newblock {\em J. Comput. Graph. Stat.}, {\bf 14}(3):511--528, 2005.
\bibitem{Woutersen1997}
{\sc AS~Woutersen, U~Emmerichs, and HJ~Bakker}.
\newblock {\bf Femtosecond mid-IR pump-probe spectroscopy of liquid water:
Evidence for a two-component structure}.
\newblock {\em Science}, {\bf 278}(5338):658--660, 1997.
\bibitem{Ruan2004}
{\sc Chong-Yu Ruan, Vladimir~A Lobastov, Franco Vigliotti, Songye Chen, and
Ahmed~H Zewail}.
\newblock {\bf Ultrafast electron crystallography of interfacial water}.
\newblock {\em Science}, {\bf 304}(5667):80--84, 2004.
\bibitem{Brubach2005}
{\sc J-B Brubach, Al~Mermet, A~Filabozzi, A~Gerschel, and P~Roy}.
\newblock {\bf Signatures of the hydrogen bonding in the infrared bands of
water}.
\newblock {\em J. Chem. Phys.}, {\bf 122}(18):184509, 2005.
\bibitem{Bergmann2007}
{\sc Uwe Bergmann, Dennis Nordlund, Ph~Wernet, Michael Odelius, Lars~GM
Pettersson, and Anders Nilsson}.
\newblock {\bf Isotope effects in liquid water probed by x-ray Raman
spectroscopy}.
\newblock {\em Phys. Rev. B}, {\bf 76}(2):024202, 2007.
\bibitem{Pokapanich2009}
{\sc Wandared Pokapanich, Henrik Bergersen, Ioana~L Bradeanu, Ricardo~RT
Marinho, Andreas Lindblad, Sebastien Legendre, Aldana Rosso, Svante Svensson,
Maxim Tchaplyguine, Nikolai~V Kryzhevoi, et~al.}
\newblock {\bf Auger electron spectroscopy as a probe of the solution of
aqueous ions}.
\newblock {\em J. Am. Chem. Soc.}, {\bf 131}(21):7264--7271, 2009.
\bibitem{Sun2010}
{\sc Qiang Sun}.
\newblock {\bf The single donator-single acceptor hydrogen bonding structure in
water probed by Raman spectroscopy}.
\newblock {\em J. Chem. Phys.}, {\bf 132}(5):054507, 2010.
\bibitem{Harada2017}
{\sc Y~Harada, J~Miyawaki, H~Niwa, K~Yamazoe, Lars~GM Pettersson, and Anders
Nilsson}.
\newblock {\bf Probing the OH stretch in different local environments in liquid
water}.
\newblock {\em J. Phys. Chem. Lett.}, {\bf 8}(22):5487--5491, 2017.
\bibitem{Yamazoe2019}
{\sc Kosuke Yamazoe, Jun Miyawaki, Hideharu Niwa, Anders Nilsson, and Yoshihisa
Harada}.
\newblock {\bf Measurements of ultrafast dissociation in resonant inelastic
x-ray scattering of water}.
\newblock {\em J. Chem. Phys.}, {\bf 150}(20):204201, 2019.
\bibitem{Silvestrelli1999}
{\sc Pier~Luigi Silvestrelli and Michele Parrinello}.
\newblock {\bf Structural, electronic, and bonding properties of liquid water
from first principles}.
\newblock {\em J. Chem. Phys.}, {\bf 111}(8):3572--3580, 1999.
\bibitem{Laage2006}
{\sc Damien Laage and James~T Hynes}.
\newblock {\bf A molecular jump mechanism of water reorientation}.
\newblock {\em Science}, {\bf 311}(5762):832--835, 2006.
\bibitem{Bryantsev2009}
{\sc Vyacheslav~S Bryantsev, Mamadou~S Diallo, Adri~CT Van~Duin, and William~A
Goddard~III}.
\newblock {\bf Evaluation of B3LYP, X3LYP, and M06-class density functionals
for predicting the binding energies of neutral, protonated, and deprotonated
water clusters}.
\newblock {\em J. Chem. Theory Comput.}, {\bf 5}(4):1016--1026, 2009.
\bibitem{Silvestrelli2017}
{\sc Pier~Luigi Silvestrelli}.
\newblock {\bf Hydrogen bonding characterization in water and small molecules}.
\newblock {\em J. Chem. Phys.}, {\bf 146}(24):244315, 2017.
\bibitem{Bernal1933}
{\sc John~D Bernal and Ralph~H Fowler}.
\newblock {\bf A theory of water and ionic solution, with particular reference
to hydrogen and hydroxyl ions}.
\newblock {\em J. Chem. Phys.}, {\bf 1}(8):515--548, 1933.
\bibitem{Shields2010}
{\sc Robert~M. Shields, Berhane Temelso, Kaye~A. Archer, Thomas~E. Morrell, and
George~C. Shields}.
\newblock {\bf Accurate predictions of water cluster formation,
(H$_2$O)$_{n=2-10}$, journal = {J. Phys. Chem. A}, volume = {114}, number =
{43}, pages = {11725-11737}, year = {2010}}.
\bibitem{Gregory1996}
{\sc Jonathon~K Gregory and David~C Clary}.
\newblock {\bf Structure of water clusters. The contribution of many-body
forces, monomer relaxation, and vibrational zero-point energy}.
\newblock {\em J. Phys. Chem.}, {\bf 100}(46):18014--18022, 1996.
\bibitem{Kunst1980}
{\sc Marinus Kunst and John~M Warman}.
\newblock {\bf Proton mobility in ice}.
\newblock {\em Nature}, {\bf 288}(5790):465--467, 1980.
\bibitem{Torrent2011}
{\sc Miquel Torrent-Sucarrat and Josep~M Anglada}.
\newblock {\bf Anharmonicity and the Eigen-Zundel dilemma in the IR spectrum of
the protonated 21 water cluster}.
\newblock {\em J. Chem. Theory Comput.}, {\bf 7}(2):467--472, 2011.
\bibitem{Wang2010}
{\sc Xue-Bin Wang, Karol Kowalski, Lai-Sheng Wang, and Sotiris~S Xantheas}.
\newblock {\bf Stepwise hydration of the cyanide anion: A temperatur-controlled
photoelectron spectroscopy and ab initio computational study of
CN-(H$_2$O)$_n$, n = 2-5}.
\newblock {\em J. Chem. Phys.}, {\bf 132}(12):124306, 2010.
\bibitem{Bigg1975}
{\sc E.~K. Bigg}.
\newblock {\bf Stratospheric particles}.
\newblock {\em J. Atmos. Sci.}, {\bf 32}(5):910--917, 1975.
\bibitem{Vaida2000}
{\sc Veronica Vaida and Jill~E Headrick}.
\newblock {\bf Physicochemical properties of hydrated complexes in the Earth's
atmosphere}.
\newblock {\em J. Phys. Chem. A}, {\bf 104}(23):5401--5412, 2000.
\bibitem{Aloisio2000}
{\sc Simone Aloisio and Joseph~S Francisco}.
\newblock {\bf Radical-water complexes in earth's atmosphere}.
\newblock {\em Acc. Chem. Res.}, {\bf 33}(12):825--830, 2000.
\bibitem{Ramanathan2001}
{\sc VCPJ Ramanathan, PJ~Crutzen, JT~Kiehl, and Daniel Rosenfeld}.
\newblock {\bf Aerosols, climate, and the hydrological cycle}.
\newblock {\em science}, {\bf 294}(5549):2119--2124, 2001.
\bibitem{Mccurdy2002}
{\sc Patrick~R McCurdy, Wayne~P Hess, and Sotiris~S Xantheas}.
\newblock {\bf Nitric acid- water complexes: Theoretical calculations and
comparison to experiment}.
\newblock {\em J. Phys. Chem. A}, {\bf 106}(33):7628--7635, 2002.
\bibitem{Hartt2008}
{\sc Gregory~M Hartt, George~C Shields, and Karl~N Kirschner}.
\newblock {\bf Hydration of OCS with one to four water molecules in atmospheric
and laboratory conditions}.
\newblock {\em J. Phys. Chem. A}, {\bf 112}(19):4490--4495, 2008.
\bibitem{Vaida2011}
{\sc Veronica Vaida}.
\newblock {\bf Perspective: Water cluster mediated atmospheric chemistry}.
\newblock {\em J. Chem. Phys.}, {\bf 135}(2):020901, 2011.
\bibitem{Kjaergaard2003}
{\sc Henrik~G Kjaergaard, Timothy~W Robinson, Daryl~L Howard, John~S Daniel,
Jill~E Headrick, and Veronica Vaida}.
\newblock {\bf Complexes of importance to the absorption of solar radiation}.
\newblock {\em J. Phys. Chem. A}, {\bf 107}(49):10680--10686, 2003.
\bibitem{Vaida2003}
{\sc Veronica Vaida, Henrik~G Kjaergaard, and Karl~J Feierabend}.
\newblock {\bf Hydrated complexes: Relevance to atmospheric chemistry and
climate}.
\newblock {\em Int. Rev. Phys. Chem.}, {\bf 22}(1):203--219, 2003.
\bibitem{Klan2001}
{\sc Petr Kl{\'a}n, David Del~Favero, Alena Ansorgov{\'a}, Jana
Kl{\'a}nov{\'a}, and Ivan Holoubek}.
\newblock {\bf Photodegradation of halobenzenes in water ice}.
\newblock {\em Environ. Sci. Pollut. Res.}, {\bf 8}(3):195--200, 2001.
\bibitem{Amiaud2007}
{\sc L~Amiaud, F~Dulieu, J-H Fillion, A~Momeni, and JL~Lemaire}.
\newblock {\bf Interaction of atomic and molecular deuterium with a nonporous
amorphous water ice surface between 8 and 30 K}.
\newblock {\em J. Chem. Phys.}, {\bf 127}(14):144709, 2007.
\bibitem{Kahan2010}
{\sc TF~Kahan, R~Zhao, and DJ~Donaldson}.
\newblock {\bf Hydroxyl radical reactivity at the air-ice interface}.
\newblock {\em Atmos. Chem. Phys.}, {\bf 10}(2):843--854, 2010.
\bibitem{Minissale2019}
{\sc M~Minissale, T~Nguyen, and F~Dulieu}.
\newblock {\bf Experimental study of the penetration of oxygen and deuterium
atoms into porous water ice}.
\newblock {\em Astron. Astrophys.}, {\bf 622}:A148, 2019.
\bibitem{Perez2012}
{\sc Crist\'{o}bal P\'{e}rez, Matt~T. Muckle, Daniel~P. Zaleski, Nathan~A.
Seifert, Berhane Temelso, George~C. Shields, Zbigniew Kisiel, and Brooks~H.
Pate}.
\newblock \href{http://www.sciencemag.org/content/336/6083/897.abstract}{{\bf
Structures of cage, prism, and book isomers of water hexamer from broadband
rotational spectroscopy}}.
\newblock {\em Science}, {\bf 336}(6083):897--901, 2012.
\bibitem{Huneycutt2003}
{\sc Alex~J Huneycutt, Ross~J Stickland, Fredrik Hellberg, and Richard~J
Saykally}.
\newblock {\bf Infrared cavity ringdown spectroscopy of acid--water clusters:
HCl--H$_2$O, DCl--D$_2$O, and DCl--(D$_2$O)$_2$}.
\newblock {\em J. Chem. Phys.}, {\bf 118}(3):1221--1229, 2003.
\bibitem{Caleman2007}
{\sc Carl Caleman and David van~der Spoel}.
\newblock {\bf Evaporation from water clusters containing singly charged ions}.
\newblock {\em Phys. Chem. Chem. Phys.}, {\bf 9}(37):5105--5111, 2007.
\bibitem{Rozenberg2009}
{\sc M~Rozenberg and A~Loewenschuss}.
\newblock {\bf Matrix isolation infrared spectrum of the sulfuric acid-
monohydrate complex: new assignments and resolution of the “missing
h-bonded $\nu$ (oh) band” issue}.
\newblock {\em J. Phys. Chem. A}, {\bf 113}(17):4963--4971, 2009.
\bibitem{Korchagina2016}
{\sc Kseniia~A. Korchagina, Aude Simon, Mathias Rapacioli, Fernand Spiegelman,
and Jérôme Cuny}.
\newblock {\bf Structural characterization of sulfur-containing water clusters
using a density-functional based tight-binding approach}.
\newblock {\em J. Phys. Chem. A}, {\bf 120}(45):9089--9100, 2016.
\bibitem{Braud2019}
{\sc Isabelle Braud, S{\'e}bastien Zamith, J{\'e}r{\^o}me Cuny, Linjie Zheng,
and Jean-Marc LHermite}.
\newblock {\bf Size-dependent proton localization in hydrated uracil clusters:
A joint experimental and theoretical study}.
\newblock {\em J. Chem. Phys.}, {\bf 150}(1):014303, 2019.
\bibitem{Ryding2011}
{\sc Mauritz~Johan Ryding, Alexey~S Zatula, Patrik~Urban Andersson, and Einar
Uggerud}.
\newblock {\bf Isotope exchange in reactions between D 2 O and size-selected
ionic water clusters containing pyridine, H+(pyridine) m (H 2 O) n}.
\newblock {\em Phys. Chem. Chem. Phys.}, {\bf 13}(4):1356--1367, 2011.
\bibitem{Koop1996}
{\sc Thomas Koop and Kenneth~S Carslaw}.
\newblock {\bf Melting of H2SO4{\textperiodcentered} 4H2O particles upon
cooling: Implications for polar stratospheric clouds}.
\newblock {\em Science}, {\bf 272}(5268):1638--1641, 1996.
\bibitem{Carslaw1997}
{\sc Kenneth~S Carslaw, Thomas Peter, and Simon~L Clegg}.
\newblock {\bf Modeling the composition of liquid stratospheric aerosols}.
\newblock {\em Rev. Geophys.}, {\bf 35}(2):125--154, 1997.
\bibitem{Arnold1977}
{\sc F~Arnold, D~Krankowsky, and KH~Marien}.
\newblock {\bf First mass spectrometric measurements of positive ions in the
stratosphere}.
\newblock {\em Nature}, {\bf 267}(5606):30--32, 1977.
\bibitem{Arnold1982}
{\sc F~Arnold, AA~Viggiano, and H~Schlager}.
\newblock {\bf Implications for trace gases and aerosols of large negative ion
clusters in the stratosphere}.
\newblock {\em Nature}, {\bf 297}(5865):371--376, 1982.
\bibitem{Payzant1973}
{\sc JD~Payzant, AJ~Cunningham, and P~Kebarle}.
\newblock {\bf Gas phase solvation of the ammonium ion by NH$_3$ and H$_2$O and
stabilities of mixed clusters nh$_4^+$(nh$_3$)$_n$(H$_2$O)$_w$}.
\newblock {\em Can. J. Chem.}, {\bf 51}(19):3242--3249, 1973.
\bibitem{Kulmala1995}
{\sc M~Kulmala, H~Vehkam{\"a}ki, T~Vesala, JC~Barrett, and CF~Clement}.
\newblock {\bf Aerosol formation in diffusive boundary layer: Binary
homogeneous nucleation of ammonia and water vapours}.
\newblock {\em J. Aerosol Sci.}, {\bf 26}(4):547--558, 1995.
\bibitem{Kirkby2011}
{\sc Jasper Kirkby, Joachim Curtius, Jo{\~a}o Almeida, Eimear Dunne, Jonathan
Duplissy, Sebastian Ehrhart, Alessandro Franchin, St{\'e}phanie Gagn{\'e},
Luisa Ickes, Andreas K{\"u}rten, et~al.}
\newblock {\bf Role of sulphuric acid, ammonia and galactic cosmic rays in
atmospheric aerosol nucleation}.
\newblock {\em Nature}, {\bf 476}(7361):429--433, 2011.
\bibitem{Dunne2016}
{\sc Eimear~M Dunne, Hamish Gordon, Andreas K{\"u}rten, Jo{\~a}o Almeida,
Jonathan Duplissy, Christina Williamson, Ismael~K Ortega, Kirsty~J Pringle,
Alexey Adamov, Urs Baltensperger, et~al.}
\newblock {\bf Global atmospheric particle formation from CERN CLOUD
measurements}.
\newblock {\em Science}, {\bf 354}(6316):1119--1124, 2016.
\bibitem{Leger1984}
{\sc A.~{L\'{e}ger} and J.~L. {Puget}}.
\newblock {\bf {Identification of the 'unidentified' IR emission features of
interstellar dust?}}
\newblock {\em Astron. Astrophys.}, {\bf 137}:L5--L8, 1984.
\bibitem{Allamandola1985}
{\sc L~J Allamandola, A~G G~M Tielens, and JRz Barker}.
\newblock {\bf Polycyclic aromatic hydrocarbons and the unidentified infrared
emission bands-Auto exhaust along the Milky Way}.
\newblock {\em Astrophys. J.}, {\bf 290}:L25--L28, 1985.
\bibitem{Puget1989}
{\sc JL~Puget and A~L{\'e}ger}.
\newblock {\bf A new component of the interstellar matter: Small grains and
large aromatic molecules}.
\newblock {\em Annu. Rev. Astron. Astrophys.}, {\bf 27}(1):161--198, 1989.
\bibitem{Tielens2008}
{\sc Alexander G G~M Tielens}.
\newblock {\bf Interstellar polycyclic aromatic hydrocarbon molecules}.
\newblock {\em Annu. Rev. Astron. Astrophys.}, {\bf 46}:289--337, 2008.
\bibitem{Tielens2005}
{\sc Alexander G G~M Tielens}.
\newblock {\em The physics and chemistry of the interstellar medium}.
\newblock Cambridge University Press, 2005.
\bibitem{Rapacioli2006}
{\sc M~Rapacioli, F~Calvo, C~Joblin, P~Parneix, D~Toublanc, and F~Spiegelman}.
\newblock {\bf Formation and destruction of polycyclic aromatic hydrocarbon
clusters in the interstellar medium}.
\newblock {\em Astron. Astrophys.}, {\bf 460}(2):519--531, 2006.
\bibitem{Montillaud2014}
{\sc Julien Montillaud and Christine Joblin}.
\newblock {\bf Absolute evaporation rates of non-rotating neutral polycyclic
aromatic hydrocarbon clusters}.
\newblock {\em Astron. Astrophys.}, {\bf 567}:A45, 2014.
\bibitem{Rapacioli2009}
{\sc Mathias Rapacioli and Fernand Spiegelman}.
\newblock {\bf Modelling singly ionized coronene clusters}.
\newblock {\em The European Physical Journal D}, {\bf 52}(1):55--58, 2009.
\bibitem{Joblin2017}
{\sc Christine Joblin, L{\'e}o Dontot, GA~Garcia, Fernand Spiegelman, Mathias
Rapacioli, Laurent Nahon, Pascal Parneix, T~Pino, and P~Br{\'e}chignac}.
\newblock {\bf Size effect in the ionization energy of PAH clusters}.
\newblock {\em J. Phys. Chem. Lett.}, {\bf 8}(15):3697--3702, 2017.
\bibitem{Finlayson1986}
{\sc Barbara~J Finlayson-Pitts and James~N Pitts~Jr}.
\newblock {\bf Atmospheric chemistry. Fundamentals and experimental
techniques}.
\newblock 1986.
\bibitem{Callen2008}
{\sc MS~Call{\'e}n, MT~De~la Cruz, JM~L{\'o}pez, R~Murillo, MV~Navarro, and
AM~Mastral}.
\newblock {\bf Some inferences on the mechanism of atmospheric gas/particle
partitioning of polycyclic aromatic hydrocarbons (PAH) at Zaragoza (Spain)}.
\newblock {\em Chemosphere}, {\bf 73}(8):1357--1365, 2008.
\bibitem{Eaves2015}
{\sc NA~Eaves, SB~Dworkin, and MJ~Thomson}.
\newblock {\bf The importance of reversibility in modeling soot nucleation and
condensation processes}.
\newblock {\em Proc. Combust. Inst.}, {\bf 35}(2):1787--1794, 2015.
\bibitem{Violi2007}
{\sc Angela Violi and Sergei Izvekov}.
\newblock {\bf Soot primary particle formation from multiscale coarse-grained
molecular dynamics simulation}.
\newblock {\em Proc. Combust. Inst.}, {\bf 31}(1):529--537, 2007.
\bibitem{Scholz2013}
{\sc Reinhard Scholz, Regina Luschtinetz, Gotthard Seifert, Till
J{\"a}geler-Hoheisel, Christian K{\"o}rner, Karl Leo, and Mathias Rapacioli}.
\newblock {\bf Quantifying charge transfer energies at donor--acceptor
interfaces in small-molecule solar cells with constrained DFTB and
spectroscopic methods}.
\newblock {\em J. Condens. Matter Phys.}, {\bf 25}(47):473201, 2013.
\bibitem{Darghouth2015}
{\sc Ala Aldin~MHM Darghouth, Mark~E Casida, Walid Taouali, Kamel Alimi,
Mathias~P Ljungberg, Peter Koval, Daniel S{\'a}nchez-Portal, and Dietrich
Foerster}.
\newblock {\bf Assessment of density-functional tight-binding ionization
potentials and electron affinities of molecules of interest for organic solar
cells against first-principles GW calculations}.
\newblock {\em Computation}, {\bf 3}(4):616--656, 2015.
\bibitem{Holm2010}
{\sc Anne I~S Holm, Henning Zettergren, Henrik~AB Johansson, Fabian Seitz,
Stefan Rosen, Henning~T Schmidt, A~{\L}awicki, Jimmy Rangama, Patrick
Rousseau, Micha{\"e}l Capron, et~al.}
\newblock {\bf Ions colliding with cold polycyclic aromatic hydrocarbon
clusters}.
\newblock {\em Phys. Rev. Lett.}, {\bf 105}(21):213401, 2010.
\bibitem{Simon2017formation}
{\sc Aude Simon, J~A Noble, Guillaume Rouaut, Audrey Moudens, C~Aupetit,
Christophe Iftner, and Jo{\"e}lle Mascetti}.
\newblock {\bf Formation of coronene: water complexes: FTIR study in argon
matrices and theoretical characterisation}.
\newblock {\em Phys. Chem. Chem. Phys.}, {\bf 19}(12):8516--8529, 2017.
\bibitem{Chen2018}
{\sc Tao Chen}.
\newblock {\bf Formation of covalently bonded polycyclic aromatic hydrocarbons
in the interstellar medium}.
\newblock {\em Astrophys. J.}, {\bf 866}(2):113, 2018.
\bibitem{Schmidt2006}
{\sc Martin Schmidt, Albert Masson, and Catherine Br{\'e}chignac}.
\newblock {\bf Coronene cluster experiments: Stability and thermodynamics}.
\newblock {\em International J. Mass Spectrom.}, {\bf 252}(2):173--179, 2006.
\bibitem{Gatchell2015}
{\sc Michael Gatchell, Mark~H Stockett, Nathalie de~Ruette, Tao Chen, Linda
Giacomozzi, Rodrigo~F Nascimento, Michael Wolf, Emma~K Anderson, Rudy
Delaunay, Violaine Vizcaino, et~al.}
\newblock {\bf Failure of hydrogenation in protecting polycyclic aromatic
hydrocarbons from fragmentation}.
\newblock {\em Phys. Rev. A}, {\bf 92}(5):050702, 2015.
\bibitem{Gatchell2017}
{\sc Michael Gatchell, Rudy Delaunay, Giovanna D'Angelo, Arkadiusz Mika,
Kostiantyn Kulyk, Alicja Domaracka, Patrick Rousseau, Henning Zettergren,
Bernd~A Huber, and Henrik Cederquist}.
\newblock {\bf Ion-induced molecular growth in clusters of small hydrocarbon
chains}.
\newblock {\em Phys. Chem. Chem. Phys.}, {\bf 19}(30):19665--19672, 2017.
\bibitem{Zamith2019thermal}
{\sc S{\'e}bastien Zamith, Ming-Chao Ji, Jean-Marc lHermite, Christine
Joblin, L{\'e}o Dontot, Mathias Rapacioli, and Fernand Spiegelman}.
\newblock {\bf Thermal evaporation of pyrene clusters}.
\newblock {\em J. Chem. Phys.}, {\bf 151}(19):194303, 2019.
\bibitem{Dawson1982}
{\sc PH~Dawson}.
\newblock {\bf The collision-induced dissociation of protonated water clusters
studied using a triple quadrupole}.
\newblock {\em Int. J. Mass Spectrom.}, {\bf 43}(2-3):195--209, 1982.
\bibitem{Graul1989}
{\sc Susan~T Graul and Robert~R Squires}.
\newblock {\bf Energy-Resolved Collision-Induced Dissociation of Proton-Bound
Cluster Ions as a Structural Probe: The Acetonitrile-Water System}.
\newblock {\em Int. J. Mass Spectrom. Ion Process}, {\bf 94}(1-2):41--61, 1989.
\bibitem{Wei1991}
{\sc S~Wei, WB~Tzeng, RG~Keesee, and AW~Castleman~Jr}.
\newblock {\bf Metastable Unimolecular and Collision-Induced Dissociation of
Hydrogen-Bonded Clusters: Evidence for Intracluster Molecular Rearrangement
and the Structure of Solvated Protonated Complexes}.
\newblock {\em J. Am. Chem. Soc.}, {\bf 113}(6):1960--1969, 1991.
\bibitem{Liu2006}
{\sc B.~Liu, S.~Brondsted Nielsen, P.~Hvelplund, H.~Zettergren, H.~Cederquist,
B.~Manil, and B.~A. Huber}.
\newblock {\bf {Collision-Induced Dissociation of Hydrated Adenosine
Monophosphate Nucleotide Ions: Protection of the Ion in Water Nanoclusters}}.
\newblock {\em Phys. Rev. Lett.}, {\bf {97}}({13}):{133401}, {SEP 29} {2006}.
\bibitem{Goebbert2006}
{\sc Daniel~J Goebbert, Hao Chen, and Paul~G Wenthold}.
\newblock {\bf Collision-induced dissociation studies of protonated
ether-(H$_2$O)$_n$ (n= 1--3) clusters}.
\newblock {\em J. Mass Spectrom.}, {\bf 41}(2):242--247, 2006.
\bibitem{Coates2018}
{\sc Rebecca~A Coates and PB~Armentrout}.
\newblock {\bf Binding energies of hydrated cobalt (ii) by collision-induced
dissociation and theoretical studies: evidence for a new critical size}.
\newblock {\em Phys. Chem. Chem. Phys.}, {\bf 20}(2):802--818, 2018.
\bibitem{Nelson1994}
{\sc Chad~C Nelson and James~A McCloskey}.
\newblock {\bf Collision-induced dissociation of uracil and its derivatives}.
\newblock {\em J. Am. Soc. Mass Spectrom.}, {\bf 5}(5):339--349, 1994.
\bibitem{Molina2015}
{\sc Estefan{\'\i}a~Rossich Molina, Daniel Ortiz, Jean-Yves Salpin, and
Riccardo Spezia}.
\newblock {\bf Elucidating collision induced dissociation products and reaction
mechanisms of protonated uracil by coupling chemical dynamics simulations
with tandem mass spectrometry experiments}.
\newblock {\em J. Mass Spectrom.}, {\bf 50}(12):1340--1351, 2015.
\bibitem{Carl2007}
{\sc Damon~R. Carl, Robert~M. Moision, and P.~B. Armentrout}.
\newblock {\bf {Binding energies for the inner hydration shells of Ca$^{2+}$:
An experimental and theoretical investigation of Ca$^{2+}$(H$_2$O)$_x$
complexes (x=5-9)}}.
\newblock {\em Int. J. Mass Spectrom.}, {\bf {265}}({2-3}):{308--325}, {SEP 1}
{2007}.
\bibitem{Nguyen2011}
{\sc Viet~Hung Nguyen, Carlos Afonso, and Jean-Claude Tabet}.
\newblock {\bf {Concomitant EDD and EID of DNA evidenced by MSn and double
resonance experiments}}.
\newblock {\em {Int. J. Mass Spectrom.}}, {\bf {301}}({1-3, SI}):{224--233},
{MAR 30} {2011}.
\bibitem{Shuck2014}
{\sc Sarah~C. Shuck, Kristie~L. Rose, and Lawrence~J. Marnett}.
\newblock \href{https://dx.doi.org/10.1021/tx400384e}{{\bf Mass spectrometric
methods for the analysis of nucleosideprotein cross-links: application to
oxopropenyl-deoxyadenosine}}.
\newblock {\em Chem. Res. Toxicol.}, {\bf 27}(1):136--146, 2014.
\bibitem{Castrovilli2017}
{\sc MC~Castrovilli, P~Markush, P~Bolognesi, P~Rousseau, S~Maclot, A~Cartoni,
R~Delaunay, A~Domaracka, J~Ko{\v{c}}i{\v{s}}ek, BA~Huber, and L~Avaldi}.
\newblock {\bf Fragmentation of pure and hydrated clusters of 5br-uracil by low
energy carbon ions: observation of hydrated fragments}.
\newblock {\em Phys. Chem. Chem. Phys.}, {\bf 19}(30):19807--19814, 2017.
\bibitem{Bera2018}
{\sc Anupam Bera, Bruno Concina, Baptiste Schindler, Gina~Predelus Renois,
Gabriel Karras, Isabelle Compagnon, Atanu Bhattacharya, and Franck
L{\'e}pine}.
\newblock {\bf Collision induced dissociation of positive ions of
dimethylnitramine, a model system for nitramine energetic molecules}.
\newblock {\em Int. J. Mass Spectrom.}, {\bf 431}:15--21, 2018.
\bibitem{Klippenstein1992}
{\sc Stephen~J Klippenstein}.
\newblock {\bf Variational optimizations in the
rice--ramsperger--kassel--marcus theory calculations for unimolecular
dissociations with no reverse barrier}.
\newblock {\em J. Chem. Phys.}, {\bf 96}(1):367--371, 1992.
\bibitem{Baer1996}
{\sc Tomas Baer and William~L Hase}.
\newblock {\em Unimolecular Reaction Dynamics: Theory and Experiments}, ~{\bf
31}.
\newblock Oxford University Press on Demand, 1996.
\bibitem{Metropolis1949}
{\sc Nicholas Metropolis and Stanislaw Ulam}.
\newblock {\bf The Monte Carlo method}.
\newblock {\em J. Am. Stat. Assoc.}, {\bf 44}(247):335--341, 1949.
\bibitem{Voter2007}
{\sc Arthur~F Voter}.
\newblock {\bf Introduction to the kinetic Monte Carlo method}.
\newblock In {\em Radiation Effects in Solids}, pages 1--23. Springer, 2007.
\bibitem{Brown2009}
{\sc Theodore~Lawrence Brown}.
\newblock {\em Chemistry: the central science}.
\newblock Pearson Education, 2009.
\bibitem{MCTDH}
{\sc M.H. Beck, A.~Jäckle, G.A. Worth, and H.-D. Meyer}.
\newblock
\href{https://www.sciencedirect.com/science/article/pii/S0370157399000472}{{\bf
The multiconfiguration time-dependent hartree (MCTDH) method: a highly
efficient algorithm for propagating wavepackets}}.
\newblock {\em Phys. Rep.}, {\bf 324}(1):1--105, 2000.
\bibitem{Griffiths2018}
{\sc David~J Griffiths and Darrell~F Schroeter}.
\newblock {\em Introduction to quantum mechanics}.
\newblock Cambridge University Press, 2018.
\bibitem{Born1927}
{\sc Max Born and Robert Oppenheimer}.
\newblock {\bf Zur quantentheorie der molekeln}.
\newblock {\em Ann. Phys.}, {\bf 389}(20):457--484, 1927.
\bibitem{Epstein1966}
{\sc Saul~T Epstein}.
\newblock {\bf Ground-state energy of a molecule in the adiabatic
approximation}.
\newblock {\em J. Chem. Phys.}, {\bf 44}(2):836--837, 1966.
\bibitem{Butler1998}
{\sc Laurie~J Butler}.
\newblock {\bf Chemical reaction dynamics beyond the Born-Oppenheimer
approximation}.
\newblock {\em Ann. Rev. Phys. Chem.}, {\bf 49}(1):125--171, 1998.
\bibitem{Puzzarini2010}
{\sc Cristina Puzzarini, John~F Stanton, and Juergen Gauss}.
\newblock {\bf Quantum-chemical calculation of spectroscopic parameters for
rotational spectroscopy}.
\newblock {\em Int. Rev. Phys. Chem.}, {\bf 29}(2):273--367, 2010.
\bibitem{Helgaker1999}
{\sc Trygve Helgaker, Micha{\l} Jaszu{\'n}ski, and Kenneth Ruud}.
\newblock {\bf Ab initio methods for the calculation of NMR shielding and
indirect spin- spin coupling constants}.
\newblock {\em Chem. Rev.}, {\bf 99}(1):293--352, 1999.
\bibitem{Pedone2010}
{\sc Alfonso Pedone, Malgorzata Biczysko, and Vincenzo Barone}.
\newblock {\bf Environmental effects in computational spectroscopy: Accuracy
and interpretation}.
\newblock {\em ChemPhysChem}, {\bf 11}(9):1812--1832, 2010.
\bibitem{Fleming1986}
{\sc Graham Fleming}.
\newblock {\bf Chemical applications of ultrafast spectroscopy}.
\newblock 1986.
\bibitem{Laane1999}
{\sc Jaan Laane, Hiroaki Takahashi, and Andre Bandrauk}.
\newblock {\em Structure and Dynamics of Electronic Excited States}.
\newblock Springer Science \& Business Media, 1999.
\bibitem{Helgaker2012}
{\sc Trygve Helgaker, Sonia Coriani, Poul J{\o}rgensen, Kasper Kristensen,
Jeppe Olsen, and Kenneth Ruud}.
\newblock {\bf Recent advances in wave function-based methods of
molecular-property calculations}.
\newblock {\em Chem. Rev.}, {\bf 112}(1):543--631, 2012.
\bibitem{Jensen2017}
{\sc Frank Jensen}.
\newblock {\em Introduction to computational chemistry}.
\newblock John wiley \& sons, 2017.
\bibitem{dftb1}
{\sc Dirk Porezag, Th~Frauenheim, Th~K{\"o}hler, Gotthard Seifert, and
R~Kaschner}.
\newblock {\bf Construction of tight-binding-like potentials on the basis of
density-functional theory: application to carbon}.
\newblock {\em Phys. Rev. B}, {\bf 51}(19):12947--12958, 1995.
\bibitem{dftb2}
{\sc G~Seifert, D~Porezag, and Th~Frauenheim}.
\newblock {\bf Calculations of molecules, clusters, and solids with a
simplified LCAO-DFT-LDA scheme}.
\newblock {\em Int. J. Quantum Chem.}, {\bf 58}(2):185--192, 1996.
\bibitem{Elstner1998}
{\sc Marcus Elstner, Dirk Porezag, G~Jungnickel, J~Elsner, M~Haugk,
Th~Frauenheim, Sandor Suhai, and Gotthard Seifert}.
\newblock {\bf Self-consistent-charge density-functional tight-binding method
for simulations of complex materials properties}.
\newblock {\em Phys. Rev. B}, {\bf 58}(11):7260, 1998.
\bibitem{Elstner2014}
{\sc Marcus Elstner and Gotthard Seifert}.
\newblock {\bf Density functional tight binding}.
\newblock {\em Philos. Trans. R. Soc. A-Math. Phys. Eng. Sci.}, {\bf
372}(2011):20120483, 2014.
\bibitem{Singh1986}
{\sc U~Chandra Singh and Peter~A Kollman}.
\newblock {\bf A combined ab initio quantum mechanical and molecular mechanical
method for carrying out simulations on complex molecular systems:
Applications to the CH$_3$Cl + Cl$^-$ exchange reaction and gas phase
protonation of polyethers}.
\newblock {\em J. Comput. Chem}, {\bf 7}(6):718--730, 1986.
\bibitem{Gao1996}
{\sc Jiali Gao}.
\newblock {\bf Methods and applications of combined quantum mechanical and
molecular mechanical potentials}.
\newblock {\em Rev. Comput. Chem.}, {\bf 7}:119--186, 1996.
\bibitem{Mordasini1998}
{\sc Tiziana~Z Mordasini and Walter Thiel}.
\newblock {\bf Combined quantum mechanical and molecular mechanical
approaches}.
\newblock {\em Chimia}, {\bf 52}(6):288--291, 1998.
\bibitem{Hartree1928}
{\sc D~R Hartree}.
\newblock {\bf The waves mechanics of an atom with non-coulombic central field:
parts I, II, III}.
\newblock In {\em Proc. Cambridge Phil. Soc}, ~{\bf 24}, pages 89--132, 1928.
\bibitem{Hartree1947}
{\sc D~R Hartree}.
\newblock {\bf The calculation of atomic structures}.
\newblock {\em Rep. Prog. Phys.}, {\bf 11}:113--143, 1947.
\bibitem{Slater1968}
{\sc John~Clarke Slater}.
\newblock {\bf Quantum theory of matter}.
\newblock 1968.
\bibitem{Mcweeny1992}
{\sc Roy McWeeny}.
\newblock {\em Methods of molecular quantum mechanics}.
\newblock Academic press, 1992.
\bibitem{Szabo1996}
{\sc A~Szabo and N~S Ostlund}.
\newblock {\bf Introduction to advanced electronic structure theory}.
\newblock {\em Modern Quantum Chemistry}, 1996.
\bibitem{Kohanoff2006}
{\sc Jorge Kohanoff}.
\newblock {\em Electronic structure calculations for solids and molecules:
theory and computational methods}.
\newblock Cambridge University Press, 2006.
\bibitem{Helgaker2014}
{\sc Trygve Helgaker, Poul Jorgensen, and Jeppe Olsen}.
\newblock {\em Molecular electronic-structure theory}.
\newblock John Wiley \& Sons, 2014.
\bibitem{Roothaan1951}
{\sc Clemens Carel~Johannes Roothaan}.
\newblock {\bf New developments in molecular orbital theory}.
\newblock {\em Rev. Mod. Phys.}, {\bf 23}(2):69--89, 1951.
\bibitem{Blinder2018}
{\sc Seymour~Michael Blinder and James~E House}.
\newblock {\em Mathematical Physics in Theoretical Chemistry}.
\newblock Elsevier, 2018.
\bibitem{koch1999}
{\sc R~Koch and T~Clark}.
\newblock {\em The chemists electronic book of orbitals}.
\newblock Springer, 1999.
\bibitem{Moskowitz1965}
{\sc JW~Moskowitz and MC~Harrison}.
\newblock {\bf Gaussian Wavefunctions for the 10-Electron Systems. III. OH$^-$,
H$_2$O, H$_3$O$^+$}.
\newblock {\em J. Chem. Phys.}, {\bf 43}(10):3550--3555, 1965.
\bibitem{Lowdin1995}
{\sc Per-Olov L{\"o}wdin}.
\newblock {\bf The historical development of the electron correlation problem}.
\newblock {\em Int. J. Quantum Chem.}, {\bf 55}(2):77--102, 1995.
\bibitem{Cramer2003}
{\sc Christopher~J Cramer and FM~Bickelhaupt}.
\newblock {\bf Essentials of computational chemistry}.
\newblock {\em Angew. Chem. Int. Ed.}, {\bf 42}(4):381--381, 2003.
\bibitem{Head1994}
{\sc Martin Head-Gordon, Rudolph~J Rico, Manabu Oumi, and Timothy~J Lee}.
\newblock {\bf A doubles correction to electronic excited states from
configuration interaction in the space of single substitutions}.
\newblock {\em Chem. Phys. Lett.}, {\bf 219}(1-2):21--29, 1994.
\bibitem{Maurice1999}
{\sc David Maurice and Martin Head-Gordon}.
\newblock {\bf Analytical second derivatives for excited electronic states
using the single excitation configuration interaction method: theory and
application to benzo [a] pyrene and chalcone}.
\newblock {\em Mol. Phys.}, {\bf 96}(10):1533--1541, 1999.
\bibitem{Moller1934}
{\sc Chr M{\o}ller and Milton~S Plesset}.
\newblock {\bf Note on an approximation treatment for many-electron systems}.
\newblock {\em Phys. Rev.}, {\bf 46}(7):618, 1934.
\bibitem{Pople1976}
{\sc John~A Pople, J~Stephen Binkley, and Rolf Seeger}.
\newblock {\bf Theoretical models incorporating electron correlation}.
\newblock {\em Int. J. Quantum Chem.}, {\bf 10}(S10):1--19, 1976.
\bibitem{Krishnan1978}
{\sc R~Krishnan and John~A Pople}.
\newblock {\bf Approximate fourth-order perturbation theory of the electron
correlation energy}.
\newblock {\em Int. J. Quantum Chem.}, {\bf 14}(1):91--100, 1978.
\bibitem{Vcivzek1966}
{\sc Ji{\v{r}}{\'\i} {\v{C}}{\'\i}{\v{z}}ek}.
\newblock {\bf On the correlation problem in atomic and molecular systems.
Calculation of wavefunction components in Ursell-type expansion using
quantum-field theoretical methods}.
\newblock {\em J. Chem. Phys}, {\bf 45}(11):4256--4266, 1966.
\bibitem{Purvis1982}
{\sc George~D Purvis~III and Rodney~J Bartlett}.
\newblock {\bf A full coupled-cluster singles and doubles model: The inclusion
of disconnected triples}.
\newblock {\em J. Chem. Phys}, {\bf 76}(4):1910--1918, 1982.
\bibitem{Raghavachari1989}
{\sc Krishnan Raghavachari, Gary~W Trucks, John~A Pople, and Martin
Head-Gordon}.
\newblock {\bf A fifth-order perturbation comparison of electron correlation
theories}.
\newblock {\em Chem. Phys. Lett.}, {\bf 157}(6):479--483, 1989.
\bibitem{Van2001}
{\sc Troy Van~Voorhis and Martin Head-Gordon}.
\newblock {\bf Two-body coupled cluster expansions}.
\newblock {\em J. Chem. Phys}, {\bf 115}(11):5033--5040, 2001.
\bibitem{Curtiss1991}
{\sc Larry~A Curtiss, Krishnan Raghavachari, Gary~W Trucks, and John~A Pople}.
\newblock {\bf Gaussian-2 theory for molecular energies of first-and second-row
compounds}.
\newblock {\em J. Chem. Phys}, {\bf 94}(11):7221--7230, 1991.
\bibitem{Curtiss1998}
{\sc Larry~A Curtiss, Krishnan Raghavachari, Paul~C Redfern, Vitaly Rassolov,
and John~A Pople}.
\newblock {\bf Gaussian-3 (G3) theory for molecules containing first and
second-row atoms}.
\newblock {\em J. Chem. Phys}, {\bf 109}(18):7764--7776, 1998.
\bibitem{Ohlinger2009}
{\sc William~S Ohlinger, Philip~E Klunzinger, Bernard~J Deppmeier, and Warren~J
Hehre}.
\newblock {\bf Efficient calculation of heats of formation}.
\newblock {\em J. Phys. Chem. A}, {\bf 113}(10):2165--2175, 2009.
\bibitem{Magnasco2009}
{\sc Roy McWeeny}.
\newblock {\em Post-Hartree-Fock Methods}, chapter~8, pages 133--139.
\newblock John Wiley \& Sons,Ltd.
\bibitem{Dacosta2011}
{\sc Herbert DaCosta and Maohong Fan}.
\newblock {\em Rate constant calculation for thermal reactions}.
\newblock Wiley Online Library, 2011.
\bibitem{Kohn1965}
{\sc Walter Kohn and Lu~Jeu Sham}.
\newblock {\bf Self-consistent equations including exchange and correlation
effects}.
\newblock {\em Physical review}, {\bf 140}(4A):A1133, 1965.
\bibitem{kohn1999nobel}
{\sc Walter Kohn}.
\newblock {\bf Nobel Lecture: Electronic structure of matter—wave functions
and density functionals}.
\newblock {\em Rev. Mod. Phys.}, {\bf 71}(5):1253, 1999.
\bibitem{Hohenberg1964}
{\sc Pierre Hohenberg and Walter Kohn}.
\newblock {\bf Inhomogeneous electron gas}.
\newblock {\em Physical Review}, {\bf 136}(3B):B864, 1964.
\bibitem{Levy1979}
{\sc Mel Levy}.
\newblock {\bf Universal variational functionals of electron densities,
first-order density matrices, and natural spin-orbitals and solution of the
v-representability problem}.
\newblock {\em Proc. Natl. Acad. Sci.}, {\bf 76}(12):6062--6065, 1979.
\bibitem{Thomas1927}
{\sc Llewellyn~H Thomas}.
\newblock {\bf The calculation of atomic fields}.
\newblock {\em Proc. Camb. Philos. Soc.}, {\bf 23}(5):542--548, 1927.
\bibitem{Fermi1928}
{\sc Enrico Fermi}.
\newblock {\bf Eine statistische methode zur bestimmung einiger eigenschaften
des atoms und ihre anwendung auf die theorie des periodischen systems der
elemente}.
\newblock {\em Zeitschrift f{\"u}r Physik}, {\bf 48}(1-2):73--79, 1928.
\bibitem{Herman1969}
{\sc Frank Herman, John~P Van~Dyke, and Irene~B Ortenburger}.
\newblock {\bf Improved statistical exchange approximation for inhomogeneous
many-electron systems}.
\newblock {\em Phys. Rev. Lett.}, {\bf 22}(16):807--811, 1969.
\bibitem{Perdew1996}
{\sc John~P Perdew and Kieron Burke}.
\newblock {\bf Comparison shopping for a gradient-corrected density
functional}.
\newblock {\em Int. J. Quantum Chem.}, {\bf 57}(3):309--319, 1996.
\bibitem{Becke1993}
{\sc Axel~D Becke}.
\newblock {\bf Density functional thermochemistry. III. The role of exact
exchange}.
\newblock {\em J. Chem. Phys.}, {\bf 98}(492):5648--5652, 1993.
\bibitem{Becke1988}
{\sc Axel~D Becke}.
\newblock {\bf Density-functional exchange-energy approximation with correct
asymptotic behavior}.
\newblock {\em Phys. Rev. A}, {\bf 38}(6):3098, 1988.
\bibitem{Lee1988}
{\sc Chengteh Lee, Weitao Yang, and Robert~G Parr}.
\newblock {\bf Development of the Colle-Salvetti correlation-energy formula
into a functional of the electron density}.
\newblock {\em Phys. Rev. B}, {\bf 37}(2):785--789, 1988.
\bibitem{Stephens1994}
{\sc Philip~J Stephens, Frank~J Devlin, Cary~F Chabalowski, and Michael~J
Frisch}.
\newblock {\bf Ab initio calculation of vibrational absorption and circular
dichroism spectra using density functional force fields}.
\newblock {\em J. Phys. Chem.}, {\bf 98}(45):11623--11627, 1994.
\bibitem{Adamo1999}
{\sc Carlo Adamo and Vincenzo Barone}.
\newblock {\bf Toward reliable density functional methods without adjustable
parameters: The PBE0 model}.
\newblock {\em J. Chem. Phys.}, {\bf 110}(13):6158--6170, 1999.
\bibitem{Henderson2009}
{\sc Thomas~M Henderson, Artur~F Izmaylov, Giovanni Scalmani, and Gustavo~E
Scuseria}.
\newblock {\bf Can short-range hybrids describe long-range-dependent
properties?}
\newblock {\em J. Chem. Phys.}, {\bf 131}(4):044108, 2009.
\bibitem{Krukau2006}
{\sc Aliaksandr~V Krukau, Oleg~A Vydrov, Artur~F Izmaylov, and Gustavo~E
Scuseria}.
\newblock {\bf Influence of the exchange screening parameter on the performance
of screened hybrid functionals}.
\newblock {\em J. Chem. Phys.}, {\bf 125}(22):224106, 2006.
\bibitem{Zhao2008}
{\sc Yan Zhao and Donald~G Truhlar}.
\newblock {\bf The M06 suite of density functionals for main group
thermochemistry, thermochemical kinetics, noncovalent interactions, excited
states, and transition elements: two new functionals and systematic testing
of four M06-class functionals and 12 other functionals}.
\newblock {\em Theor. Chem. Acc.}, {\bf 120}(1-3):215--241, 2008.
\bibitem{Li2018}
{\sc Chen Li, Xiao Zheng, Neil~Qiang Su, and Weitao Yang}.
\newblock {\bf Localized orbital scaling correction for systematic elimination
of delocalization error in density functional approximations}.
\newblock {\em Natl. Sci. Rev.}, {\bf 5}(2):203--215, 2018.
\bibitem{Foulkes1989}
{\sc W~Matthew~C Foulkes and Roger Haydock}.
\newblock {\bf Tight-binding models and density-functional theory}.
\newblock {\em Phys. Rev. B}, {\bf 39}(17):12520, 1989.
\bibitem{Porezag1995}
{\sc Dirk Porezag, Th~Frauenheim, Th~K{\"o}hler, Gotthard Seifert, and
R~Kaschner}.
\newblock {\bf Construction of tight-binding-like potentials on the basis of
density-functional theory: Application to carbon}.
\newblock {\em Phys. Rev. B}, {\bf 51}(19):12947, 1995.
\bibitem{Seifert1996}
{\sc G~Seifert, D~Porezag, and Th~Frauenheim}.
\newblock {\bf Calculations of molecules, clusters, and solids with a
simplified LCAO-DFT-LDA scheme}.
\newblock {\em Int. J. Quantum Chem.}, {\bf 58}(2):185--192, 1996.
\bibitem{Elstne2007}
{\sc Marcus Elstner, T~Frauenheim, J~McKelvey, and G~Seifert}.
\newblock {\bf Density functional tight binding: Contributions from the
american chemical society symposium}.
\newblock {\em J. Phys. Chem. A}, {\bf 111}(26):5607--5608, 2007.
\bibitem{Oliveira2009}
{\sc Augusto~F Oliveira, Gotthard Seifert, Thomas Heine, and H{\'e}lio~A
Duarte}.
\newblock {\bf Density-functional based tight-binding: an approximate DFT
method}.
\newblock {\em J. Braz. Chem. Soc., volume={20}, number={7},
pages={1193--1205}, year={2009}, publisher={SciELO Brasil}}.
\bibitem{Gaus2011}
{\sc Michael Gaus, Qiang Cui, and Marcus Elstner}.
\newblock {\bf DFTB3: extension of the self-consistent-charge
density-functional tight-binding method (SCC-DFTB)}.
\newblock {\em J. Chem. Theory Comput.}, {\bf 7}(4):931--948, 2011.
\bibitem{Mulliken1955}
{\sc Robert~S Mulliken}.
\newblock {\bf Electronic population analysis on LCAO--MO molecular wave
functions. I}.
\newblock {\em J. Chem. Phys.}, {\bf 23}(10):1833--1840, 1955.
\bibitem{Bader1985}
{\sc Richard F.~W. Bader}.
\newblock {\bf Atoms in molecules}.
\newblock {\em Acc. Chem. Res.}, {\bf 18}(1):9--15, 1985.
\bibitem{Bader1990}
{\sc Richard F~W Bader}.
\newblock {\em Atoms in molecules: a quantum theory}.
\newblock Oxford: Clarendon press, 1990.
\bibitem{Glendening1998}
{\sc Eric~D Glendening and Frank Weinhold}.
\newblock {\bf Natural resonance theory: II. Natural bond order and valency}.
\newblock {\em J. Comput. Chem}, {\bf 19}(6):610--627, 1998.
\bibitem{Glendening2012}
{\sc Eric~D Glendening, Clark~R Landis, and Frank Weinhold}.
\newblock {\bf Natural bond orbital methods}.
\newblock {\em Wiley Interdiscip. Rev. Comput. Mol. Sci.}, {\bf 2}(1):1--42,
2012.
\bibitem{Singh1984}
{\sc U~Chandra Singh and Peter~A Kollman}.
\newblock {\bf An approach to computing electrostatic charges for molecules}.
\newblock {\em J. Comput. Chem}, {\bf 5}(2):129--145, 1984.
\bibitem{Besler1990}
{\sc Brent~H Besler, Kenneth~M Merz~Jr, and Peter~A Kollman}.
\newblock {\bf Atomic charges derived from semiempirical methods}.
\newblock {\em J. Comput. Chem}, {\bf 11}(4):431--439, 1990.
\bibitem{Li1998}
{\sc Jiabo Li, Tianhai Zhu, Christopher~J Cramer, and Donald~G Truhlar}.
\newblock {\bf New class IV charge model for extracting accurate partial
charges from wave functions}.
\newblock {\em J. Phys. Chem. A}, {\bf 102}(10):1820--1831, 1998.
\bibitem{Kalinowski2004}
{\sc Jaroslaw~A Kalinowski, Bogdan Lesyng, Jason~D Thompson, Christopher~J
Cramer, and Donald~G Truhlar}.
\newblock {\bf Class IV charge model for the self-consistent charge
density-functional tight-binding method}.
\newblock {\em J. Phys. Chem. A}, {\bf 108}(13):2545--2549, 2004.
\bibitem{Kelly2005}
{\sc Casey~P Kelly, Christopher~J Cramer, and Donald~G Truhlar}.
\newblock {\bf Accurate partial atomic charges for high-energy molecules using
class IV charge models with the MIDI! basis set}.
\newblock {\em Theor. Chem. Acc.}, {\bf 113}(3):133--151, 2005.
\bibitem{Rapacioli2009corr}
{\sc Mathias Rapacioli, Fernand Spiegelman, Dahbia Talbi, Tzonka Mineva, Annick
Goursot, Thomas Heine, and Gotthard Seifert}.
\newblock {\bf Correction for dispersion and Coulombic interactions in
molecular clusters with density functional derived methods: Application to
polycyclic aromatic hydrocarbon clusters}.
\newblock {\em J. Chem. Phys.}, {\bf 130}(24):244304, 2009.
\bibitem{Mayer1983}
{\sc Istvan Mayer}.
\newblock {\bf Charge, bond order and valence in the AB initio SCF theory}.
\newblock {\em Chem. Phys. Lett.}, {\bf 97}(3):270--274, 1983.
\bibitem{Cances1997}
{\sc E~Cances, Benedetta Mennucci, and J~Tomasi}.
\newblock {\bf A new integral equation formalism for the polarizable continuum
model: Theoretical background and applications to isotropic and anisotropic
dielectrics}.
\newblock {\em J. Chem. Phys.}, {\bf 107}(8):3032--3041, 1997.
\bibitem{Lu2012}
{\sc Tian Lu and Feiwu Chen}.
\newblock {\bf Multiwfn: a multifunctional wavefunction analyzer}.
\newblock {\em J. Comput. Chem}, {\bf 33}(5):580--592, 2012.
\bibitem{Lewis1995}
{\sc James~P Lewis and Otto~F Sankey}.
\newblock {\bf Geometry and energetics of DNA basepairs and triplets from first
principles quantum molecular relaxations}.
\newblock {\em Biophys. J.}, {\bf 69}(3):1068--1076, 1995.
\bibitem{Gianturco1999}
{\sc FA~Gianturco, F~Paesani, MF~Laranjeira, V~Vassilenko, and MA~Cunha}.
\newblock {\bf Intermolecular forces from density functional theory. III. A
multiproperty analysis for the Ar($^1$S)-CO($^1\Sigma$) interaction}.
\newblock {\em J. Chem. Phys.}, {\bf 110}(16):7832--7845, 1999.
\bibitem{Elstner2001}
{\sc Marcus Elstner, Pavel Hobza, Thomas Frauenheim, S{\'a}ndor Suhai, and
Efthimios Kaxiras}.
\newblock {\bf Hydrogen bonding and stacking interactions of nucleic acid base
pairs: A density-functional-theory based treatment}.
\newblock {\em J. Chem. Phys.}, {\bf 114}(12):5149--5155, 2001.
\bibitem{Wu2002}
{\sc Qin Wu and Weitao Yang}.
\newblock {\bf Empirical correction to density functional theory for van der
Waals interactions}.
\newblock {\em J. Chem. Phys.}, {\bf 116}(2):515--524, 2002.
\bibitem{Grimme2004}
{\sc Stefan Grimme}.
\newblock {\bf Accurate description of van der Waals complexes by density
functional theory including empirical corrections}.
\newblock {\em J. Comput. Chem}, {\bf 25}(12):1463--1473, 2004.
\bibitem{Zimmerli2004}
{\sc Urs Zimmerli, Michele Parrinello, and Petros Koumoutsakos}.
\newblock {\bf Dispersion corrections to density functionals for water aromatic
interactions}.
\newblock {\em J. Chem. Phys.}, {\bf 120}(6):2693--2699, 2004.
\bibitem{Neumann2005}
{\sc Marcus~A Neumann and Marc-Antoine Perrin}.
\newblock {\bf Energy ranking of molecular crystals using density functional
theory calculations and an empirical van der Waals correction}.
\newblock {\em J. Phys. Chem. B}, {\bf 109}(32):15531--15541, 2005.
\bibitem{Goursot2007}
{\sc Annick Goursot, Tzonka Mineva, Ruslan Kevorkyants, and Dahbia Talbi}.
\newblock {\bf Interaction between n-alkane chains: Applicability of the
empirically corrected density functional theory for van der Waals complexes}.
\newblock {\em J. Chem. Theory Comput.}, {\bf 3}(3):755--763, 2007.
\bibitem{Frenkel2001}
{\sc Daan Frenkel and Berend Smit}.
\newblock {\em Understanding molecular simulation: from algorithms to
applications}, ~{\bf 1}.
\newblock Elsevier, 2001.
\bibitem{Jones1924}
{\sc John~Edward Jones}.
\newblock {\bf On the determination of molecular fields.—I. From the
variation of the viscosity of a gas with temperature}.
\newblock {\em Proc. Math. Phys. Eng. Sci.}, {\bf 106}(738):441--462, 1924.
\bibitem{Lennard1924}
{\sc John~Edward Lennard-Jones}.
\newblock {\bf On the determination of molecular fields. II. From the equation
of state of gas}.
\newblock {\em Proc. Roy. Soc. A}, {\bf 106}:463--477, 1924.
\bibitem{Morse1929}
{\sc Philip~M Morse}.
\newblock {\bf Diatomic molecules according to the wave mechanics. II.
Vibrational levels}.
\newblock {\em Physical review}, {\bf 34}(1):57--64, 1929.
\bibitem{Born1932}
{\sc Max Born and Joseph~E Mayer}.
\newblock {\bf Zur gittertheorie der ionenkristalle}.
\newblock {\em Zeitschrift f{\"u}r Physik}, {\bf 75}(1-2):1--18, 1932.
\bibitem{Stillinger1985}
{\sc Frank~H Stillinger and Thomas~A Weber}.
\newblock {\bf Computer simulation of local order in condensed phases of
silicon}.
\newblock {\em Phys. Rev. B}, {\bf 31}(8):5262--5271, 1985.
\bibitem{Kaplan2006}
{\sc Ilya~G Kaplan}.
\newblock {\em Intermolecular interactions: physical picture, computational
methods and model potentials}.
\newblock John Wiley \& Sons, 2006.
\bibitem{Bahar1997}
{\sc Ivet Bahar, Ali~Rana Atilgan, and Burak Erman}.
\newblock {\bf Direct evaluation of thermal fluctuations in proteins using a
single-parameter harmonic potential}.
\newblock {\em Fold Des.}, {\bf 2}(3):173--181, 1997.
\bibitem{Girifalco1959}
{\sc Louis~A Girifalco and Victor~G Weizer}.
\newblock {\bf Application of the Morse potential function to cubic metals}.
\newblock {\em Physical Review}, {\bf 114}(3):687--690, 1959.
\bibitem{Lennard1931}
{\sc John~Edward Lennard-Jones}.
\newblock {\bf Cohesion}.
\newblock {\em Proceedings of the Physical Society}, {\bf 43}(5):461--482,
1931.
\bibitem{Monticelli2013}
{\sc Luca Monticelli and D~Peter Tieleman}.
\newblock {\bf Force fields for classical molecular dynamics}.
\newblock In {\em Biomolecular simulations}, pages 197--213. Springer, 2013.
\bibitem{Metropolis1987}
{\sc N~Metropolis}.
\newblock {\bf The beginning of the Monte Carlo method}.
\newblock {\em Los Alamos Science}, {\bf 15}:125--130, 1987.
\bibitem{Kroese2014}
{\sc Dirk~P Kroese, Tim Brereton, Thomas Taimre, and Zdravko~I Botev}.
\newblock {\bf Why the Monte Carlo method is so important today}.
\newblock {\em Wiley Interdisciplinary Reviews: Computational Statistics}, {\bf
6}(6):386--392, 2014.
\bibitem{Rosenbluth1955}
{\sc Marshall~N Rosenbluth and Arianna~W Rosenbluth}.
\newblock {\bf Monte Carlo calculation of the average extension of molecular
chains}.
\newblock {\em J. Chem. Phys.}, {\bf 23}(2):356--359, 1955.
\bibitem{Binder1993}
{\sc Kurt Binder, Dieter Heermann, Lyle Roelofs, A~John Mallinckrodt, and Susan
McKay}.
\newblock {\bf Monte Carlo simulation in statistical physics}.
\newblock {\em Comput. Phys.}, {\bf 7}(2):156--157, 1993.
\bibitem{Baeurle2009}
{\sc Stephan~A Baeurle}.
\newblock {\bf Multiscale modeling of polymer materials using field-theoretic
methodologies: a survey about recent developments}.
\newblock {\em J. Math. Chem.}, {\bf 46}(2):363--426, 2009.
\bibitem{Alder1957}
{\sc Berni~Julian Alder and Thomas~Everett Wainwright}.
\newblock {\bf Phase transition for a hard sphere system}.
\newblock {\em J. Chem. Phys.}, {\bf 27}(5):1208--1209, 1957.
\bibitem{Gibson1960}
{\sc JB~Gibson, An~N Goland, M~Milgram, and GoHo Vineyard}.
\newblock {\bf Dynamics of radiation damage}.
\newblock {\em Physical Review}, {\bf 120}(4):1229--1253, 1960.
\bibitem{Rahman1964}
{\sc Aneesur Rahman}.
\newblock {\bf Correlations in the motion of atoms in liquid argon}.
\newblock {\em Physical review}, {\bf 136}(2A):A405--A411, 1964.
\bibitem{Allen2017}
{\sc Michael~P Allen and Dominic~J Tildesley}.
\newblock {\em Computer simulation of liquids}.
\newblock Oxford university press, 2017.
\bibitem{Cicccotti1987}
{\sc G~Cicccotti, D~Frenkel, and IR~McDonald}.
\newblock {\bf Simulations of liquids and solids--molecular dynamics and monte
carlo methods in statistical mechanics}, 1987.
\bibitem{Van1990}
{\sc Wilfred~F Van~Gunsteren and Herman~JC Berendsen}.
\newblock {\bf Computer simulation of molecular dynamics: methodology,
applications, and perspectives in chemistry}.
\newblock {\em Angew. Chem. Int. Ed.}, {\bf 29}(9):992--1023, 1990.
\bibitem{Berne1998}
{\sc Bruce~J Berne, Giovanni Ciccotti, and David~F Coker}.
\newblock {\em Classical and Quantum Dynamics in Condensed Phase Simulations:
Proceedings of the International School of Physics}.
\newblock World Scientific, 1998.
\bibitem{Tuckerman2000}
{\sc Mark~E Tuckerman and Glenn~J Martyna}.
\newblock {\bf Understanding modern molecular dynamics: techniques and
applications}, 2000.
\bibitem{Karplus2002}
{\sc Martin Karplus and J~Andrew McCammon}.
\newblock {\bf Molecular dynamics simulations of biomolecules}.
\newblock {\em Nat. Struct. Biol.}, {\bf 9}(9):646--652, 2002.
\bibitem{Rapaport2004}
{\sc Dennis~C Rapaport}.
\newblock {\em The art of molecular dynamics simulation}.
\newblock Cambridge university press, 2004.
\bibitem{Tavan2005}
{\sc Paul Tavan, Heiko Carstens, and Gerald Mathias}.
\newblock {\bf Molecular dynamics simulations of proteins and peptides:
Problems, achievements, and perspectives}.
\newblock {\em Protein Folding Handbook}, pages 1170--1195, 2005.
\bibitem{Van2006}
{\sc Wilfred~F van Gunsteren, Dirk Bakowies, Riccardo Baron, Indira
Chandrasekhar, Markus Christen, Xavier Daura, Peter Gee, Daan~P Geerke, Alice
Gl{\"a}ttli, Philippe~H H{\"u}nenberger, et~al.}
\newblock {\bf Biomolecular modeling: goals, problems, perspectives}.
\newblock {\em Angew. Chem. Int. Ed.}, {\bf 45}(25):4064--4092, 2006.
\bibitem{Parrinello1980}
{\sc Michele Parrinello and Aneesur Rahman}.
\newblock {\bf Crystal structure and pair potentials: A molecular-dynamics
study}.
\newblock {\em Phys. Rev. Lett.}, {\bf 45}(14):1196--1199, 1980.
\bibitem{Ballone1988}
{\sc Pietro Ballone, Wanda Andreoni, Roberto Car, and Michele Parrinello}.
\newblock {\bf Equilibrium structures and finite temperature properties of
silicon microclusters from ab initio molecular-dynamics calculations}.
\newblock {\em Phys. Rev. Lett.}, {\bf 60}(4):271--274, 1988.
\bibitem{Gutierrez1996}
{\sc Rafael Gutierrez, Thomas Frauenheim, Thomas K{\"o}hler, and Gothard
Seifert}.
\newblock {\bf Stability of silicon carbide structures: from clusters to solid
surfaces}.
\newblock {\em J. Mater. Chem. A .}, {\bf 6}(10):1657--1663, 1996.
\bibitem{Briant1975}
{\sc CL~Briant and JJ~Burton}.
\newblock {\bf Molecular dynamics study of the structure and thermodynamic
properties of argon microclusters}.
\newblock {\em J. Chem. Phys.}, {\bf 63}(5):2045--2058, 1975.
\bibitem{Postma1982}
{\sc Johan~PM Postma, Herman~JC Berendsen, and Jan~R Haak}.
\newblock {\bf Thermodynamics of cavity formation in water. A molecular
dynamics study}.
\newblock In {\em Faraday Symposia of the Chemical Society}, ~{\bf 17}, pages
55--67. Royal Society of Chemistry, 1982.
\bibitem{Honeycutt1987}
{\sc J~Dana Honeycutt and Hans~C Andersen}.
\newblock {\bf Molecular dynamics study of melting and freezing of small
Lennard-Jones clusters}.
\newblock {\em Journal of Physical Chemistry}, {\bf 91}(19):4950--4963, 1987.
\bibitem{Dang1997}
{\sc Liem~X Dang and Tsun-Mei Chang}.
\newblock {\bf Molecular dynamics study of water clusters, liquid, and
liquid--vapor interface of water with many-body potentials}.
\newblock {\em J. Chem. Phys.}, {\bf 106}(19):8149--8159, 1997.
\bibitem{Coveney2016}
{\sc Peter~V Coveney and Shunzhou Wan}.
\newblock {\bf On the calculation of equilibrium thermodynamic properties from
molecular dynamics}.
\newblock {\em Phys. Chem. Chem. Phys.}, {\bf 18}(44):30236--30240, 2016.
\bibitem{Charati1998}
{\sc SG~Charati and SA~Stern}.
\newblock {\bf Diffusion of gases in silicone polymers: molecular dynamics
simulations}.
\newblock {\em Macromolecules}, {\bf 31}(16):5529--5535, 1998.
\bibitem{Yeh2004}
{\sc In-Chul Yeh and Gerhard Hummer}.
\newblock {\bf System-size dependence of diffusion coefficients and viscosities
from molecular dynamics simulations with periodic boundary conditions}.
\newblock {\em J. Phys. Chem. B}, {\bf 108}(40):15873--15879, 2004.
\bibitem{Braga2014}
{\sc Carlos Braga, Amparo Galindo, and Erich~A M{\"u}ller}.
\newblock {\bf Nonequilibrium molecular dynamics simulation of diffusion at the
liquid-liquid interface}.
\newblock {\em J. Chem. Phys.}, {\bf 141}(15):154101, 2014.
\bibitem{Pranami2015}
{\sc Gaurav Pranami and Monica~H Lamm}.
\newblock {\bf Estimating error in diffusion coefficients derived from
molecular dynamics simulations}.
\newblock {\em J. Chem. Theory Comput.}, {\bf 11}(10):4586--4592, 2015.
\bibitem{Mondello1997}
{\sc Maurizio Mondello and Gary~S Grest}.
\newblock {\bf Viscosity calculations of n-alkanes by equilibrium molecular
dynamics}.
\newblock {\em J. Chem. Phys.}, {\bf 106}(22):9327--9336, 1997.
\bibitem{Hess2002}
{\sc Berk Hess}.
\newblock {\bf Determining the shear viscosity of model liquids from molecular
dynamics simulations}.
\newblock {\em J. Chem. Phys.}, {\bf 116}(1):209--217, 2002.
\bibitem{Zhang2015}
{\sc Yong Zhang, Akihito Otani, and Edward~J Maginn}.
\newblock {\bf Reliable viscosity calculation from equilibrium molecular
dynamics simulations: A time decomposition method}.
\newblock {\em J. Chem. Theory Comput.}, {\bf 11}(8):3537--3546, 2015.
\bibitem{Aragon1976}
{\sc SR~Aragon and R~Pecora}.
\newblock {\bf Fluorescence correlation spectroscopy as a probe of molecular
dynamics}.
\newblock {\em J. Chem. Phys.}, {\bf 64}(4):1791--1803, 1976.
\bibitem{Vuilleumier1999}
{\sc Rodolphe Vuilleumier and Daniel Borgis}.
\newblock {\bf Transport and spectroscopy of the hydrated proton: a molecular
dynamics study}.
\newblock {\em J. Chem. Phys.}, {\bf 111}(9):4251--4266, 1999.
\bibitem{Pavone2006}
{\sc Michele Pavone, Giuseppe Brancato, Giovanni Morelli, and Vincenzo Barone}.
\newblock {\bf Spectroscopic properties in the liquid phase: combining
high-level ab initio calculations and classical molecular dynamics}.
\newblock {\em ChemPhysChem}, {\bf 7}(1):148--156, 2006.
\bibitem{Brancato2006}
{\sc Giuseppe Brancato, Nadia Rega, and Vincenzo Barone}.
\newblock {\bf A quantum mechanical/molecular dynamics/mean field study of
acrolein in aqueous solution: analysis of H bonding and bulk effects on
spectroscopic properties}.
\newblock {\em J. Chem. Phys.}, {\bf 125}(16):164515, 2006.
\bibitem{Beck2000}
{\sc Michael~H Beck, Andreas J{\"a}ckle, Graham~A Worth, and H-D Meyer}.
\newblock {\bf The multiconfiguration time-dependent Hartree (MCTDH) method: a
highly efficient algorithm for propagating wavepackets}.
\newblock {\em Phys. Rep.}, {\bf 324}(1):1--105, 2000.
\bibitem{Wang2003}
{\sc Haobin Wang and Michael Thoss}.
\newblock {\bf Multilayer formulation of the multiconfiguration time-dependent
Hartree theory}.
\newblock {\em J. Chem. Phys.}, {\bf 119}(3):1289--1299, 2003.
\bibitem{Wei1994}
{\sc Hua Wei and Tucker Carrington~Jr}.
\newblock {\bf Discrete variable representations of complicated kinetic energy
operators}.
\newblock {\em J. Chem. Phys.}, {\bf 101}(2):1343--1360, 1994.
\bibitem{Light2000}
{\sc John~C Light and Tucker Carrington~Jr}.
\newblock {\bf Discrete-variable representations and their utilization}.
\newblock {\em Advances in Chemical Physics}, {\bf 114}:263--310, 2000.
\bibitem{Batina1991}
{\sc John~T Batina}.
\newblock {\bf Unsteady Euler algorithm with unstructured dynamic mesh for
complex-aircraft aerodynamic analysis}.
\newblock {\em AIAA J.}, {\bf 29}(3):327--333, 1991.
\bibitem{Butcher2008}
{\sc John~Charles Butcher and Nicolette Goodwin}.
\newblock {\em Numerical methods for ordinary differential equations}, ~{\bf
2}.
\newblock Wiley Online Library, 2008.
\bibitem{Gear1966}
{\sc Charles~William Gear}.
\newblock {\bf The numerical integration of ordinary differential equations of
various orders}.
\newblock Technical report, Argonne National Lab., Ill., 1966.
\bibitem{Diethelm2002}
{\sc Kai Diethelm, Neville~J Ford, and Alan~D Freed}.
\newblock {\bf A predictor-corrector approach for the numerical solution of
fractional differential equations}.
\newblock {\em Nonlinear Dyn.}, {\bf 29}(1-4):3--22, 2002.
\bibitem{Runge1895}
{\sc Carl Runge}.
\newblock {\bf {\"U}ber die numerische Aufl{\"o}sung von
Differentialgleichungen}.
\newblock {\em Math. Ann}, {\bf 46}(2):167--178, 1895.
\bibitem{Kutta1901}
{\sc Wilhelm Kutta}.
\newblock {\bf Beitrag zur naherungsweisen Integration totaler
Differentialgleichungen}.
\newblock {\em Z. Math. Phys.}, {\bf 46}:435--453, 1901.
\bibitem{Butcher1996}
{\sc John~Charles Butcher}.
\newblock {\bf A history of Runge-Kutta methods}.
\newblock {\em Appl. Numer. Math.}, {\bf 20}(3):247--260, 1996.
\bibitem{Butcher2015}
{\sc JC~Butcher}.
\newblock {\bf Runge--Kutta methods for ordinary differential equations}.
\newblock In {\em Numerical Analysis and Optimization}, pages 37--58. Springer,
2015.
\bibitem{Verlet1967}
{\sc Loup Verlet}.
\newblock {\bf Computer" experiments" on classical fluids. I. Thermodynamical
properties of Lennard-Jones molecules}.
\newblock {\em Physical review}, {\bf 159}(1):98--103, 1967.
\bibitem{Fraige2004}
{\sc FY~Fraige and PA~Langston}.
\newblock {\bf Integration schemes and damping algorithms in distinct element
models}.
\newblock {\em Advanced Powder Technology}, {\bf 15}(2):227--245, 2004.
\bibitem{Swope1982}
{\sc William~C Swope, Hans~C Andersen, Peter~H Berens, and Kent~R Wilson}.
\newblock {\bf A computer simulation method for the calculation of equilibrium
constants for the formation of physical clusters of molecules: Application to
small water clusters}.
\newblock {\em J. Chem. Phys.}, {\bf 76}(1):637--649, 1982.
\bibitem{Ray1981}
{\sc John~R Ray and HW~Graben}.
\newblock {\bf Direct calculation of fluctuation formulae in the microcanonical
ensemble}.
\newblock {\em Mol. Phys.}, {\bf 43}(6):1293--1297, 1981.
\bibitem{Ray1999}
{\sc John~R Ray and Hongwei Zhang}.
\newblock {\bf Correct microcanonical ensemble in molecular dynamics}.
\newblock {\em Phys. Rev. E}, {\bf 59}(5):4781--4785, 1999.
\bibitem{Nose1984}
{\sc Shuichi Nos{\'e}}.
\newblock {\bf A unified formulation of the constant temperature molecular
dynamics methods}.
\newblock {\em J. Chem. Phys.}, {\bf 81}(1):511--519, 1984.
\bibitem{Nose1984M}
{\sc Sh{\=u}ichi Nos{\'e}}.
\newblock {\bf A molecular dynamics method for simulations in the canonical
ensemble}.
\newblock {\em Mol. Phys.}, {\bf 52}(2):255--268, 1984.
\bibitem{Hoover1985}
{\sc William~G Hoover}.
\newblock {\bf Canonical dynamics: Equilibrium phase-space distributions}.
\newblock {\em Phys. Rev. A}, {\bf 31}(3):1695--1697, 1985.
\bibitem{Hunenberger2005}
{\sc Philippe~H H{\"u}nenberger}.
\newblock {\bf Thermostat algorithms for molecular dynamics simulations}.
\newblock In {\em Advanced computer simulation}, pages 105--149. Springer,
2005.
\bibitem{Torrie1977}
{\sc Glenn~M Torrie and John~P Valleau}.
\newblock {\bf Nonphysical sampling distributions in Monte Carlo free-energy
estimation: Umbrella sampling}.
\newblock {\em J. Comput. Phys.}, {\bf 23}(2):187--199, 1977.
\bibitem{Hansmann1993}
{\sc Ulrich~HE Hansmann and Yuko Okamoto}.
\newblock {\bf Prediction of peptide conformation by multicanonical algorithm:
New approach to the multiple-minima problem}.
\newblock {\em J. Comput. Chem}, {\bf 14}(11):1333--1338, 1993.
\bibitem{Marchi1999}
{\sc Massimo Marchi and Pietro Ballone}.
\newblock {\bf Adiabatic bias molecular dynamics: a method to navigate the
conformational space of complex molecular systems}.
\newblock {\em J. Chem. Phys.}, {\bf 110}(8):3697--3702, 1999.
\bibitem{Bartels2000}
{\sc Christian Bartels}.
\newblock {\bf Analyzing biased Monte Carlo and molecular dynamics
simulations}.
\newblock {\em Chem. Phys. Lett.}, {\bf 331}(5-6):446--454, 2000.
\bibitem{Darve2001}
{\sc Eric Darve and Andrew Pohorille}.
\newblock {\bf Calculating free energies using average force}.
\newblock {\em J. Chem. Phys.}, {\bf 115}(20):9169--9183, 2001.
\bibitem{Laio2002}
{\sc Alessandro Laio and Michele Parrinello}.
\newblock {\bf Escaping free-energy minima}.
\newblock {\em Proc. Natl. Acad. Sci.}, {\bf 99}(20):12562--12566, 2002.
\bibitem{Iannuzzi2003}
{\sc Marcella Iannuzzi, Alessandro Laio, and Michele Parrinello}.
\newblock {\bf Efficient exploration of reactive potential energy surfaces
using Car-Parrinello molecular dynamics}.
\newblock {\em Phys. Rev. Lett.}, {\bf 90}(23):238302, 2003.
\bibitem{Barducci2011}
{\sc Alessandro Barducci, Massimiliano Bonomi, and Michele Parrinello}.
\newblock {\bf Metadynamics}.
\newblock {\em Wiley Interdiscip. Rev. Comput. Mol. Sci.}, {\bf 1}(5):826--843,
2011.
\bibitem{Kirkpatrick1983}
{\sc Scott Kirkpatrick, C~Daniel Gelatt, and Mario~P Vecchi}.
\newblock {\bf Optimization by simulated annealing}.
\newblock {\em science}, {\bf 220}(4598):671--680, 1983.
\bibitem{Van1987}
{\sc Peter~JM Van~Laarhoven and Emile~HL Aarts}.
\newblock {\bf Simulated annealing}.
\newblock In {\em Simulated annealing: Theory and applications}, pages 7--15.
Springer, 1987.
\bibitem{Swendsen1986}
{\sc Robert~H Swendsen and Jian-Sheng Wang}.
\newblock {\bf Replica Monte Carlo simulation of spin-glasses}.
\newblock {\em Phys. Rev. Lett.}, {\bf 57}(21):2607, 1986.
\bibitem{Geyer1991}
{\sc Charles~J Geyer et~al.}
\newblock {\bf Computing science and statistics: Proceedings of the 23rd
Symposium on the Interface}.
\newblock {\em American Statistical Association, New York}, {\bf 156}, 1991.
\bibitem{Hukushima1996}
{\sc Koji Hukushima and Koji Nemoto}.
\newblock {\bf Exchange Monte Carlo method and application to spin glass
simulations}.
\newblock {\em J. Phys. Soc. Jpn.}, {\bf 65}(6):1604--1608, 1996.
\bibitem{Falcioni1999}
{\sc Marco Falcioni and Michael~W Deem}.
\newblock {\bf A biased Monte Carlo scheme for zeolite structure solution}.
\newblock {\em J. Chem. Phys.}, {\bf 110}(3):1754--1766, 1999.
\bibitem{Earl2005}
{\sc David~J Earl and Michael~W Deem}.
\newblock {\bf Parallel tempering: Theory, applications, and new perspectives}.
\newblock {\em Phys. Chem. Chem. Phys.}, {\bf 7}(23):3910--3916, 2005.
\bibitem{Sugita1999}
{\sc Yuji Sugita and Yuko Okamoto}.
\newblock {\bf Replica-exchange molecular dynamics method for protein folding}.
\newblock {\em Chem. Phys. Lett.}, {\bf 314}(1-2):141--151, 1999.
\bibitem{Hartke1993}
{\sc Bernd Hartke}.
\newblock {\bf Global geometry optimization of clusters using genetic
algorithms}.
\newblock {\em J. Phys. Chem.}, {\bf 97}(39):9973--9976, 1993.
\bibitem{Unger1993}
{\sc Ron Unger and John Moult}.
\newblock {\bf Genetic algorithms for protein folding simulations}.
\newblock {\em J. Mol. Biol., volume={231}, number={1}, pages={75--81},
year={1993}, publisher={Elsevier}}.
\bibitem{Sivanandam2008}
{\sc SN~Sivanandam and SN~Deepa}.
\newblock {\bf Genetic algorithms}.
\newblock In {\em Introduction to genetic algorithms}, pages 15--37. Springer,
2008.
\bibitem{Toledo2014}
{\sc Claudio Fabiano~Motta Toledo, L~Oliveira, and Paulo~Morelato
Fran{\c{c}}a}.
\newblock {\bf Global optimization using a genetic algorithm with
hierarchically structured population}.
\newblock {\em J. Comput. Appl. Math.}, {\bf 261}:341--351, 2014.
\bibitem{deMonNano2009}
{\sc T~Heine, M~Rapacioli, S~Patchkovskii, J~Frenzel, A~Koster, P~Calaminici,
HA~Duarte, S~Escalante, R~Flores-Moreno, and A~Goursot}.
\newblock {\bf deMonNano}, 2009.
\bibitem{Gaus2013para}
{\sc Michael Gaus, Albrecht Goez, and Marcus Elstner}.
\newblock {\bf Parametrization and benchmark of DFTB3 for organic molecules}.
\newblock {\em J. Chem. Theory Comput.}, {\bf 9}(1):338--354, 2013.
\bibitem{Thompson2003}
{\sc Jason~D Thompson, Christopher~J Cramer, and Donald~G Truhlar}.
\newblock {\bf Parameterization of charge model 3 for AM1, PM3, BLYP, and
B3LYP}.
\newblock {\em J. Comput. Chem.}, {\bf 24}(11):1291--1304, 2003.
\bibitem{Zhechkov2005}
{\sc Lyuben Zhechkov, Thomas Heine, Serguei Patchkovskii, Gotthard Seifert, and
Helio~A Duarte}.
\newblock {\bf An efficient a posteriori treatment for dispersion interaction
in density-functional-based tight binding}.
\newblock {\em J. Chem. Theory Comput.}, {\bf 1}(5):841--847, 2005.
\bibitem{Simon2012}
{\sc Aude Simon, Mathias Rapacioli, Jo{\"e}lle Mascetti, and Fernand
Spiegelman}.
\newblock {\bf Vibrational Spectroscopy and Molecular Dynamics of Water
Monomers and Dimers Adsorbed on Polycyclic Aromatic Hydrocarbons}.
\newblock {\em Phys. Chem. Chem. Phys.}, {\bf 14}(19):6771--6786, 2012.
\bibitem{Odutola1980}
{\sc JA~Odutola and TR~Dyke}.
\newblock {\bf Partially deuterated water dimers: Microwave spectra and
structure}.
\newblock {\em J. Chem. Phys.}, {\bf 72}(9):5062--5070, 1980.
\bibitem{Sugita2000}
{\sc Yuji Sugita and Yuko Okamoto}.
\newblock {\bf Replica-exchange multicanonical algorithm and multicanonical
replica-exchange method for simulating systems with rough energy landscape}.
\newblock {\em Chem. Phys. Lett.}, {\bf 329}(3-4):261--270, 2000.
\bibitem{Douady2009}
{\sc Julie Douady, Florent Calvo, and Fernand Spiegelman}.
\newblock {\bf Effect of an ionic impurity on the caloric curves of water
clusters}.
\newblock {\em Eur. Phys. J. D}, {\bf 52}(1-3):47--50, 2009.
\bibitem{Wolken2000}
{\sc Jill~K Wolken and Franti{\v{s}}ek Ture{\v{c}}ek}.
\newblock {\bf Proton affinity of uracil. A computational study of protonation
sites}.
\newblock {\em J. Am. Soc. Mass Spectrom.}, {\bf 11}(12):1065--1071, 2000.
\bibitem{Pedersen2014}
{\sc Sara~{\O}vad Pedersen, Camilla~Skinnerup Byskov, Frantisek Turecek, and
Steen~Br{\o}ndsted Nielsen}.
\newblock {\bf Structures of protonated thymine and uracil and their
monohydrated gas-phase ions from ultraviolet action spectroscopy and theory}.
\newblock {\em J. Phys. Chem. A}, {\bf 118}(24):4256--4265, 2014.
\bibitem{Weigend2005}
{\sc Florian Weigend and Reinhart Ahlrichs}.
\newblock {\bf Balanced basis sets of split valence, triple zeta valence and
quadruple zeta valence quality for H to Rn: design and assessment of
accuracy}.
\newblock {\em Phys. Chem. Chem. Phys.}, {\bf 7}(18):3297--3305, 2005.
\bibitem{Weigend2006}
{\sc Florian Weigend}.
\newblock {\bf Accurate Coulomb-fitting basis sets for H to Rn}.
\newblock {\em Phys. Chem. Chem. Phys.}, {\bf 8}(9):1057--1065, 2006.
\bibitem{GaussianCode}
{\sc M.~J. Frisch, G.~W. Trucks, H.~B. Schlegel, G.~E. Scuseria, M.~A. Robb,
J.~R. Cheeseman, G.~Scalmani, V.~Barone, B.~Mennucci, G.~A. Petersson, and
{\it et. al.}}
\bibitem{Boys2002}
{\sc SF~Boys and F~Bernardi}.
\newblock {\bf The calculation of small molecular interactions by the
differences of separate total energies. Some procedures with reduced errors}.
\newblock {\em Mol. Phys.}, {\bf 100}(1):65--73, 2002.
\bibitem{Keesee1989}
{\sc R.~G. Keesee}.
\newblock
\href{https://agupubs.onlinelibrary.wiley.com/doi/abs/10.1029/JD094iD12p14683}{{\bf
Nucleation and particle formation in the upper atmosphere}}.
\newblock {\em J. Geophys. Res. Atmos.}, {\bf 94}(D12):14683--14692, 1989.
\bibitem{Gilligan2000}
{\sc J~J Gilligan, DJ~Moody, and A~W Castleman}.
\newblock {\bf Reactions of protonated water clusters with chlorine nitrate
revisited}.
\newblock {\em Z. Phys. Chem.}, {\bf 214}(10):1383--1391, 2000.
\bibitem{Sennikov2005}
{\sc Petr~G Sennikov, Stanislav~K Ignatov, and Otto Schrems}.
\newblock {\bf Complexes and clusters of water relevant to atmospheric
chemistry: H2O complexes with oxidants}.
\newblock {\em ChemPhysChem}, {\bf 6}(3):392--412, 2005.
\bibitem{Cabellos2016}
{\sc Alba Vargas-Caamal, Jose~Luis Cabellos, Filiberto Ortiz-Chi, Henry~S.
Rzepa, Albeiro Restrepo, and Gabriel Merino}.
\newblock {\bf How Many Water Molecules Does it Take to Dissociate HCl?}
\newblock {\em Chem. Eur. J.}, {\bf 22}(8):2812--2818, 2016.
\bibitem{Orabi2013}
{\sc Esam~A Orabi and Guillaume Lamoureux}.
\newblock {\bf Polarizable interaction model for liquid, supercritical, and
aqueous ammonia}.
\newblock {\em J. Chem. Theory Comput.}, {\bf 9}(4):2035--2051, 2013.
\bibitem{Bommer2016}
{\sc Martin Bommer, Ana-Nicoleta Bondar, Athina Zouni, Holger Dobbek, and
Holger Dau}.
\newblock {\bf Crystallographic and computational analysis of the barrel part
of the PsbO protein of photosystem II: Carboxylate--water clusters as
putative proton transfer relays and structural switches}.
\newblock {\em Biochemistry}, {\bf 55}(33):4626--4635, 2016.
\bibitem{Rodgers2003}
{\sc SD~Rodgers and SB~Charnley}.
\newblock {\bf Chemical evolution in protostellar envelopes: Cocoon chemistry}.
\newblock {\em Astrophys. J.}, {\bf 585}(1):355, 2003.
\bibitem{Van2004}
{\sc Ewine~F Van~Dishoeck}.
\newblock {\bf ISO spectroscopy of gas and dust: from molecular clouds to
protoplanetary disks}.
\newblock {\em Annu. Rev. Astrophys. J.}, {\bf 42}, 2004.
\bibitem{Gibb2004}
{\sc EL~Gibb, DCB Whittet, ACA Boogert, and AGGM Tielens}.
\newblock {\bf Interstellar ice: the infrared space observatory legacy}.
\newblock {\em Astrophys. J., Suppl. Ser.}, {\bf 151}(1):35, 2004.
\bibitem{Parise2005}
{\sc B~Parise, C~Ceccarelli, and S~Maret}.
\newblock {\bf Theoretical HDO emission from low-mass protostellar envelopes}.
\newblock {\em Astron. Astrophys.}, {\bf 441}(1):171--179, 2005.
\bibitem{Boogert2015}
{\sc AC~Adwin Boogert, Perry~A Gerakines, and Douglas~CB Whittet}.
\newblock {\bf Observations of the icy universe}.
\newblock {\em Annu. Rev. Astron. Astrophys.}, {\bf 53}, 2015.
\bibitem{Dulieu2010}
{\sc F~Dulieu, L~Amiaud, E~Congiu, J-H Fillion, E~Matar, A~Momeni,
V~Pirronello, and JL~Lemaire}.
\newblock {\bf Experimental evidence for water formation on interstellar dust
grains by hydrogen and oxygen atoms}.
\newblock {\em Astron. Astrophys.}, {\bf 512}:A30, 2010.
\bibitem{Michoulier2018}
{\sc Eric Michoulier, Nadia~Ben Amor, Mathias Rapacioli, Jennifer~A Noble,
Jo{\"e}lle Mascetti, C{\'e}line Toubin, and Aude Simon}.
\newblock {\bf Theoretical determination of adsorption and ionisation energies
of polycyclic aromatic hydrocarbons on water ice}.
\newblock {\em Phys. Chem. Chem. Phys.}, {\bf 20}(17):11941--11953, 2018.
\bibitem{Kulmala2004}
{\sc M.~Kulmala, H.~Vehkamäki, T.~Petäjä, M.~Dal Maso, A.~Lauri, V.-M.
Kerminen, W.~Birmili, and P.H. McMurry}.
\newblock {\bf Formation and growth rates of ultrafine atmospheric particles: A
review of observations}.
\newblock {\em J. Aerosol Sci.}, {\bf 35}(2):143--176, 2004.
\bibitem{Ziereis1986}
{\sc H~Ziereis and F~Arnold}.
\newblock {\bf Gaseous ammonia and ammonium ions in the free troposphere}.
\newblock {\em Nature}, {\bf 321}(6069):503--505, 1986.
\bibitem{Perkins1984}
{\sc Mark~D Perkins and Fred~L Eisele}.
\newblock {\bf First mass spectrometric measurements of atmospheric ions at
ground level}.
\newblock {\em J. Geophys. Res. Atmos.}, {\bf 89}(D6):9649--9657, 1984.
\bibitem{Arnold1997}
{\sc F~Arnold, KH~Wohlfrom, J~Schneider, M~Klemm, T~Stilp, and F~Grimm}.
\newblock {\bf Atmospheric measurements of aerosol precursor gases in the upper
troposphere and lower stratosphere}.
\newblock {\em J. Aerosol Sci.}, {\bf 1001}(28):S65--S66, 1997.
\bibitem{Herbine1985}
{\sc P~Herbine and TR~Dyke}.
\newblock {\bf Rotational spectra and structure of the ammonia--water complex}.
\newblock {\em J. Chem. Phys.}, {\bf 83}(8):3768--3774, 1985.
\bibitem{Stockman1992}
{\sc Paul~A Stockman, Roger~E Bumgarner, Sakae Suzuki, and Geoffrey~A Blake}.
\newblock {\bf Microwave and tunable far-infrared laser spectroscopy of the
ammonia-water dimer}.
\newblock {\em J. Chem. Phys.}, {\bf 96}(4):2496--2510, 1992.
\bibitem{Hulthe1997}
{\sc Gustaf Hulthe, Gunnar Stenhagen, Olof Wennerstr{\"o}m, and Carl-Henrik
Ottosson}.
\newblock {\bf Water clusters studied by electrospray mass spectrometry}.
\newblock {\em J. Chromatogr. A}, {\bf 777}(1):155--165, 1997.
\bibitem{Wang1998}
{\sc Yih-Sheng Wang, Hai-Chou Chang, Jyh-Chiang Jiang, Sheng~H. Lin, Yuan~T.
Lee, and Huan-Cheng Chang}.
\newblock {\bf Structures and isomeric transitions of NH$_4^+$(H$_2$O)$_{3-6}$:
from single to double rings}.
\newblock {\em J. Am. Chem. Soc.}, {\bf 120}(34):8777--8788, 1998.
\bibitem{Chang1998}
{\sc Hai-Chou Chang, Yih-Sheng Wang, Yuan~T Lee, and Huan-Cheng Chang}.
\newblock {\bf Studying protonated ion hydration by infrared spectroscopy of
size-selected NH$_4^+$(H$_2$O)$_n$ clusters in a free jet expansion}.
\newblock {\em Int. J. Mass Spectrom.}, {\bf 179}:91--102, 1998.
\bibitem{Jiang1999}
{\sc J~C Jiang, H-C Chang, YT~Lee, and SH~Lin}.
\newblock {\bf Ab initio studies of NH$_4^+$(H$_2$O)$_{1-5}$ and the influence
of hydrogen-bonding nonadditivity on geometries and vibrations}.
\newblock {\em J. Phys. Chem. A}, {\bf 103}(16):3123--3135, 1999.
\bibitem{Hvelplund2010}
{\sc Preben Hvelplund, Theo Kurten, Kristian St{\o}chkel, Mauritz~Johan Ryding,
Steen~Br{\o}ndsted Nielsen, and Einar Uggerud}.
\newblock {\bf Stability and structure of protonated clusters of ammonia and
water, H$^+$(NH$_3$)$_m$(H$_2$O)$_n$}.
\newblock {\em J. Phys. Chem. A}, {\bf 114}(27):7301--7310, 2010.
\bibitem{Douady2008}
{\sc Julie Douady, Florent Calvo, and Fernand Spiegelman}.
\newblock {\bf Structure, stability, and infrared spectroscopy of
(H$_2$O)$_n$NH$_4^+$ clusters: A theoretical study at zero and finite
temperature}.
\newblock {\em J. Chem. Phys.}, {\bf 129}(15):154305, 2008.
\bibitem{Morrell2010}
{\sc Thomas~E Morrell and George~C Shields}.
\newblock {\bf Atmospheric implications for formation of clusters of ammonium
and 1-10 water molecules}.
\newblock {\em J. Phys. Chem. A}, {\bf 114}(12):4266--4271, 2010.
\bibitem{Bacelo2002}
{\sc Daniel~E Bacelo}.
\newblock {\bf Theoretical study of microscopic solvation of ammonia in water
clusters: NH$_3$(H$_2$O)$_n$, $n=$ 3, 4}.
\newblock {\em J. Phys. Chem. A}, {\bf 106}(46):11190--11196, 2002.
\bibitem{Galashev2013}
{\sc AE~Galashev}.
\newblock {\bf A computer study of ammonium adsorption on water clusters}.
\newblock {\em Russ. J. Phys. Chem. B}, {\bf 7}(4):502--508, 2013.
\bibitem{Lee1996}
{\sc Chengteh Lee, George Fitzgerald, Marc Planas, and Juan~J Novoa}.
\newblock {\bf Ionization of bases in water: Structure and stability of the
NH$_4^+$ $\cdots$ OH$^-$ ionic forms in ammonia-water clusters}.
\newblock {\em J. Phys. Chem.}, {\bf 100}(18):7398--7404, 1996.
\bibitem{Skurski1998}
{\sc Piotr Skurski and Maciej Gutowski}.
\newblock {\bf Theoretical study of the dipole-bound anion (H$_2$O $\ldots$
NH$_3$)$^-$}.
\newblock {\em J. Chem. Phys.}, {\bf 108}(15):6303--6311, 1998.
\bibitem{Donaldson1999}
{\sc DJ~Donaldson}.
\newblock {\bf Adsorption of atmospheric gases at the air- water interface. I.
NH$_3$}.
\newblock {\em J. Phys. Chem. A}, {\bf 103}(1):62--70, 1999.
\bibitem{Sadlej1999}
{\sc J~Sadlej, R~Moszynski, J~Cz Dobrowolski, and AP~Mazurek}.
\newblock {\bf Structure and energetics of the weakly bound NH$_3$ $\cdots$
H$_2$O complex}.
\newblock {\em J. Phys. Chem. A}, {\bf 103}(42):8528--8536, 1999.
\bibitem{Kozack1992polar}
{\sc RE~Kozack and PC~Jordan}.
\newblock {\bf Polarizability effects in a four-charge model for water}.
\newblock {\em J. Chem. Phys.}, {\bf 96}(4):3120--3130, 1992.
\bibitem{Pei2015}
{\sc Shi-Tu Pei, Shuai Jiang, Yi-Rong Liu, Teng Huang, Kang-Ming Xu, Hui Wen,
Yu-Peng Zhu, and Wei Huang}.
\newblock {\bf Properties of ammonium ion--water clusters: analyses of
structure evolution, noncovalent interactions, and temperature and humidity
effects}.
\newblock {\em J. Phys. Chem. A}, {\bf 119}(12):3035--3047, 2015.
\bibitem{Walters2018}
{\sc Wendell~W Walters, Jiajue Chai, and Meredith~G Hastings}.
\newblock {\bf Theoretical phase resolved ammonia--ammonium nitrogen
equilibrium isotope exchange fractionations: Applications for tracking
atmospheric ammonia gas-to-particle conversion}.
\newblock {\em ACS Earth Space Chem.}, {\bf 3}(1):79--89, 2018.
\bibitem{Choi2010}
{\sc Tae~Hoon Choi and Kenneth~D Jordan}.
\newblock {\bf Application of the SCC-DFTB method to H$^+$(H$_2$O)$_6$,
H$^+$(H$_2$O)$_{21}$, and H$^+$(H$_2$O)$_{22}$}.
\newblock {\em J. Phys. Chem. B}, {\bf 114}(20):6932--6936, 2010.
\bibitem{Choi2013}
{\sc Tae~Hoon Choi, Ruibin Liang, C~Mark Maupin, and Gregory~A Voth}.
\newblock {\bf Application of the SCC-DFTB method to hydroxide water clusters
and aqueous hydroxide solutions}.
\newblock {\em J. Phys. Chem. B}, {\bf 117}(17):5165--5179, 2013.
\bibitem{Simon2019}
{\sc Aude Simon, Mathias Rapacioli, Eric Michoulier, Linjie Zheng, Kseniia
Korchagina, and J{\'e}r{\^o}me Cuny}.
\newblock {\bf Contribution of the density-functional-based tight-binding
scheme to the description of water clusters: methods, applications and
extension to bulk systems}.
\newblock {\em Mol. Simul.}, {\bf 45}(4-5):249--268, 2019.
\bibitem{Simon2013water}
{\sc Aude Simon and Fernand Spiegelman}.
\newblock {\bf Water clusters adsorbed on polycyclic aromatic hydrocarbons:
Energetics and conformational dynamics}.
\newblock {\em J. Chem. Phys.}, {\bf 138}(19):194309, 2013.
\bibitem{Winget2003}
{\sc Paul Winget, Cenk Selcuki, Anselm~HC Horn, Bodo Martin, and Timothy
Clark}.
\newblock {\bf Towards a next generationneglect of diatomic
differential overlap based semiempirical molecular orbital technique}.
\newblock {\em Theor. Chem. Acc.}, {\bf 110}(4):254--266, 2003.
\bibitem{Lee2004}
{\sc Han~Myoung Lee, P~Tarakeshwar, Jungwon Park, Maciej~Roman Ko{\l}aski,
Yeo~Jin Yoon, Hai-Bo Yi, Woo~Youn Kim, and Kwang~S Kim}.
\newblock {\bf Insights into the structures, energetics, and vibrations of
monovalent cation-(water) 1-6 clusters}.
\newblock {\em J. Phys. Chem. A}, {\bf 108}(15):2949--2958, 2004.
\bibitem{Pickard2005}
{\sc Frank~C Pickard~IV, Meghan~E Dunn, and George~C Shields}.
\newblock {\bf Comparison of model chemistry and density functional theory
thermochemical predictions with experiment for formation of ionic clusters of
the ammonium cation complexed with water and ammonia; atmospheric
implications}.
\newblock {\em J. Phys. Chem. A}, {\bf 109}(22):4905--4910, 2005.
\bibitem{Kazimirski2003}
{\sc Jan~K Kazimirski and Victoria Buch}.
\newblock {\bf Search for low energy structures of water clusters (H$_2$O)$_n$,
$n$= 20- 22, 48, 123, and 293}.
\newblock {\em J. Phys. Chem. A}, {\bf 107}(46):9762--9775, 2003.
\bibitem{Bandow2006}
{\sc Bernhard Bandow and Bernd Hartke}.
\newblock {\bf Larger water clusters with edges and corners on their way to
ice: Structural trends elucidated with an improved parallel evolutionary
algorithm}.
\newblock {\em J. Phys. Chem. A}, {\bf 110}(17):5809--5822, 2006.
\bibitem{Kozack1992empiri}
{\sc RE~Kozack and PC~Jordan}.
\newblock {\bf Empirical models for the hydration of protons}.
\newblock {\em J. Chem. Phys.}, {\bf 96}(4):3131--3136, 1992.
\bibitem{Labastie1990}
{\sc Pierre Labastie and Robert~L Whetten}.
\newblock {\bf {Statistical Thermodynamics of the Cluster Solid-Liquid
Transition}}.
\newblock {\em Phys. Rev. Lett.}, {\bf 65}(13):1567--1570, 1990.
\bibitem{Maclot2011}
{\sc Sylvain Maclot, Michael Capron, R{\'e}mi Maisonny, Arkadiusz {\L}awicki,
Alain M{\'e}ry, Jimmy Rangama, Jean-Yves Chesnel, Sadia Bari, Ronnie
Hoekstra, Thomas Schlath{\"o}lter, B~Manil, L~Adoui, P~Rousseau, and
BA~Huber}.
\newblock {\bf Ion-induced fragmentation of amino acids: effect of the
environment}.
\newblock {\em ChemPhysChem}, {\bf 12}(5):930--936, 2011.
\bibitem{Domaracka2012}
{\sc Alicja Domaracka, Michael Capron, Sylvain Maclot, Jean-Yves Chesnel, Alain
M{\'e}ry, Jean-Christophe Poully, Jimmy Rangama, Lamri Adoui, Patrick
Rousseau, and Bernd~A Huber}.
\newblock {\bf Ion interaction with biomolecular systems and the effect of the
environment}.
\newblock {\em J. Phys. Conf. Ser.}, {\bf 373}:012005, 2012.
\bibitem{Markush2016}
{\sc Pal Markush, Paola Bolognesi, Antonella Cartoni, Patrick Rousseau, Sylvain
Maclot, Rudy Delaunay, Alicja Domaracka, Jaroslav Kocisek, Mattea~C
Castrovilli, Bernd~A Huber, and Lorenzo Avaldi}.
\newblock {\bf The role of the environment in the ion induced fragmentation of
Uracil}.
\newblock {\em Phys. Chem. Chem. Phys.}, {\bf 18}(25):16721--16729, 2016.
\bibitem{Wincel2009}
{\sc Henryk Wincel}.
\newblock {\bf Microhydration of protonated nucleic acid bases and protonated
nucleosides in the gas phase}.
\newblock {\em J. Am. Soc. Mass Spectrom.}, {\bf 20}(10):1900--1905, 2009.
\bibitem{Boudaiffa2000}
{\sc Badia Bouda{\"i}ffa, Pierre Cloutier, Darel Hunting, Michael~A Huels, and
L{\'e}on Sanche}.
\newblock {\bf Resonant formation of DNA strand breaks by low-energy (3 to 20
eV) electrons}.
\newblock {\em Science}, {\bf 287}(5458):1658--1660, 2000.
\bibitem{Smyth2011}
{\sc Maeve Smyth and Jorge Kohanoff}.
\newblock {\bf Excess electron localization in solvated DNA bases}.
\newblock {\em Phys. Rev. Lett.}, {\bf 106}(23):238108, 2011.
\bibitem{Siefermann2011}
{\sc Katrin~R Siefermann and Bernd Abel}.
\newblock {\bf The hydrated electron: a seemingly familiar chemical and
biological transient}.
\newblock {\em Angew. Chem. Int. Ed.}, {\bf 50}(23):5264--5272, 2011.
\bibitem{Alizadeh2013}
{\sc Elahe Alizadeh, Ana~G Sanz, Gustavo Garcia, and Leon Sanche}.
\newblock {\bf Radiation damage to DNA: The indirect effect of low-energy
electrons}.
\newblock {\em J. Phys. Chem. Lett.}, {\bf 4}(5):820--825, 2013.
\bibitem{Rasmussen2010}
{\sc Andrew~M Rasmussen, Maria~C Lind, Sunghwan Kim, and Henry~F Schaefer~III}.
\newblock {\bf Hydration of the lowest triplet states of the DNA/RNA
pyrimidines}.
\newblock {\em J. Chem. Theory Comput.}, {\bf 6}(3):930--939, 2010.
\bibitem{Sadr2014}
{\sc Leila Sadr-Arani, Pierre Mignon, Henry Chermette, and Thierry Douki}.
\newblock {\bf Theoretical and experimental study of the fragmentation of
protonated uracil}.
\newblock {\em Chem. Phys. Lett.}, {\bf 605}:108--114, 2014.
\bibitem{Molina2016}
{\sc Estefan{\'\i}a~Rossich Molina, Jean-Yves Salpin, Riccardo Spezia, and
Emilio Martinez-Nunez}.
\newblock {\bf On the gas phase fragmentation of protonated uracil: A
statistical perspective}.
\newblock {\em Phys. Chem. Chem. Phys.}, {\bf 18}(22):14980--14990, 2016.
\bibitem{Bakker2008}
{\sc Joost~M Bakker, Rajeev~K Sinha, Thierry Besson, Maurizio Brugnara, Paolo
Tosi, Jean-Yves Salpin, and Philippe Ma{\^\i}tre}.
\newblock {\bf Tautomerism of uracil probed via infrared spectroscopy of singly
hydrated protonated uracil}.
\newblock {\em J. Phys. Chem. A}, {\bf 112}(48):12393--12400, 2008.
\bibitem{Shishkin2000}
{\sc Oleg~V Shishkin, Leonid Gorb, and Jerzy Leszczynski}.
\newblock {\bf Modeling of the hydration shell of uracil and thymine}.
\newblock {\em Int. J. Mol. Sci.}, {\bf 1}(2):17--27, 2000.
\bibitem{Gadre2000}
{\sc Shridhar~R Gadre, K~Babu, and Alistair~P Rendell}.
\newblock {\bf Electrostatics for exploring hydration patterns of molecules. 3.
Uracil}.
\newblock {\em J. Phys. Chem. A}, {\bf 104}(39):8976--8982, 2000.
\bibitem{Van2001diffu}
{\sc Tanja van Mourik, Sarah~L Price, and David~C Clary}.
\newblock {\bf Diffusion Monte Carlo simulations on uracil--water using an
anisotropic atom--atom potential model}.
\newblock {\em Faraday discussions}, {\bf 118}:95--108, 2001.
\bibitem{Gaigeot2001}
{\sc Marie-Pierre Gaigeot and Mahmoud Ghomi}.
\newblock {\bf Geometrical and Vibrational Properties of Nucleic Acid
Constituents Interacting with Explicit Water Molecules as Analyzed by Density
Functional Theory Calculations. 1. Uracil + n$_w$H$_2$O (n$_w$= 1, ..., 7)}.
\newblock {\em J. Phys. Chem. B}, {\bf 105}(21):5007--5017, 2001.
\bibitem{Danilov2006}
{\sc Victor~I Danilov, Tanja van Mourik, and Valery~I Poltev}.
\newblock {\bf Modeling of the 'hydration shell' of uracil and thymine in small
water clusters by DFT and MP2 methods}.
\newblock {\em Chem. Phys. Lett.}, {\bf 429}(1-3):255--260, 2006.
\bibitem{Bacchus2015}
{\sc Marie-Christine Bacchus-Montabonel and Florent Calvo}.
\newblock {\bf Nanohydration of uracil: emergence of three-dimensional
structures and proton-induced charge transfer}.
\newblock {\em Phys. Chem. Chem. Phys.}, {\bf 17}(15):9629--9633, 2015.
\bibitem{Dalleska1993}
{\sc NF~Dalleska, Kenji Honma, and PB~Armentrout}.
\newblock {\bf Stepwise solvation enthalpies of protonated water clusters:
Collision-induced dissociation as an alternative to equilibrium studies}.
\newblock {\em J. Am. Chem. Soc.}, {\bf 115}(25):12125--12131, 1993.
\bibitem{Zamith2012}
{\sc S{\'e}bastien Zamith, Pierre Labastie, and Jean-Marc l'Hermite}.
\newblock {\bf Fragmentation cross sections of protonated water clusters}.
\newblock {\em J. Chem. Phys.}, {\bf 136}(21):214301, 2012.
\bibitem{Myers2007}
{\sc Richard~L Myers}.
\newblock {\em The 100 most important chemical compounds: a reference guide}.
\newblock ABC-CLIO, 2007.
\bibitem{Hansen2009}
{\sc K~Hansen, PU~Andersson, and E~Uggerud}.
\newblock {\bf Activation energies for evaporation from protonated and
deprotonated water clusters from mass spectra}.
\newblock {\em J. Chem. Phys.}, {\bf 131}(12):124303, 2009.
\bibitem{Kurinovich2002}
{\sc Mary~Ann Kurinovich, Linda~M Phillips, Seema Sharma, and Jeehiun~K Lee}.
\newblock {\bf The gas phase proton affinity of uracil: measuring multiple
basic sites and implications for the enzyme mechanism of orotidine
5'-monophosphate decarboxylase}.
\newblock {\em Chemical communications}, {\bf 21}(20):2354--2355, 2002.
\bibitem{Magnera1991}
{\sc Thomas~F Magnera, Donald~E David, and Josef Michl}.
\newblock {\bf The first twenty-eight gas-phase proton hydration energies}.
\newblock {\em Chem. Phys. Lett.}, {\bf 182}(3-4):363--370, 1991.
\bibitem{Cheng1998}
{\sc Hai-Ping Cheng}.
\newblock {\bf Water clusters: fascinating hydrogen-bonding networks, solvation
shell structures, and proton motion}.
\newblock {\em J. Phys. Chem. A}, {\bf 102}(31):6201--6204, 1998.
\bibitem{Zundel1968}
{\sc G.~Zundel and H.~Metzger}.
\newblock {\bf Energieb{\"a}nder der tunnelnden {\"U}berschu{\ss}-Protonen in
fl{\"u}ssigen S{\"a}uren. Eine IR-spektroskopische Untersuchung der Natur der
Gruppierungen H$_5$O$_2^+$}.
\newblock {\em Proc. Z. Phys. Chem.}, {\bf 58}(5\_6):225--245, 1968.
\bibitem{Brechignac1989}
{\sc C~Br{\'e}chignac, Ph~Cahuzac, J~Leygnier, and J~Weiner}.
\newblock {\bf Dynamics of unimolecular dissociation of sodium cluster ions}.
\newblock {\em J. Chem. Phys.}, {\bf 90}(3):1492--1498, 1989.
\bibitem{Brechignac1994}
{\sc C~Br{\'e}chignac, H~Busch, Ph~Cahuzac, and J~Leygnier}.
\newblock {\bf Dissociation pathways and binding energies of lithium clusters
from evaporation experiments}.
\newblock {\em J. Chem. Phys.}, {\bf 101}(8):6992--7002, 1994.
\bibitem{Wong2004}
{\sc Richard~L Wong, Kolja Paech, and Evan~R Williams}.
\newblock {\bf Blackbody infrared radiative dissociation at low temperature:
Hydration of X$^{2+}$(H$_2$O)$_n$, for X= Mg, Ca}.
\newblock {\em International J. Mass Spectrom.}, {\bf 232}(1):59--66, 2004.
\bibitem{Bush2008}
{\sc Matthew~F Bush, Richard~J Saykally, and Evan~R Williams}.
\newblock {\bf Reactivity and infrared spectroscopy of gaseous hydrated
trivalent metal ions}.
\newblock {\em J. Am. Chem. Soc.}, {\bf 130}(28):9122--9128, 2008.
\bibitem{Gatchell2014}
{\sc Michael Gatchell, Patrick Rousseau, A~Domaracka, Mark~H Stockett, Tao
Chen, Henning~T Schmidt, JY~Chesnel, A~M{\'e}ry, S~Maclot, L~Adoui, et~al.}
\newblock {\bf Ions colliding with mixed clusters of C$_{60}$ and coronene:
Fragmentation and bond formation}.
\newblock {\em Phys. Rev. A}, {\bf 90}(2):022713, 2014.
\bibitem{Boering1992}
{\sc Kristie~A Boering, Joseph Rolfe, and John~I Brauman}.
\newblock {\bf Low energy collision induced dissociation: phase-shifting
excitation control of ion kinetic energy in ion cyclotron resonance
spectrometry}.
\newblock {\em Int. J. Mass Spectrom. Ion Processes}, {\bf 117}:357--386, 1992.
\bibitem{Wells2005}
{\sc J~Mitchell Wells and Scott~A McLuckey}.
\newblock {\bf Collision-induced dissociation (CID) of peptides and proteins}.
\newblock {\em Methods Enzymol.}, {\bf 402}:148--185, 2005.
\bibitem{Ma1997}
{\sc YL~Ma, QM~Li, H~Van~den Heuvel, and M~Claeys}.
\newblock {\bf Characterization of flavone and flavonol aglycones by
collision-induced dissociation tandem mass spectrometry}.
\newblock {\em Rapid Commun. Mass}, {\bf 11}(12):1357--1364, 1997.
\bibitem{Chowdhury2009}
{\sc Saiful~M Chowdhury, Xiuxia Du, Nikola Tolic, Si~Wu, Ronald~J Moore,
M~Uljana Mayer, Richard~D Smith, and Joshua~N Adkins}.
\newblock {\bf Identification of cross-linked peptides after click-based
enrichment using sequential collision-induced dissociation and electron
transfer dissociation tandem mass spectrometry}.
\newblock {\em Anal. Chem.}, {\bf 81}(13):5524--5532, 2009.
\bibitem{Sleno2004ion}
{\sc Lekha Sleno and Dietrich~A Volmer}.
\newblock {\bf Ion activation methods for tandem mass spectrometry}.
\newblock {\em J. Mass Spectrom.}, {\bf 39}(10):1091--1112, 2004.
\bibitem{Cody1982}
{\sc RB~Cody, RC~Burnier, and BS~Freiser}.
\newblock {\bf Collision-induced dissociation with Fourier transform mass
spectrometry}.
\newblock {\em Anal. Chem.}, {\bf 54}(1):96--101, 1982.
\bibitem{Olsen2007higher}
{\sc Jesper~V Olsen, Boris Macek, Oliver Lange, Alexander Makarov, Stevan
Horning, and Matthias Mann}.
\newblock {\bf Higher-energy C-trap dissociation for peptide modification
analysis}.
\newblock {\em Nat. Methods.}, {\bf 4}(9):709--712, 2007.
\bibitem{Hart2011}
{\sc Gene Hart-Smith and Mark~J Raftery}.
\newblock {\bf Detection and characterization of low abundance glycopeptides
via higher-energy C-trap dissociation and orbitrap mass analysis}.
\newblock {\em J. Am. Soc. Mass Spectrom.}, {\bf 23}(1):124--140, 2011.
\bibitem{Gauthier1991}
{\sc JW~Gauthier, TR~Trautman, and DB~Jacobson}.
\newblock {\bf Sustained off-resonance irradiation for collision-activated
dissociation involving Fourier transform mass spectrometry.
Collision-activated dissociation technique that emulates infrared multiphoton
dissociation}.
\newblock {\em Anal. Chim. Acta}, {\bf 246}(1):211--225, 1991.
\bibitem{Laskin2005}
{\sc Julia Laskin and Jean~H Futrell}.
\newblock {\bf Activation of large lons in FT-ICR mass spectrometry}.
\newblock {\em Mass Spectrom. Rev.}, {\bf 24}(2):135--167, 2005.
\bibitem{Mcquinn2009}
{\sc Keri McQuinn, Fraser Hof, and J~Scott McIndoe}.
\newblock {\bf Collision-induced dissociation of protonated nanodroplets}.
\newblock {\em Int. J. Mass Spectrom.}, {\bf 279}(1):32--36, 2009.
\bibitem{Carl2013}
{\sc Damon~R Carl and Peter~B Armentrout}.
\newblock {\bf Hreshold collision-induced dissociation of hydrated magnesium:
experimental and theoretical investigation of the binding energies for
Mg$^{2+}$(H$_2$O)$_x$ complexes (x= 2--10)}.
\newblock {\em ChemPhysChem}, {\bf 14}(4):681--697, 2013.
\bibitem{Hofstetter2013}
{\sc Theresa~E. Hofstetter and P.~B. Armentrout}.
\newblock \href{https://doi.org/10.1021/jp3044829}{{\bf Threshold
collision-induced dissociation and theoretical studies of hydrated Fe(II):
binding energies and coulombic barrier heights}}.
\newblock {\em J. Phys. Chem. A}, {\bf 117}(6):1110--1123, 2013.
\bibitem{Coates2017}
{\sc Rebecca~A Coates and PB~Armentrout}.
\newblock {\bf Thermochemical investigations of hydrated nickel dication
complexes by threshold collision-induced dissociation and theory}.
\newblock {\em J. Phys. Chem. A}, {\bf 121}(19):3629--3646, 2017.
\bibitem{Haag2009}
{\sc N~Haag, B~Liu, S~Br{\o}ndsted Nielsen, H~Zettergren, P~Hvelplund, B~Manil,
B~A Huber, H~A~B Johansson, H~T Schmidt, and H~Cederquist}.
\newblock {\bf Collisions with biomolecules embedded in small water clusters}.
\newblock {\em J. Phys. Conf. Ser.}, {\bf 194}(1):012053, nov 2009.
\bibitem{Li1992}
{\sc Shijian Li and Elliot~R Bernstein}.
\newblock {\bf Toluene-water clusters: Ion fragmentation and chemistry}.
\newblock {\em J. Chem. Phys.}, {\bf 97}(2):792--803, 1992.
\bibitem{Bobbert2002}
{\sc C~Bobbert, S~Sch{\"u}tte, C~Steinbach, and U~Buck}.
\newblock {\bf Fragmentation and reliable size distributions of large ammonia
and water clusters}.
\newblock {\em Eur. Phys. J. D}, {\bf 19}(2):183--192, 2002.
\bibitem{Spasov2000}
{\sc Vassil~A Spasov, Taeck-Hong Lee, and Kent~M Ervin}.
\newblock {\bf Threshold collision-induced dissociation of anionic copper
clusters and copper cluster monocarbonyls}.
\newblock {\em J. Chem. Phys.}, {\bf 112}(4):1713--1720, 2000.
\bibitem{Armentrout2008}
{\sc PB~Armentrout, Kent~M Ervin, and MT~Rodgers}.
\newblock {\bf Statistical rate theory and kinetic energy-resolved ion
chemistry: theory and applications}.
\newblock {\em J. Phys. Chem. A}, {\bf 112}(41):10071--10085, 2008.
\bibitem{Rodgers1998}
{\sc MT~Rodgers and PB~Armentrout}.
\newblock {\bf Statistical modeling of competitive threshold collision-induced
dissociation}.
\newblock {\em J. Chem. Phys.}, {\bf 109}(5):1787--1800, 1998.
\bibitem{Armentrout2007}
{\sc PB~Armentrout}.
\newblock {\bf Statistical modeling of sequential collision-induced
dissociation thresholds}.
\newblock {\em J. Chem. Phys.}, {\bf 126}(23):234302, 2007.
\bibitem{Braud2017}
{\sc Isabelle Braud, S{\'e}bastien Zamith, and J-M LHermite}.
\newblock {\bf A gas aggregation source for the production of heterogeneous
molecular clusters}.
\newblock {\em Rev. Sci. Instrum.}, {\bf 88}(4):043102, 2017.
\bibitem{Chirot2006new}
{\sc Fabien Chirot, S{\'e}bastien Zamith, Pierre Labastie, and J-M
LHermite}.
\newblock {\bf New device to study unimolecular cluster nucleation}.
\newblock {\em Rev. Sci. Instrum.}, {\bf 77}(6):063108, 2006.
\bibitem{Frenzel2004}
{\sc J~Frenzel, AF~Oliveira, N~Jardillier, T~Heine, and G~Seifert}.
\newblock {\bf Semi-relativistic, self-consistent charge Slater-Koster tables
for density-functional based tight-binding (DFTB) for materials science
simulations}.
\newblock {\em Zeolites}, {\bf 2}(3):7, 2004.
\bibitem{Spiegelman2020}
{\sc Fernand Spiegelman, Nathalie Tarrat, J{\'e}r{\^o}me Cuny, Leo Dontot,
Evgeny Posenitskiy, Carles Mart{\'\i}, Aude Simon, and Mathias Rapacioli}.
\newblock {\bf Density-functional tight-binding: basic concepts and
applications to molecules and clusters}.
\newblock {\em Adv. Phys. -X}, {\bf 5}(1):1710252, 2020.
\bibitem{Simon2017}
{\sc Aude Simon, Mathias Rapacioli, Guillaume Rouaut, Georges Trinquier, and
FX~Gad{\'e}a}.
\newblock {\bf Dissociation of polycyclic aromatic hydrocarbons: molecular
dynamics studies}.
\newblock {\em Philos. Trans. R. Soc. A}, {\bf 375}(2092):20160195, 2017.
\bibitem{Rapacioli2018}
{\sc Mathias Rapacioli, Nathalie Tarrat, and Fernand Spiegelman}.
\newblock {\bf Melting of the Au$_{20}$ gold cluster: Does charge matter?}
\newblock {\em J. Phys. Chem. A}, {\bf 122}(16):4092--4098, 2018.
\bibitem{Simon2018}
{\sc Aude Simon, Jean-Philippe Champeaux, Mathias Rapacioli, Patrick
Moretto-Capelle, X.~Gad{\'e}a, Florent, and Martine Sence}.
\newblock {\bf Dissociation of polycyclic aromatic hydrocarbons at high energy:
MD/DFTB simulations versus collision experiments}.
\newblock {\em Theor. Chem. Acc.}, {\bf 137}(7):106, 2018.
\bibitem{Warshel1976}
{\sc Arieh Warshel and Michael Levitt}.
\newblock {\bf Theoretical studies of enzymic reactions: dielectric,
electrostatic and steric stabilization of the carbonium ion in the reaction
of lysozyme}.
\newblock {\em J. Mol. Biol.}, {\bf 103}(2):227--249, 1976.
\bibitem{Cui2001}
{\sc Qiang Cui, Marcus Elstner, Efthimios Kaxiras, Thomas Frauenheim, and
Martin Karplus}.
\newblock {\bf A QM/MM implementation of the self-consistent charge density
functional tight binding (SCC-DFTB) method}.
\newblock {\em J. Phys. Chem. B}, {\bf 105}(2):569--585, 2001.
\bibitem{Iftner2014}
{\sc Christophe Iftner, Aude Simon, Kseniia Korchagina, Mathias Rapacioli, and
Fernand Spiegelman}.
\newblock {\bf A density functional tight binding/force field approach to the
interaction of molecules with rare gas clusters: Application to
(C$_6$H$_6$)$^{+/0}$Ar$_n$ clusters}.
\newblock {\em J. Chem. Phys.}, {\bf 140}(3):034301, 2014.
\bibitem{Kukk2015}
{\sc Edwin Kukk, DT~Ha, Y~Wang, Dariusz~Grzegorz Piekarski, Sergio
Diaz-Tendero, Kuno Kooser, Eero It{\"a}l{\"a}, Helena Levola, Manuel
Alcam{\'\i}, Elisabeth Rachlew, et~al.}
\newblock {\bf Internal energy dependence in X-ray-induced molecular
fragmentation: an experimental and theoretical study of thiophene}.
\newblock {\em Phys. Rev. A}, {\bf 91}(4):043417, 2015.
\bibitem{Rapacioli2018atomic}
{\sc Mathias Rapacioli, St{\'e}phanie Cazaux, Nolan Foley, Aude Simon, Ronnie
Hoekstra, and Thomas Schlath{\"o}lter}.
\newblock {\bf Atomic hydrogen interactions with gas-phase coronene cations:
hydrogenation versus fragmentation}.
\newblock {\em Phys. Chem. Chem. Phys.}, {\bf 20}(35):22427--22438, 2018.
\bibitem{Dontot2019}
{\sc L{\'e}o Dontot, Fernand Spiegelman, and Mathias Rapacioli}.
\newblock {\bf Structures and energetics of neutral and cationic pyrene
clusters}.
\newblock {\em J. Phys. Chem. A}, {\bf 123}(44):9531--9543, 2019.
\bibitem{Chung2011}
{\sc Seung-Hyun Chung and Angela Violi}.
\newblock {\bf Peri-condensed aromatics with aliphatic chains as key
intermediates for the nucleation of aromatic hydrocarbons}.
\newblock {\em Proc. Combust. Inst.}, {\bf 33}(1):693--700, 2011.
\bibitem{Saggese2015}
{\sc Chiara Saggese, Sara Ferrario, Joaquin Camacho, Alberto Cuoci, Alessio
Frassoldati, Eliseo Ranzi, Hai Wang, and Tiziano Faravelli}.
\newblock {\bf Kinetic modeling of particle size distribution of soot in a
premixed burner-stabilized stagnation ethylene flame}.
\newblock {\em Combust. Flame}, {\bf 162}(9):3356--3369, 2015.
\bibitem{Mao2017}
{\sc Qian Mao, Adri~CT Van~Duin, and KH~Luo}.
\newblock {\bf Formation of incipient soot particles from polycyclic aromatic
hydrocarbons: a ReaxFF molecular dynamics study}.
\newblock {\em Carbon}, {\bf 121}:380--388, 2017.
\bibitem{Wang2018}
{\sc Chen~S Wang, Norman~C Bartelt, Regina Ragan, and Konrad Th{\"u}rmer}.
\newblock {\bf Revealing the molecular structure of soot precursors}.
\newblock {\em Carbon}, {\bf 129}:537--542, 2018.
\bibitem{Kyrtopoulos2001}
{\sc SA~Kyrtopoulos, Panagiotis Georgiadis, H~Autrup, N~Demopoulos, P~Farmer,
A~Haugen, K~Katsouyanni, B~Lambert, S~Ovrebo, R~Sram, et~al.}
\newblock {\bf Biomarkers of genotoxicity of urban air pollution: overview and
descriptive data from a molecular epidemiology study on populations exposed
to moderate-to-low levels of polycyclic aromatic hydrocarbons: the AULIS
project}.
\newblock {\em Mutat. Res. Genet. Toxicol. Environ.}, {\bf 496}(1-2):207--228,
2001.
\bibitem{Farmer2003}
{\sc Peter~B Farmer, Rajinder Singh, Balvinder Kaur, Radim~J Sram, Blanka
Binkova, Ivan Kalina, Todor~A Popov, Seymour Garte, Emanuela Taioli, Alena
Gabelova, et~al.}
\newblock {\bf Molecular epidemiology studies of carcinogenic environmental
pollutants: effects of polycyclic aromatic hydrocarbons (PAHs) in
environmental pollution on exogenous and oxidative DNA damage}.
\newblock {\em Mutat. Res.-Rev. Mutat. Res.}, {\bf 544}(2-3):397--402, 2003.
\bibitem{Aumaitre2019}
{\sc Cyril Aumaitre and Jean-Fran{\c{c}}ois Morin}.
\newblock {\bf Polycyclic aromatic hydrocarbons as potential building blocks
for organic solar cells}.
\newblock {\em Chem. Rec.}, {\bf 19}(6):1142--1154, 2019.
\bibitem{Rapacioli2005}
{\sc M~Rapacioli, C~Joblin, and P~Boissel}.
\newblock {\bf Spectroscopy of polycyclic aromatic hydrocarbons and very small
grains in photodissociation regions}.
\newblock {\em Astron. Astrophys.}, {\bf 429}(1):193--204, 2005.
\bibitem{Berne2008}
{\sc O~Bern{\'e}, C~Joblin, M~Rapacioli, J~Thomas, J-C Cuillandre, and
Y~Deville}.
\newblock {\bf Extended red emission and the evolution of carbonaceous
nanograins in NGC 7023}.
\newblock {\em Astron. Astrophys.}, {\bf 479}(3):L41--L44, 2008.
\bibitem{Eschenbach1998}
{\sc Annette Eschenbach, Reinhard Wienberg, and Bernd Mahro}.
\newblock {\bf Fate and stability of nonextractable residues of [14C] PAH in
contaminated soils under environmental stress conditions}.
\newblock {\em Environ. Sci. Technol.}, {\bf 32}(17):2585--2590, 1998.
\bibitem{Goulart2017}
{\sc Marcelo Goulart, Martin Kuhn, Bilal Rasul, Johannes Postler, Michael
Gatchell, Henning Zettergren, Paul Scheier, and Olof Echt}.
\newblock {\bf The structure of coronene cluster ions inferred from H 2 uptake
in the gas phase}.
\newblock {\em Phys. Chem. Chem. Phys.}, {\bf 19}(41):27968--27973, 2017.
\bibitem{Lei2019}
{\sc Lei Lei, Yuzhong Yao, Jie Zhang, Dale Tronrud, Wei Kong, Chengzhu Zhang,
Lan Xue, L{\'e}o Dontot, and Mathias Rapacioli}.
\newblock {\bf Electron diffraction of pyrene nanoclusters embedded in
superfluid helium droplets}.
\newblock {\em J. Phys. Chem. Lett.}, {\bf 11}(3):724--729, 2019.
\bibitem{Roser2015}
{\sc JE~Roser and A~Ricca}.
\newblock {\bf Polycyclic aromatic hydrocarbon clusters as sources of
interstellar infrared emission}.
\newblock {\em Astrophys. J.}, {\bf 801}(2):108, 2015.
\bibitem{Lemmens2019}
{\sc Alexander~K Lemmens, S{\'e}bastien Gruet, Amanda~L Steber, Jens Antony,
Stefan Grimme, Melanie Schnell, and Anouk~M Rijs}.
\newblock {\bf Far-IR and UV spectral signatures of controlled complexation and
microhydration of the polycyclic aromatic hydrocarbon acenaphthene}.
\newblock {\em Phys. Chem. Chem. Phys.}, {\bf 21}(7):3414--3422, 2019.
\bibitem{Delaunay2015}
{\sc Rudy Delaunay, Michael Gatchell, Patrick Rousseau, Alicja Domaracka,
Sylvain Maclot, Yang Wang, Mark~H Stockett, Tao Chen, Lamri Adoui, Manuel
Alcam{\'\i}, et~al.}
\newblock {\bf Molecular growth inside of polycyclic aromatic hydrocarbon
clusters induced by ion collisions}.
\newblock {\em J. Phys. Chem. Lett.}, {\bf 6}(9):1536--1542, 2015.
\bibitem{Piacenza2005}
{\sc Manuel Piacenza and Stefan Grimme}.
\newblock {\bf Van der Waals complexes of polar aromatic molecules: Unexpected
structures for dimers of azulene}.
\newblock {\em J. Am. Chem. Soc.}, {\bf 127}(42):14841--14848, 2005.
\bibitem{Birer2015}
{\sc {\"O}~Birer and E~Yurtsever}.
\newblock {\bf Dimer formation of perylene: An ultracold spectroscopic and
computational study}.
\newblock {\em J. Mol. Struct.}, {\bf 1097}:29--36, 2015.
\bibitem{Zhao2008truhlar}
{\sc Y.~Zh{ao} and Donald~G. Truhlar}.
\newblock \href{http://pubs.acs.org/doi/abs/10.1021/jp710918f}{{\bf A Prototype
for graphene material simulation; structures and interaction potentials of
coronene dimers}}.
\newblock {\em J. Phys. Chem. C}, {\bf 112}:4061--4067, 2008.
\bibitem{Bowal2019}
{\sc Kimberly Bowal, Jacob~W Martin, and Markus Kraft}.
\newblock {\bf Partitioning of polycyclic aromatic hydrocarbons in
heterogeneous clusters}.
\newblock {\em Carbon}, {\bf 143}:247--256, 2019.
\bibitem{Ricca2013}
{\sc Alessandra Ricca, Charles~W Bauschlicher~Jr, and Louis~J Allamandola}.
\newblock {\bf The infrared spectroscopy of neutral polycyclic aromatic
hydrocarbon clusters}.
\newblock {\em Astrophys. J.}, {\bf 776}(1):31, 2013.
\bibitem{Grafenstein2009}
{\sc J{\"u}rgen Gr{\"a}fenstein and Dieter Cremer}.
\newblock {\bf The self-interaction error and the description of non-dynamic
electron correlation in density functional theory}.
\newblock {\em Theor. Chem. Acc.}, {\bf 123}(3):171--182, 2009.
\bibitem{Dontot2016}
{\sc L{\'e}o Dontot, Nicolas Suaud, Mathias Rapacioli, and Fernand Spiegelman}.
\newblock {\bf An extended DFTB-CI model for charge-transfer excited states in
cationic molecular clusters: model studies versus ab initio calculations in
small PAH clusters}.
\newblock {\em Phys. Chem. Chem. Phys.}, {\bf 18}(5):3545--3557, 2016.
\bibitem{Dontot2020}
{\sc L{\'e}o Dontot, Fernand Spiegelman, S{\'e}bastien Zamith, and Mathias
Rapacioli}.
\newblock {\bf Dependence upon charge of the vibrational spectra of small
Polycyclic Aromatic Hydrocarbon clusters: the example of pyrene}.
\newblock {\em Eur. Phys. J. D}, {\bf 74}(11):1--9, 2020.
\bibitem{Rapacioli2011}
{\sc Mathias Rapacioli, Fernand Spiegelman, Anthony Scemama, and Andr{\'e}
Mirtschink}.
\newblock {\bf Modeling charge resonance in cationic molecular clusters:
combining DFT-tight binding with configuration interaction}.
\newblock {\em J. Chem. Theory Comput.}, {\bf 7}(1):44--55, 2011.
\bibitem{Gatchell2016}
{\sc Michael Gatchell}.
\newblock {\em Molecular Hole Punching: Impulse Driven Reactions in Molecules
and Molecular Clusters}.
\newblock PhD thesis, Department of Physics, Stockholm University, 2016.
\bibitem{Gatchell2016knockout}
{\sc Michael Gatchell and Henning Zettergren}.
\newblock {\bf Knockout driven reactions in complex molecules and their
clusters}.
\newblock {\em J. Phys. B}, {\bf 49}(16):162001, 2016.
\bibitem{Levine1987}
{\sc Raphael~D Levine, Richard~Barry Bernstein, et~al.}
\newblock {\em Molecular reaction dynamics and chemical reactivity}.
\newblock Oxford University Press, USA, 1987.
\bibitem{Chen2014}
{\sc Tao Chen, Michael Gatchell, Mark~H Stockett, John~D Alexander, Y~Zhang,
Patrick Rousseau, A~Domaracka, S~Maclot, R~Delaunay, L~Adoui, et~al.}
\newblock {\bf Absolute fragmentation cross sections in atom-molecule
collisions: scaling laws for non-statistical fragmentation of polycyclic
aromatic hydrocarbon molecules}.
\newblock {\em J. Chem. Phys.}, {\bf 140}(22):224306, 2014.
\end{thebibliography}
Reference in New Issue View Git Blame Copy Permalink