Structures of stable compositions of sodium oxide cluster cations (NanOm+, n≤11) have been investigated by ion mobility mass spectrometry. Stoichiometric compositions series, Na(Na2O)(n−1)/2+ (n=3, 5, 7, 9, and 11), were observed as stable composition series, and NaO(Na2O)(n−1)/2+ series (n=5, 7, 9, and 11) were observed as secondary stable series in the mass spectra. To assign the structures of these cluster ion series, collision cross sections between the ions and helium buffer gas were determined experimentally from the ion mobility measurements. Theoretical collision cross sections were also calculated for optimized structures of these compositions. Finally, the structures of Na(Na2O)(n−1)/2+ and NaO(Na2O)(n−1)/2+ were assigned to those having similar structural frames for each n except for n=9. All bonds in the assigned structures of Na(Na2O)(n−1)/2+ were between sodium and oxygen. On the other hand, there was one O−O bond in addition to Na−O bonds in NaO(Na2O)(n−1)/2+. This result indicates that NaO(Na2O)(n−1)/2+ have a peroxide ion (O22−) as a substitute for an oxide ion (O2−) of Na(Na2O)(n−1)/2+. As a result, both stable series, Na(Na2O)(n−1)/2+ and NaO(Na2O)(n−1)/2+, are closed-shell compositions. These closed-shell characteristics have a strong influence on the stability of sodium oxide cluster cations.

[1]
F. A.
Cotton
,
G.
Wilkinson
,
C. A.
Murillo
, and
Manfred
Bochmann
,
Advanced Inorganic Chemistry
, 6th Edn.,
New York
:
Wiley and Sons
, (
1999
).
[2]
T. P.
Martin
,
T.
Bergmann
, and
N.
Malinowski
,
J. Chem. Soc. Faraday Trans.
86
,
2489
(
1990
).
[3]
A.
Nakajima
,
T.
Sugioka
,
K.
Hoshino
, and
K.
Kaya
,
Chem. Phys. Lett.
189
,
455
(
1992
).
[4]
D.
Wang
,
J. D.
Graham
,
A. M.
Buytendyk
, and
K. H.
Bowen
 Jr.
,
J. Chem. Phys.
135
,
164308
(
2011
).
[5]
K.
Majer
,
M.
Lei
,
C.
Hock
,
B.
von Issendorff
, and
A.
Aguado
,
J. Chem. Phys.
131
,
204313
(
2009
).
[6]
S. D.
Elliot
,
R.
Ahlriches
,
O.
Hampe
, and
M. M.
Kappes
,
Phys. Chem. Chem. Phys.
2
,
3415
(
2000
).
[7]
E. U.
Würthwein
,
P. von R.
Schleyer
, and
J. A.
Pople
,
J. Am. Chem. Soc.
106
,
6973
(
1984
).
[8]
E.
Rehm
,
A. I.
Boldyrev
, and
P. von R.
Schleyer
,
Inorg. Chem.
31
,
4834
(
1992
).
[9]
O.
Hampe
,
G. M.
Koretsky
,
M.
Gegenheimer
,
C.
Huber
, and
M. M.
Kappes
,
J. Chem. Phys.
107
,
7085
(
1997
).
[10]
S. D.
Elliott
and
R.
Ahlrichs
,
J. Chem. Phys.
109
,
4267
(
1998
).
[11]
S. D.
Elliott
and
R.
Ahlrichs
,
Phys. Chem. Chem. Phys.
2
,
313
(
2000
).
[12]
S.
Zein
and
J. V.
Ortiz
,
J. Chem. Phys.
136
,
224305
(
2012
).
[13]
K.
Ohshimo
,
N.
Norimasa
,
R.
Moriyama
, and
F.
Misaizu
,
J. Chem. Phys.
144
,
194305
(
2016
).
[14]
J. W. J.
Wu
,
R.
Moriyama
,
H.
Tahara
,
K.
Ohshimo
, and
F.
Misaizu
,
J. Phys. Chem. A
120
,
3788
(
2016
).
[15]
R.
Moriyama
,
J. W. J.
Wu
,
K.
Ohshimo
, and
F.
Misaizu
,
Bull. Chem. Soc. Jpn.
89
,
1225
(
2016
).
[16]
R.
Moriyama
,
R.
Sato
,
M.
Nakano
,
K.
Ohshimo
, and
F.
Misaizu
,
J. Phys. Chem. A
121
,
5605
(
2017
).
[17]
K.
Ohshimo
,
T.
Komukai
,
R.
Moriyama
, and
F.
Misaizu
,
J. Phys. Chem. A
118
,
3899
(
2014
).
[18]
K.
Ota
,
K.
Koyasu
,
K.
Ohshimo
, and
F.
Misaizu
,
Chem. Phys. Lett.
588
,
63
(
2013
).
[19]
K.
Ohshimo
,
S.
Azuma
,
T.
Komukai
,
R.
Moriyama
, and
F.
Misaizu
,
J. Phys. Chem. C
119
,
11014
(
2015
).
[20]
K.
Koyasu
,
K.
Komatsu
, and
F.
Misaizu
,
J. Chem. Phys.
139
,
164308
(
2013
).
[21]
F.
Misaizu
,
N.
Hori
,
H.
Tanaka
,
K.
Komatsu
,
A.
Furuya
, and
K.
Ohno
,
Eur. Phys. J. D
52
,
59
(
2009
).
[22]
K.
Ohshimo
,
F.
Misaizu
, and
K.
Ohno
,
J. Chem. Phys.
117
,
5209
(
2002
).
[23]
K.
Koyasu
,
T.
Ohtaki
, and
F.
Misaizu
,
Bull. Chem. Soc. Jpn.
84
,
1342
(
2011
).
[24]
K.
Koyasu
,
T.
Ohtaki
,
N.
Hori
, and
F.
Misaizu
,
Chem. Phys. Lett.
523
,
54
(
2012
).
[25]
E. A.
Mason
and
E. W.
McDaniel
,
Transport Properties of Ions in Gases
,
New York
:
Wiley and Sons
, (
1988
).
[26]
M. J.
Frisch
,
G. W.
Trucks
,
H. B.
Schlegel
,
G. E.
Scuseria
,
M. A.
Robb
,
J. R.
Cheeseman
,
G.
Scalmani
,
V.
Barone
,
G. A.
Petersson
,
H.
Nakatsuji
,
X.
Li
,
M.
Caricato
,
A. V.
Marenich
,
J.
Bloino
,
B. G.
Janesko
,
R.
Gomperts
,
B.
Mennucci
,
H. P.
Hratchian
,
J. V.
Ortiz
,
A. F.
Izmaylov
,
J. L.
Sonnenberg
,
D.
Williams-Young
,
F.
Ding
,
F.
Lipparini
,
F.
Egidi
,
J.
Goings
,
B.
Peng
,
A.
Petrone
,
T.
Henderson
,
D.
Ranasinghe
,
V. G.
Zakrzewski
,
J.
Gao
,
N.
Rega
,
G.
Zheng
,
W.
Liang
,
M.
Hada
,
M.
Ehara
,
K.
Toyota
,
R.
Fukuda
,
J.
Hasegawa
,
M.
Ishida
,
T.
Nakajima
,
Y.
Honda
,
O.
Kitao
,
H.
Nakai
,
T.
Vreven
,
K.
Throssell
,
J. A.
Montgomery
, Jr.
,
J. E.
Peralta
,
F.
Ogliaro
,
M. J.
Bearpark
,
J. J.
Heyd
,
E. N.
Brothers
,
K. N.
Kudin
,
V. N.
Staroverov
,
T. A.
Keith
,
R.
Kobayashi
,
J.
Normand
,
K.
Raghavachari
,
A. P.
Rendell
,
J. C.
Burant
,
S. S.
Iyengar
,
J.
Tomasi
,
M.
Cossi
,
J. M.
Millam
,
M.
Klene
,
C.
Adamo
,
R.
Cammi
,
J. W.
Ochterski
,
R. L.
Martin
,
K.
Morokuma
,
O.
Farkas
,
J. B.
Foresman
, and
D. J.
Fox
,
Gaussian 16, Revision B.01
.
Wallingford, CT
:
Gaussian, Inc.
, (
2016
).
[27]
G.
von Helden
,
M. T.
Hsu
,
N.
Gotts
, and
M. T.
Bowers
,
J. Phys. Chem.
97
,
8182
(
1993
).
[28]
M. F.
Mesleh
,
J. M.
Hunter
,
A. A.
Shvartsburg
,
G. C.
Schatz
, and
M. F.
Jarrold
,
J. Phys. Chem.
100
,
16082
(
1996
).
[29]
R. D.
Shannon
,
Acta Crystallogr. A
32
,
751
(
1976
).
[30]
R.
Moriyama
,
J. W. J.
Wu
,
M.
Nakano
,
K.
Ohshimo
, and
F.
Misaizu
,
J. Phys. Chem. C
122
,
5195
(
2018
).
[31]
J. W. J.
Wu
,
R.
Moriyama
,
M.
Nakano
,
K.
Ohshimo
, and
F.
Misaizu
,
Phys. Chem. Chem. Phys.
19
,
24903
(
2017
).
[32]
Y.
Yuan
and
L.
Cheng
,
Int. J. Quant. Chem.
113
,
1264
(
2013
).
[33]
A. F.
Wells
,
Structural Inorganic Chemistry
,
Oxford
:
Clarendon Press
, (
2012
).
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