We report our study of a silica-water interface using reactive molecular dynamics. This first-of-its-kind simulation achieves length and time scales required to investigate the detailed chemistry of the system. Our molecular dynamics approach is based on the ReaxFF force field of van Duin et al [J. Phys. Chem. A107, 3803 (2003)]. The specific ReaxFF implementation (SERIALREAX) and force fields are first validated on structural properties of pure silica and water systems. Chemical reactions between reactive water and dangling bonds on a freshly cut silica surface are analyzed by studying changing chemical composition at the interface. In our simulations, reactions involving silanol groups reach chemical equilibrium in 250ps. It is observed that water molecules penetrate a silica film through a proton-transfer process we call “hydrogen hopping,” which is similar to the Grotthuss mechanism. In this process, hydrogen atoms pass through the film by associating and dissociating with oxygen atoms within bulk silica, as opposed to diffusion of intact water molecules. The effective diffusion constant for this process, taken to be that of hydrogen atoms within silica, is calculated to be 1.68×106cm2/s. Polarization of water molecules in proximity of the silica surface is also observed. The subsequent alignment of dipoles leads to an electric potential difference of 10.5V between the silica slab and water.

1.
M.
Qhobosheane
,
S.
Santra
,
P.
Zhang
, and
W.
Tan
,
Analyst (Cambridge, U.K.)
126
,
1274
(
2001
).
2.
W.
Tan
,
K.
Wang
,
X.
He
,
X.
Zhao
,
T.
Drake
,
L.
Wang
, and
R.
Bagwe
,
Med. Res. Rev.
24
,
621
(
2004
).
3.
R. S.
McDonald
,
J. Phys. Chem.
62
,
1168
(
1958
).
4.
K.
Davis
and
M.
Tomozawa
,
J. Non-Cryst. Solids
201
,
177
(
1996
).
5.
R.
Sato
and
M.
Tomozawa
,
J. Non-Cryst. Solids
343
,
26
(
2004
).
6.
R.
Mozzi
and
B.
Warren
,
J. Appl. Crystallogr.
2
,
164
(
1969
).
7.
Q.
Mei
,
C.
Benmore
,
S.
Sen
,
R.
Sharma
, and
J.
Yarger
,
Phys. Rev. B
78
,
144204
(
2008
).
8.
T.
Charpentier
,
P.
Kroll
, and
F.
Mauri
,
J. Phys. Chem. C
113
,
7917
(
2009
).
9.
A.
Pedone
,
G.
Malavasi
,
M. C.
Menziani
,
U.
Segre
,
F.
Musso
,
M.
Corno
,
B.
Civalleri
, and
P.
Ugliengo
,
Chem. Mater.
20
,
2522
(
2008
).
10.
C.
Mischler
,
W.
Kob
, and
K.
Binder
,
Comput. Phys. Commun.
147
,
222
(
2002
).
11.
E. R.
Cruz-Chu
,
A.
Aksimentiev
, and
K.
Schulten
,
J. Phys. Chem. B
110
,
21497
(
2006
).
12.
J.
Du
and
A. N.
Cormack
,
J. Am. Ceram. Soc.
88
,
2532
(
2005
).
13.
C.
Wang
,
N.
Kuzuu
, and
Y.
Tamai
,
J. Non-Cryst. Solids
318
,
131
(
2003
).
14.
T.
Mahadevan
and
S.
Garofalini
,
J. Phys. Chem. C
112
,
1507
(
2008
).
15.
M. -H.
Du
,
A.
Kolchin
, and
H. -P.
Cheng
,
J. Chem. Phys.
120
,
1044
(
2004
).
16.
A. A.
Hassanali
and
S. J.
Singer
,
J. Phys. Chem. B
111
,
11181
(
2007
).
17.
M.
Du
,
A.
Kolchin
, and
H.
Cheng
,
J. Chem. Phys.
119
,
6418
(
2003
).
18.
A. C. T.
van Duin
,
S.
Dasgupta
,
F.
Lorant
, and
W. A.
Goddard
,
J. Phys. Chem. A
105
,
9396
(
2001
).
19.
J.
Yu
,
S. B.
Sinnott
, and
S. R.
Phillpot
,
Phys. Rev. B
75
,
085311
(
2007
).
20.
H. M.
Aktulga
,
S.
Pandit
,
A. C. T.
van Duin
, and
A.
Grama
, “
Reactive Molecular Dynamics: Numerical Methods and Algorithmic Techniques
” (submitted), available as a Purdue University Technical Report.
21.
A. K.
Rappé
and
W. A. I.
Goddard
,
J. Phys. Chem.
95
,
3358
(
1991
).
22.
Y.
Saad
and
M.
Schultz
,
SIAM (Soc. Ind. Appl. Math.) J. Sci. Stat. Comput.
7
,
856
(
1986
).
23.
K.
Chenoweth
,
A. C. T.
van Duin
, and
W. A.
Goddard
,
J. Phys. Chem. A
112
,
1040
(
2008
).
24.
S.
Nosé
,
J. Chem. Phys.
81
,
511
(
1984
).
25.
H. J. C.
Berendsen
,
J. P. M.
Postma
,
W. F.
van Gunsteren
,
A.
DiNola
, and
J. R.
Haak
,
J. Chem. Phys.
81
,
3684
(
1984
)
26.
G. J.
Martyna
,
D. J.
Tobia
, and
M.
Klein
,
J. Chem. Phys.
101
,
4177
(
1994
).
27.
K.
Vollmayr
,
W.
Kob
, and
K.
Binder
,
Phys. Rev. B
54
,
15808
(
1996
).
28.
N. T.
Huff
,
E.
Demiralp
,
C.
Tahir
, and
W. A. I.
Goddard
,
J. Non-Cryst. Solids
253
,
133
(
1999
).
29.
M.
Tarini
,
P.
Cignoni
, and
C.
Montani
,
IEEE Trans. Vis. Comput. Graph.
12
,
1237
(
2006
).
30.
A.
van Duin
,
A.
Strachan
,
S.
Stewman
,
Q.
Zhang
,
X.
Xu
, and
W.
Goddard
,
J. Phys. Chem. A
107
,
3803
(
2003
).
31.
A. C. T.
van Duin
,
V.
Bryantsev
,
J.
Su
, and
W. A.
Goddard
, “
Proton-transfer reactions
” (unpublished).
32.
T. T.
Trinh
,
A. P. J.
Jansen
, and
R. A.
van Santen
,
J. Phys. Chem. B
110
,
23099
(
2006
).
33.
H. J. C.
Berendsen
,
J. R.
Grigera
, and
T. P.
Straatsma
,
J. Phys. Chem.
91
,
6269
(
1987
).
34.
M.
Sprik
,
J.
Hutter
, and
M.
Parrinello
,
J. Chem. Phys.
105
,
1142
(
1996
).
35.
W. S.
Benedict
,
N.
Gailar
, and
E. K.
Plyler
,
J. Chem. Phys.
24
,
1139
(
1956
)
36.
S. A.
Clough
,
Y.
Beers
,
G. P.
Klein
, and
L. S.
Rothman
,
J. Chem. Phys.
59
,
2254
(
1973
).
37.
Y. S.
Badyal
,
M. -L.
Saboungi
,
D. L.
Price
,
S. D.
Shastri
,
D. R.
Haeffner
, and
A. K.
Soper
,
J. Chem. Phys.
112
,
9206
(
2000
).
38.
R.
Bentwood
,
A.
Barnes
, and
W.
Orville-Thomas
,
J. Mol. Spectrosc.
84
,
391
(
1980
).
39.
K.
Kuchitsu
and
Y.
Morino
,
Bull. Chem. Soc. Jpn.
38
,
805
(
1965
).
40.
A.
Soper
,
J. Chem. Phys.
101
,
6888
(
1994
).
41.
K.
Krynicki
,
C. D.
Green
, and
D. W.
Sawyer
,
Faraday Discuss. Chem. Soc.
66
,
199
(
1978
).
42.
T. A.
Halgren
and
W.
Damm
,
Curr. Opin. Struct. Biol.
11
,
236
(
2001
).
43.
D. A.
Kemp
and
M. S.
Gordon
,
J. Phys. Chem. A
112
,
4885
(
2008
).
44.
P.
Chaikin
and
T.
Lubensky
,
Principles of Condensed Matter Physics
(
Cambridge University Press
,
Cambridge
,
1995
).
45.
A.
Takada
,
P.
Richet
,
C.
Catlow
, and
G.
Price
,
J. Non-Cryst. Solids
345
,
224
(
2004
).
46.
P.
Vashishta
,
R. K.
Kalia
, and
J. P.
Rino
,
Phys. Rev. B
41
,
12197
(
1990
).
47.
D. I.
Grimley
and
A. C.
Wright
,
J. Non-Cryst. Solids
119
,
49
(
1990
).
48.
J.
Da Silva
,
D.
Pinatti
,
C.
Anderson
, and
M.
Rudee
,
Philos. Mag.
31
,
713
(
1975
).
49.
V.
Sokhan
and
D.
Tildesley
,
Mol. Phys.
92
,
625
(
1997
).
50.
E.
Papirer
,
Adsorption on Silica Surfaces
,
Surfactant Science Series
, Vol.
90
(
Dekker
,
New York
,
2000
).
51.
L.
Zhuravlev
,
Colloids Surf., A
173
,
1
(
2000
).
52.
T.
Bakos
,
S.
Rashkeev
, and
S.
Pantelides
,
Phys. Rev. Lett.
88
,
055508
(
2002
).
53.
S. A.
Pandit
,
Soft Matter Lipid Bilayers and Red Blood Cells
(
Wiley-VCH
,
Weinheim
,
2008
), Vol.
4
.
54.
S.
Ong
,
X.
Zhao
, and
K.
Eisnthal
,
Chem. Phys. Lett.
191
,
327
(
1992
).
You do not currently have access to this content.