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8/3/2019 Hemali Davande et al- Quantum Chemistry–Based Force Field for Simulations of Energetic Dinitro Compounds
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Quantum Chemistry–Based Force Field forSimulations of Energetic Dinitro Compounds
HEMALI DAVANDEOLEG BORODINGRANT D. SMITH
Department of Chemical Engineering and Departmentof Materials Science & Engineering, University of Utah,Salt Lake City, UT, USA
THOMAS D. SEWELL
Theoretical Division, Los Alamos National Laboratory,Los Alamos, NM, USA
A quantum chemistry–based force field for molecular dynamics simulations of energetic dinitro compounds has been developed, based on intermolecular binding energies,molecular geometries, molecular electrostatic potentials,
and conformational energies obtained from quantumchemistry calculations on model compounds. Nonbonded parameters were determined by fitting experimental densi-ties and heats of vaporizations of model compounds.Torsional parameters were parameterized to reproduce accurately the relative conformational energy minima and barriers in 2,2-dinitropropane, di-methoxy di-methyl ether, 2,2-dinitro-3-methoxypropane, and bis(2,2-dini-tropropyl)formal. Molecular dynamics simulations using the developed force field accurately reproduce thermo-dynamic and transport properties of 1,1-dinitroethane,
Address correspondence to G. D. Smith, Department of Chemical
Engineering and Department of Materials Science & Engineering, 122South Central Campus Dr., Room 304, University of Utah, Salt LakeCity, Utah, 84112, USA. E-mail: [email protected]
Energetic Materials , 23: 205–237, 2005Copyright # Taylor & Francis Inc.ISSN: 0737-0652 print
DOI: 10.1080/07370650591006885
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2,2-dinitropropane, and a eutectic mixture of bis(2,2-
dinitropropyl)formal and bis(2,2-dinitropropyl)acetal.
Keywords: PBX, molecular orbital calculations, heteroge-neous explosives
1. Introduction
Dinitro compounds have important applications as componentsof rocket propellant charges and as plasticizers in plastic-bonded explosives (PBXs), due in part to their relatively largedecomposition energies [1]. We are interested in using molecu-
lar simulations to improve our understanding of the mechanicaland thermophysical behavior of PBXs, in particular PBX-9501 [2], which is composed of 94.9-wt% HMX (octahydro-1,3,5,7-tetranitro-1,3,5,7-tetrazocine), 2.5-wt% EstaneTM 5703[poly(butylene adipate-co-tetramethylene diphenyl-urethane),hereafter referred to simply as Estane], and 2.5-wt% nitro-plasticizer [50=50-wt% eutectic of bis(2,2-dinitropropyl)formal=acetal, denoted hereafter as BDNPF=A]. Molecularmodeling of PBX-9501 composites and specific interactionsamong its components has been complicated by the absenceof accurate force fields for the constituent materials. This paperis one in a series of reports on force field development and mole-
cular simulations of PBX-9501 constituents. Force field devel-opment and validation for HMX [3] and Estane [4] has beenreported previously; analogous development and validation of a quantum chemistry–based force field for model dinitro com-pounds and dinitro plasticizer are reported here.
BDNPF=A plasticizer is cost effective to use and safe tohandle. It provides excellent propellant and explosive physicalproperties and enhances the performance of formulations whileproviding additional energy to the composite. It also exhibitsgood long-term stability. BDNPF=A plasticizer acts as a lubri-cant within the polymeric binder network, reducing the elastic
modulus and lowering the glass transition temperature of thepolymer. Large amounts of energetic plasticizer can increasethe specific impulse of the propellant and reduce the possibility
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of cracking [5]. BDNPF=A is used in both U.S. and British sys-
tems, for example, U.S. Navy underwater and airburst plastic-bonded explosive formulations [6]. It is widely used in warheadsfor torpedoes, missiles, and projectiles. Most recent applica-tions of this material have been in low-vulnerability gun propel-lant, insensitive high explosives, and insensitive munitions, allused and currently fielded by the U.S. Army [6]. Plasticizedpolyurethanes are used as binders for high explosives to impartstructural integrity to the composite, aid in processing, anddecrease the sensitivity to external stimuli [7]. Although bothBDNPF and BDNPA are solid at room temperature, the50=50-wt% mixture of the two forms a eutectic with a lower
melting point than early plasticizers such as nitroglycerin anddiethyl phthalate [8].Atomistic classical molecular dynamics (MD) simulations
can provide molecular-level understanding of the partitioningof nitroplasticizer between the ‘‘hard’’ and ‘‘soft’’ segment-richdomains [4] in microphase-segregated, segmented poly(esterurethane), the resulting domain structure; and the influenceof this domain structure, on thermodynamic, mechanical,dynamic, and transport properties of the binder. To utilize ato-mistic MD simulations for studies of PBX-9501 binder, accuratedescriptions of the molecular geometry and conformationalenergetics of Estane and BDNPF=A nitroplasticizer are
required. The formulation of a quantum chemistry–based forcefield for BDNPF is the principal subject of the present work.
We report in Section 2 high level ab initio quantumchemistry calculations for some important energetic dinitrocompounds, including BDNPF, 2,2-dinitro-3-methoxypropane(DNMP), and di-methoxy di-methyl ether (DMDME). InSection 3, a classical, analytic force field is developed basedon fitting the equilibrium geometries and conformationalenergetics obtained from the quantum chemistry calculationsdescribed in Section 2, with subsequent minor adjustments tomatch the available thermodynamic data. The ability of the
resultant force field to reproduce accurately thermodynamicand transport properties of dinitro compounds is presentedand discussed in Section 4.
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2. Quantum Chemistry Calculations
In this section we report ab initio quantum chemistry cal-culations of equilibrium geometries and conformational ener-getics of several compounds that will be utilized in the actualforce field parameterization for BDNPF. As we cannotperform extensive high-level quantum chemistry studies onthe full BDNPF molecule (Figure 1(a)) or BDNPA molecule(Figure 1(b)), we carried out most of our investigations forsmaller dinitro compounds that possess subsets of the chemi-cal linkages and dihedral arrangements that occur inBDNPF (Figures 1(c)–1(e)). However, the combined set of model compounds spans the set of relevant interactions in
BDNPF. We performed quantum chemistry calculations onlyfor the full BDNPF molecule for a selection of low-energyconformations as a test of transferability of the force fielddeveloped on the basis of the smaller compounds to the tar-get molecule.
All ab initio quantum chemistry calculations were per-formed using the Gaussian 98 package [9]. Density functionaland Hartree-Fock theory were used for initial geometry opti-mizations of the model compounds. The hybrid B3LYPfunctional [10,11] and 6-31GÃ basis sets were used for DNP,DNMP, DMDME, and BDNPF. Following our previous
work on a variety of polymers including polyethylene oxide,polypropylene oxide, 1,2-dimethoxyethane [12,13], HMX [3],and Estane [4], we used these comparatively inexpensive‘‘scoping’’ calculations as a starting point for determinationof more accurate conformational geometries and energeticsat the B3LYP, HF, and MP2 levels, using the B3LYP=aug-augmented correlation consistent polarized valence double-fbasis sets (aug-cc-pvDz) [14].
Conformational energies and geometries for DMDME,DNP, and DNMP for important conformers and rotationalbarriers corresponding to HF, B3LYP, and MP2 theory in con-
junction with the aug-cc-pvDz basis set are summarized in
Tables 1–3, respectively, and will be discussed in subsequentsections.
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Figure 1. Molecular structures. Circles with brick pattern:nitrogen; empty circles : hydrogen; gray circles : carbon; circles with diagonal hash: oxygen. (a) Labeling of the unique torsionsin bis(2,2-dinitropropyl)formal (BDNPF). u1 and u6 areCÀCÀCÀO torsions; u3 and u4 are CÀOÀCÀO torsions; u5
and u2 are CÀOÀCÀC torsions; and u7, u8, u9 and u10 areOÀNÀCÀC torsions. (b) bis(2,2-dinitropropyl)acetal(BDNPA). (c) di-methoxy di-methyl ether (DMDME). u11
and u12 are CÀOÀCÀO torsions. (d) 2,2-dinitro-3-methoxy
propane (DNMP). (e) 2,2-dinitropropane (DNP).
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Figure 1. Continued.
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Table 1
Relative conformational energies for di-methoxy di-methylether (DMDME) as obtained from the parameterized force
field (normal text) and quantum chemistry (MP2=aug-cc-pvDz==B3LYP=aug-cc-pvDz, italics)
Torsional angles (degree)
ConformerEnergy
(kcal=mol) u3
a u4 u11 u12
gggg 0.00 78.0 83.7 83.7 78.10.00 68.2 73.4 74.3 68.7
gg145g
b
3.95 79.0 80.3 145.0
c
79.03.11 68.7 70.5 145.0 69.0 gg152g 3.31 78.9 81.4 152.0 79.3
3.05 68.7 69.9 152.0 69.0 ggtg 1.11 79.7 85.1 182.2 79.5
2.98 68.7 70.5 159.7 69.0 gg220g 3.42 80.9 84.7 220.9 80.4
3.10 73.7 79.1 220.9 73.5 ggg Àg 1.53 75.4 91.3 272.5 94.5
2.83 66.0 87.0 265.0 85.0 gg345g 9.31 75.0 76.9 345.0 100.5
9.09 65.6 88.3 345.0 103.6
ggg Àg À 1.36 78.7 83.0 276.9 281.21.66 71.6 97.0 296.0 294.5
g138g Àg À 3.66 79.6 138.0 279.9 284.23.15 60.0 138.0 293.0 294.0
g Àtg Àg À 1.11 280.5 177.8 274.8 280.42.42 292.0 196.0 291.0 292.0
a u3, u4, u11, and u12 are the CÀOÀCÀO torsions in DMDME
(see Figure 1(c)).b The conformer notation gg145g means torsion u11 was con-
strained to 145.c Numbers in bold denote constrained torsions.
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Table 2
Relative conformational energies for 2,2-dinitropropane (DNP)as obtained from the parameterized force field (normal text)
and from quantum chemistry (MP2=aug-cc-pvDz==B3LYP=aug-cc-pvDz, italics)
ConformerEnergy
(kcal=mol)
Torsionu7
a
(degree)
Torsionu8
(degree)
tg þ 0.00 161.6 96.00.00 167.4 111.1
180g þb 0.40 180.0c 90.1
0.31 180.0 102.9 150g þ 0.27 150.0 101.1
0.38 150.0 121.5 135tÀ 0.99 135.0 143.8
0.98 135.0 133.2 120tÀ 1.23 120.0 152.4
1.35 120.0 150.3 105t 1.00 105.0 160.4
1.14 105.0 167.6 90t 0.32 90.0 193.2
0.59 90.0 179.3
75t 0.01 75.0 199.10.09 75.0 188.0 g þ t 0.32 90.0 180.0
0.58 90.0 180.0
g þ tÀ 1.24 120.0 150.0
1.36 120.0 150.0
g þ tÀ (saddle)d 1.22 117.6 153.7
1.38 117.6 153.4gtÀ (saddle) 1.81 26.6 154.1
2.63 26.6 154.1g þg À 1.23 120.0 330.0
1.36 120.0 330.0
(Continued )
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Table 2
Continued
ConformerEnergy
(kcal=mol)
Torsionu7
a
(degree)
Torsionu8
(degree)
g þcis 1.96 120.0 0.0
2.39 120.0 0.0
a u7 and u8 represent OÀNÀCÀC torsions in DNP (see Figure
1(e)).b The conformer 180g þ means torsion u7 was constrained to 180.c
Numbers in bold font denote constrained torsions.d The ‘‘saddle’’ notation here corresponds to single-point calcula-tions done using quantum chemistry studies. The correspondingmolecular mechanics energies were obtained by constraining thetorsions u7 and u8 to quantum chemistry values.
Table 3
Relative conformational energies for 2,2-dinitro-3-methoxypropane (DNMP) as obtained from the parameterized forcefield (normal text) and from quantum chemistry (MP2=aug-
cc-pvDz==B3LYP=aug-cc-pvDz, italics)
ConformerEnergy
(kcal=mol)
Torsionu1
a
(degree)
Torsionu2
(degree)
gt 0.00 62.3 172.30.00 62.3 175.3
tt 2.55 182.8 178.02.67 167.0 176.0
tg 3.07 162.7 74.93.85 156.0 88.8
gg 2.95 60.0b 60.0
3.31 60.0 b 60.0
(Continued )
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Table 3
Continued
ConformerEnergy
(kcal=mol)
Torsionu1
a
(degree)
Torsionu2
(degree)
g95 c 1.56 54.9 95.0
1.18 55.0 95.0
gg À 4.46 60.0 280.0
4.44 60.0 280.0
gg À (saddle)d 2.95 82.5 277.53.39 82.5 277.5
tg þ 3.07 162.7 75.03.69 160.6 110.4
120t 6.47 120.3 156.06.68 120.3 176.5
g120 0.90 66.3 120.0
0.92 63.1 120.0
cisg 5.41 0 97.9
5.55 0.50 97.9
cisg (saddle) 5.51 351.7 101.45.67 351.7 101.4
cist 4.57 0 181.5
4.47 0 183.4cist (saddle) 4.66 6.1 180.9
4.63 6.1 180.9
a u1 and u2 represent CÀCÀCÀO and CÀOÀCÀC torsions,
respectively (see Figure 1(d)).b Bold font is used to identify the constrained torsions.c The conformer notation g95 means torsion u2 was constrained
to 95.d The ‘‘saddle’’ notation here corresponds to single-point calcula-
tions done using quantum chemistry studies. The correspondingmolecular mechanics energies were obtained by constraining the tor-sions u1 and u2 to quantum chemistry values.
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3. Force Field Development
Methodology
The classical force field represents the total potential energyV ðr Þ of a collection of atoms with positions given by the vector~R R as a sum of nonbonded interactions V NBð~R R Þ and energy con-tributions due to all bond, valence bend, torsional, and defor-mational interactions:
V ð~R R Þ ¼ V NBð~R R ij Þ þX
bonds
V BOND ðr ij Þ þX
bends
V BEND ðhijk Þ
þ
Xtorsions
V TORS ðuijkl Þ þ
Xdeformations
V DEFORM ðdijkl Þ: ð1Þ
The nonbonded energy V NBð~R R ij Þ consists of a sum of thetwo-body repulsion and dispersion energy terms between atomsi and j , represented by the Buckingham exponential-6 poten-tial, and the energy due to the interactions between fixed par-tial atomic charges (i.e., Coulombic terms):
V NBð~R R ij Þ ¼1
2
XN
i; j ¼1
Aij expðÀBij R ij Þ ÀC ij
R 6ij
þqiq j
4peo R ij : ð2Þ
Nonbonded interactions were included between all atoms of different molecules and between atoms of the same molecule
separated by more than two bonds (1–4 interactions included).The following combining rules were used to evaluate interac-tions between different types of atoms:
Aij ¼ ffiffiffiffiffiffiffiffiffiffiffiffi
AiiA jj
p ;
Bij ¼Bii þ B jj
2;
C ij ¼ ffiffiffiffiffiffiffiffiffiffiffiffi
C iiC jj
p :
ð3Þ
Contributions due to covalent interactions were repre-sented as the following:
V BOND ¼1
2k bond
ij ðr ij À r 0ij Þ2; ð4Þ
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V BEND
ðhijk Þ ¼
1
2 k bend ijk ðhijk À h
0ijk Þ
2
; ð5Þ
V TORS ðuijkl Þ ¼1
2
Xn
k tors ijkl ðnÞ½1 À cosðnuijkl Þ; ð6Þ
V DEFORM ¼1
2k d
ijkl d2ijkl : ð7Þ
Here r 0ij is an equilibrium bond length,1 h0ijk is an equilibrium
valence bend angle, and dijkl is an out-of-plane bend (i.e., theangle between the plane containing atoms i, j , and k and thebond between atoms k and l ); k bond
ij , k bend ijk , k tors
ijkl (n), and k d ijkl
are the bond, bend, torsion, and deformation force constants,respectively. The indices indicate which (bonded) atoms areinvolved in the interaction.
In this contribution we follow the force field developmentmethodology applied previously to HMX [3], Estane [4], and anumber of other polymers [12,13]. Specifically, we obtain par-tial atomic charges by fitting the electrostatic potentialobtained from a quantum mechanical wavefunction=densityon a grid of points for each of the model compounds. We eitheruse published repulsion=dispersion parameters for compoundswith chemical environments similar to those of interest here,or fit them ourselves to available thermodynamic data for those
compounds for which interaction parameters have not beenreported. The ‘‘equilibrium’’ bond lengths and bending anglesare adjusted to reproduce equilibrium geometries of model com-pounds obtained from quantum chemistry. Finally, we fit thetorsional parameters to reproduce the geometries and confor-mational energetics of model compounds, obtained from high-level quantum chemistry calculations.
1Note that the natural bond length or bond angle for a given bondor valence angle does not necessarily correspond to the bond length or
angle of the molecular mechanics optimized geometry of a molecule.Nonbonded interactions can result in an optimized bond length orangle that differs from the equilibrium value.
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Repulsion=Dispersion Parameters
The parameters for carbon (C) and hydrogen (H) were takenfrom our previous studies on polyethylene and poly(oxymethy-lene) [15]. It was found that the repulsion=dispersion para-meters for nitrogen and oxygen taken from studies on HMX[3], where they were derived for a nitro (ÀNO2) group attachedto nitrogen, were not suitable to describe the potential energyand the dynamics for compounds containing the dinitro func-tionality attached to carbon. Thus, using the calculated chargesand optimized geometric parameters, the repulsion=dispersionparameters for nitrogen and oxygen were adjusted to yieldthe best overall agreement between experimental densities
and enthalpies of vaporization and those calculated from liquidphase molecular dynamics (see Table 4), for DNP, DNE,BDNPF, and BDNPF=A. Once this initial set of ‘‘optimal’’nonbonded parameters was obtained, the entire procedure,starting from refits of the valence parameters, was reiteratedmultiple times until a converged best fit was obtained. Theresulting optimized repulsion=dispersion parameters arereported in Table 5.
Partial Atomic Charges
The different atom types employed for determination of partialcharges are illustrated in Figure 2. The different charge groupsused were (1) Ce, for carbon atoms in end groups (CH3) of BDNPF; (2) Cn, for carbon atoms attached to NO2 groups;(3) Cn, for carbon atoms attached to oxygen (atom of type O,see below) on one side and carbon atom of type Cn on the otherside; (4) Cl, for carbon atoms attached to carbon atoms of typeCn and Ce in DNMP; (5) Cll, for carbon atoms attached tooxygen atoms (of type O, see below) on both sides of the centralcarbon in BDNPF; (6) O, for oxygen; (7) On, for oxygen atomsin an NO2 group; (8) H, for hydrogen atoms attached to carbon
atom of type Ce; (9) Hm, for hydrogen atoms attached to carbonatoms of type Cn; and (10) Hl, for hydrogen atoms attached tocarbon atoms of type Cl (in DNMP) or Cll (in BDNPF). We
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T a b l e 4
C
o m p a r i s o n o f
t h e r m o
d y n a m
i c p
r o p e r t i e s o
b t a i n e d
f r o m s i m u l a
t i o n s
t o e x p e r i m e n
t a l r e s u
l t s
( i n p a r e n
t h e s e s )
L i q u i d
T e m p e r a t u r e
( K )
B o x
s i z e ( A ˚
) R o u s e
t i m e
( p s )
E q u
i l i b r a t i o n
t i m e
( n s )
P r o d u c t i o n
r u n
t i m
e ( n s )
D e n s i t y
( g = c c )
E n
t h a l p y
o f
v a p o r i z a t i
o n
( k c a l = m o
l )
D N P a
2 9 8
2 5 . 9
2 0
1 . 0
N P T
- 1 . 5
1 . 2 6 7
1 3 . 8
N V T
- 1 . 5
( 1 . 3
) b
( 1 3 . 7 ) c
D N E d
2 9 8
2 4 . 7
1 5
1 . 0
N P T
- 2 . 0
1 . 3 1 6
1 4 . 2
N V T
- 2 . 0
( 1 . 3
5 4 ) e
( 1 4 . 6 ) c
B D N P
F f
4 0 0
2 2 . 3
6 0 0
3 . 0
N P T
- 3 . 0
( — ) g
2 2 . 6
N V T
- 2 . 0
( 1 7 . 9 ) h
E u
t e c t i c m
i x t u r e
2 9 8
2 9 . 0
3 0 , 0
0 0
5 . 0
N P T
- 8 . 0
1 . 3 5 9
( 1 . 3
8 3 – 1 . 3 9
7 ) i
( — ) g
a 2 , 2 - d
i n i t r o p r o p a n e , s e e F i g u r e 1 ( e ) .
b R
e f e r e n c e [ 2 5 ] .
c R
e f e r e n c e [ 2 4 ] .
d 1 , 1 - d
i n i t r o e t h a n e .
e R
e f e r e n c e [ 2 3 ] .
f b i s ( 2 , 2 - d i n i t r o p r o p y l ) f o r m a l , s e e F i g
u r e 1 ( a ) .
g N
o e x p e r i m e n t a l r e s u l t s a r e a v a i l a b
l e f o r c o m p a r i s o n .
h R
e f e r e n c e [ 2 6 ] a n d s e e t e x t i n S e c t i o n 4 .
i R e f e r e n c e [ 2 6 ] .
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used MP2=aug-cc-pvDz==B3LYP=aug-cc-pvDz for determina-tion of charges, for the lowest energy conformations obtainedfor each model compound. Note that new atom types weredefined for hydrogen atoms bonded to carbons, which arebonded in turn to comparatively electronegative atoms. Thestandard electrostatic potential (ESP) derived charges are thecoefficients that yield the optimal least-squares fit to the model
function for the given set of ESP points.Within this approach, charges obtained for the internal
atoms can fluctuate significantly, while exerting only minimalinfluence on the objective function (v2) for the fit to the ESP.To mitigate this effect, the partial atomic charges for the modelcompounds and BDNPF were determined using restrained elec-trostatic potential (RESP) fitting [16,17]. The electrostaticpotential envelope cutoffs were set to the van der Waals radii:1.8A for hydrogen, 2.5 A for carbon and nitrogen, and 2.0 A foroxygen. The electrostatic potential was evaluated at approxi-mately 350,000 points for each model compound; the fit was
constrained to yield net charge neutrality for each molecule.The partial atomic charges for different atom types in DNMP,DNP, and BDNPF are given in Table 6.
Table 5
Final repulsion (A and B) and dispersion (C ) forcefield parameters
Nonbonded, U NB~R R ¼1
2
XN
i; j ¼1
Aij expðÀBij R ij Þ ÀC ij
R 6ij
Atompair
Aij
(kcal=mol) Bij (AÀ1)C ij
(kcal molÀ1 AÀ6) Source
CÀC 14976.00 3.09 640.08 [15]OÀO 78877.76 4.06 319.12 This workNÀN 63267.40 3.78 250.00 This work
HÀH 2649.60 3.74 27.40 [15]CÀH 4320.00 3.42 138.24 [15]
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Figure 2. Atom type definitions for assigning partial atomiccharges in (a) bis(2,2-dinitropropyl)formal (BDNPF), (b) 2,2-dini-tro-3-methoxy propane (DNMP), (c) 2,2-dinitropropane (DNP).
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Bonded Interaction Parameters The values for k bond and k bend were taken from work on HMX[3], Estane [4], polyethylene and poly(oxymethylene) [15], andpoly(oxyethylene) and 1,2-dimethoxyethane [18]. Molecularmechanics geometry optimization was performed on each modelcompound, with initial guesses for equilibrium bond lengths r 0and bond angles h0. The values of bond lengths r 0 and bondangles h0 (taken from the corresponding references for k bond
and k bend ) were adjusted to provide the best match betweenmolecular mechanics– and quantum chemistry–optimizedgeometries. The results are listed in Table 7. In the final pass
for optimization of r 0 and h0, the repulsion=dispersion para-meters given in Table 4 and the partial charges given in Table6 were used. The optimized r 0 and h0 from DNMP were used for
Table 6
Partial atomic charges for model compounds and BDNPF,calculated using quantum chemistry (MP2=aug-cc-pvDz==
B3LYP=aug-cc-pvDZ)
Atom type DNMPa DNPb BDNPFc
Ce
d À0.1809 À0.6079 À0.1809Cn 0.2855 0.5646 0.2855Ch À0.1314 – À0.1314N 0.5122 0.5178 0.5122O À0.2364 À0.3708 À0.2364On À0.3444 – À0.3444
H 0.0825 0.1831 0.0825Cl À0.2024 – –Hm 0.1035 – 0.1035Hl 0.1221 – 0.1221Cll – – 0.0835
a 2,2-dinitro-3-methoxy propane (see Figure 1(d)).b 2,2-dinitropropane (Figure 1(e)).c bis(2,2-dinitroproyl)formal (Figure 1(a)).d Refer to Figure 2 for atom type definitions.
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T a b l e 7
B i s ( 2
, 2 - d
i n i t r o p r o p y
l ) f o r m
a l ( B D N P F ) f o r c e
f i e l d ( c o v a l
e n t i n t e r a c t i o n s o n
l y )
V b o n d ð r i j Þ ¼
1 2 k b o n d
i j
ð r i j À
r 0 i j Þ 2
B o n d
t y p e
k b o n d
( k c a
l m o
l À 1
A ˚ À 2 )
r 0 ( A ˚ )
Q C ( A ˚ )
( a v g
)
M M
( A ˚ ) ( a v g
)
S o u r c e
C À
C
6 1 8
. 0
1 . 4 6 8
1 . 5 2 2
1 . 4 9 8
[ 1 5
]
C À
H
6 5 5
. 0
1 . 0 9 8
1 . 0 9 8
1 . 0 8 7
[ 1 5
]
C À
N
6 7 2
. 0
1 . 5 1 2
1 . 5 4 5
1 . 5 2 6
[ 4
]
O À
N
1 9 9 0 . 1
1 . 2 2 1
1 . 2 2 0
1 . 2 2 2
[ 3
]
C À
O
7 3 9
. 0
1 . 4 0 6
1 . 4 1 8
1 . 4 1 2
[ 1 5
]
V
b e n d ð h i j k
Þ ¼
1 2 k b e n d
i j k
ð h i j k À
h 0 i j k Þ
2
B e n d
t y p e
k b e n d
( k c a l m o l À 1
r a d À 2 )
h 0
( d e g r e e )
Q C
( d e g r e e ) a
M M
( d e g r e e ) b
S o u r c e
C À
C À
C
1 0 5 . 0
1 2 2
. 1
1 1 4 . 9
1 1 4 . 9
[ 1 5
]
C À
C À
O
1 1 9 . 0
1 0 4
. 9
1 0 6 . 5
1 0 6 . 8
[ 1 8
]
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C À
O À
C
1 4 9 . 0
1 1 1 . 2
1 1 2
. 6
1 1 3
. 5
[ 1 5
]
C À
C À
H
8 5 . 8
0
1 1 0 . 1 0
1 0 9
. 9
1 1 0
. 5
[ 1 5
]
C À
C À
N
1 4 4 . 0
1 0 9 . 4
1 0 9
. 3
1 0 8 . 2
[ 4
]
O À
N À
C c
1 2 5 . 0
1 1 2 . 9
1 1 6
. 8
1 1 6 . 6
[ 3
]
H À
C À
O
1 1 2 . 0
1 0 7 . 1
1 0 9
. 6
1 0 8
. 9
[ 1 5
]
H À
C À
H
7 7 . 0
1 0 8 . 5
1 0 9
. 5
1 0 8
. 2
[ 1 5
]
O À
N À
O
1 2 5 . 0
1 2 6 . 4
1 2 6
. 5
1 2 6 . 5
[ 3
]
N À
C À
N
1 4 4 . 0
1 1 6 . 2
1 0 4
. 0
1 0 9 . 0
[ 3
]
O À
C À
O
1 4 4 . 0
1 2 0 . 8
À
À
[ 4
]
V t o r s ð /
i j k l Þ ¼
P n
1 2 k t o r s
i j k l
ð n Þ ½ 1 À
c o s ð n / i j k l Þ
T o r s i o
n
k t o r s
1
( k c a l = m o
l )
k t o r s
2
( k c a l = m o
l )
k t o r s
3
( k c a
l = m o l )
k t o r s
4
( k c a
l = m o
l )
S o u r c e
C À
C À
C À
O
À 1 . 8 9 9 0
0 . 6 9 5 0
2 . 7 0 0 0
–
T h i s w o
r k
C À
C À
O À
C
5 . 8 9 5 0
1 . 4 5 9 4
0 . 0 0 0 5
–
T h i s w o
r k
H À
C À
C À
C
0 . 0 0 0 0
0 . 0 0 0 0
À 0 . 2 7 7 9
–
[ 1 5 ]
O À
N À
C À
C
3 . 5 0 0 0
0 . 0 0 0 0
À 2 . 5 9 9 7
–
T h i s w o
r k
N À
C À
C À
O
À 3 . 1 2 5 0
1 . 1 1 5 0
À 1 . 1 9 0 0
–
T h i s w o
r k
H À
C À
O À
C
0 . 0 0 0 0
0 . 0 0 0 0
À 0 . 7 2 9 0
–
[ 1 5 ]
( C o n t i n u e d )
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T a b l e 7
C o n
t i n u e d
V t o r s ð /
i j k l Þ ¼
P n
1 2 k t o r s
i j k l
ð n Þ ½ 1 À
c o s ð n / i j k l Þ
T o r s i o
n
k t o r s
1
( k c a l = m o
l )
k t o r s
2
( k c a l = m o
l )
k t o r s
3
( k c a
l = m o l )
k t o r s
4
( k c a
l = m o
l )
S o u r c e
H À
C À
C À
N
0 . 0 0 0 0
0 . 0 0 0 0
À 0
. 2 7 7 9
–
S a m e a s
À H C C
C
O À
N À
C À
N
0 . 0 0 0 0
0 . 0 0 0 0
0 . 0
0 0 0
–
–
C À
O À
C À
O
À 0 . 5 9 4 8
À 2 . 1 9 3 4
À 0
. 1 7 9 0
1 . 9 8 0 0
T h i s w o
r k
V d e f o r m
¼
1 2 k d i j k l d
2 i j k l
O u
t - o f - p l a n e
b e n
d
k d
( k c a
l m o
l À 1
r a d À 2 )
S o u r c e
O À
N À
O À
C d
8 9 . 3
[ 3 ]
a O
p t i m i z e d g e o m e t r y o b t a i n e d a t M
P 2 = a u g - c c - p v D z = = B 3 L Y P = a u g - c c - p v D Z l e v e l o f q u a n t u m c h e m i s t r y
.
b O
p t i m i z e d g e o m e t r y o b t a i n e d u s i n g
m o l e c u l a r m e c h a n i c s m i n i m i z a t i o
n o f t h e B D N P F f o r c e f i e l d
.
c T
h e f o r c e c o n s t a n t f o r t h e O À
N À O
b e n d i s a s s u m e d e q u a l t o t h a t f o r t h e O À
N À
C b e n d
.
d T
a k e n f r o m t h e o u t - o f - p l a n e b e n d c o n s t a n t f o r O À
N À
O À
N d e r i v e d f o r H M X [ 3 ] .
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BDNPF. The mean-square error for all bonds was 0.009 A, and
that for the valence bends was 1.9. These small fiducials sug-gest good transferability of the force field developed from smal-ler model compounds to BDNPF=A system.
Torsional Parameters
Because the expense of sufficiently high-level quantum chemis-try calculations precludes us from accurate determination of allBDNPF conformers and barriers among them, we have chosento fit torsional parameters for representative model compoundsand check their transferability to BDNPF by comparing mole-
cular mechanics and quantum chemistry results only for the mostimportant conformers in BDNPF. The torsional parameterswere optimized for model compounds, using optimized bondlengths and bond angles from Table 7, partial atomic charges fromTable 6 (DNMP), and nonbonded parameters from Table 5.
The torsional parameters for CÀOÀCÀO were obtainedfrom the molecular mechanics force field for DMDME(Figure 1(c)). To achieve direct transferability of the torsionalparameters, the charges on the atoms for DMDME were takenfrom BDNPF. A comparison of energies and geometries of DMDME from quantum chemistry and the force field is givenin Table 1.
For DNP the parameters for the OÀNÀCÀC torsion(Figure 1(e)) were adjusted to yield the best agreement betweenthe conformational energies and geometries obtained from quan-tum chemistry (MP2=aug-cc-pvDz==B3LYP=aug-cc-pvDz) andmolecular mechanics. From the conformational energy plot forDNP shown in Figure 3, we conclude that the molecularmechanics force field accurately reproduces the saddle pointsand minima for this model compound. The minimum energyOÀNÀCÀC (u7,u8) conformation at the MP2=aug-cc-pvDz==B3LYP=aug-cc-pvDz level was found to be tg þ (161.6, 96.0),and the maximum-energy conformation was found to be
gt-saddle (26.6
, 154.1
) with an energy 2.63 kcal=mol relativeto the minimum energy conformation. The energies of all theconformations studied for DNP are summarized in Table 2.
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The torsional parameters for OÀNÀCÀC were transferredfrom DNP to DNMP. Using the charges from Table 6 (DNP),the torsional parameters for CÀCÀCÀO, CÀCÀOÀC, and
NÀCÀCÀO (Figure 1(d)) were adjusted to match molecularmechanics and quantum chemistry energies and geometries.The conformational energy path for the CÀCÀCÀO torsion is
Figure 3. Comparison of conformational energies for DNPobtained from force field to quantum chemistry results (dihe-dral angles in degrees, relative energies in kcal=mol; see Figure1(e); additional details in Table 3).
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shown in Figure 4. The minimum energy CÀCÀCÀO (u1, u2)conformation at the MP2=aug-cc-pvDz==B3LYP=aug-cc-pvDzlevel was found to be gt (62.3, 172.3). Comparisons of theenergies of all the conformations studied for DNMP, includinga large number of conformations with one or both torsionsfixed, are summarized in Table 3. The out-of-plane bend forceconstants for OÀNÀOÀC were taken to be equal to theOÀNÀOÀN out-of-plane bend force constants in HMX [3].
Transferability of the Force Field from Model
Compounds to BDNPF
As a part of our validation of the potential, we studied thetransferability of the force field parameters developed for
Figure 4. Comparison of conformational energies for DNMPcalculated from the force field to quantum chemistry resultsat the MP2=aug-cc-pvDz==B3LYP=aug-cc-pvDz level of theory(dihedral angle in degrees, relative energies in kcal=mol).
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model compounds to BDNPF. We performed quantum chem-
istry studies on BDNPF for five important geometric minimalisted in Table 8, at the B3LYP=aug-cc-pvDz level. (In thiscase MP2=aug-cc-pvDz==B3LYP=aug-cc-pvDz was not com-putationally tractable with the available resources.) Thegtggtg conformer was found to have the minimum energy.The comparison between quantum chemistry– and molecularmechanics–based force field energies and the geometriesreveals that the developed potential can be successfully trans-ferred to BDNPF. The deviation between the quantumchemistry– and molecular mechanics–based energy differencesis less than 0.25 kcal=mol for all geometries. The deviation in
torsional angles between quantum chemistry– and molecular
Table 8
Comparison between the conformational energies and backbonetorsions for bis(2,2-dinitropropyl)formal (BDNPF) calculated
using the force field (normal text) and quantum chemistry(B3LYP=aug-cc-pvDz, italics)
ConformerEnergy
(kcal=mol)
Torsion (degree)
u1
a u2 u3 u4 u5 u6
gtggtg 0.00 65.3 184.8 82.1 82.1 184.8 65.30.00 61.8 184.6 61.3 59.4 182.4 65.7
gtgttg 1.78 66.9 187.8 82.2 179.1 174.6 66.01.89 64.2 168.7 71.3 184.6 174.8 64.1
gttttg 4.82 64.4 172.2 177.3 177.3 172.7 64.45.03 62.0 173.6 171.4 171.4 173.6 62.2
ttggtg 2.12 173.6 203.8 80.5 81.0 192.0 66.92.11 168.1 194.6 71.8 72.6 176.5 65.5
ttggtt 2.84 170.4 185.1 70.5 70.5 185.1 170.42.59 192.1 179.4 62.8 62.6 179.5 192.5
a u1 and u6 represent CÀCÀCÀO torsions, u3 and u4 represent
CÀOÀCÀO torsions, and u2 and u5 represent CÀOÀCÀC torsions(see Figure 1(a)).
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mechanics–based predictions is less than 20 for most of the
geometries considered.
Extension of Force Field for BDNPF to BDNPA
For the simulations of a eutectic mixture of BDNPF andBDNPA, the force field developed for BDNPF was adaptedto accommodate BDNPA. The repulsion=dispersion para-meters developed for BDNPF were transferred directly toBDNPA without modification, and likewise for the bond, bend,torsion, and out-of-plane bends force constants. The charge onthe carbon in the acetal group in BDNPA was adjusted such
that the ‘‘acetal’’ group has a total charge equal to that of the ‘‘formal’’ hydrogen atom in BDNPF (referred to as H l inFigure 2). The rest of the charges in BDNPA were taken tobe equal to the corresponding charges in BDNPF. The bond,bend, torsion, and deformation force constants for BDNPAwere taken from the corresponding force constants developedin the force field for BDNPF. For the HÀCÀCÀO andHÀCÀCÀH torsions, which are not present in BDNPF, thetorsional parameters were taken from the force field on poly(ethylene oxide) [11].
4. Molecular Dynamics Simulations
Molecular Dynamics Methodology
All simulations were carried out using the lucretius MD simula-tion package [19], using the Nose-Hoover thermostat and baro-stat. All production runs correspond to a pressure of oneatmosphere. A cutoff radius of 10 A was used for all van derwaals interactions. A multiple time-step integrator describedelsewhere [20] was employed. Covalent bond lengths were con-strained using the SHAKE algorithm [21]. The time step of integration for high-frequency vibrations (bends and torsions)was 0.5 fs. Nonbonded interactions within a cutoff radius of 6 A
were evaluated every 1.0fs, and those between 6 A and 10Awere evaluated every 2.0 fs. To account for long-range electro-static interactions, the particle Mesh Ewald algorithm [22]
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was used. The atomic stress tensor (employed in shear viscosity
calculations described below) was recorded every 10.0 fs.Further details regarding simulations specific to particular sys-tems and properties are provided in Table 4. For calculation of density and enthalpy of vaporization, equilibration was per-formed for at least five times as long as the slowest relaxationtime in a given system (referred to as the Rouse time in Table 4and defined as the time at which backbone end-to-end autocor-relation function decayed to a value of eÀ1). To calculate thesteady shear viscosity, equilibration was performed for at least20 times the longest relaxation time of the system, and the pro-duction run time was at least 300 times that relaxation time.
Thermodynamic Properties
We investigated the ability of our force field to reproduce=predict a variety of thermodynamic and transport propertiesof liquid dinitro compounds, including liquid DNE, DNP, andBDNPF=A eutectic.
Atomistic simulations were performed for DNE and DNP at298 K in the isobaric-isothermal (NPT) ensemble, in a cubic,three-dimensionally periodic simulation cell. The density andenthalpy of vaporization of DNE obtained from our liquidphase molecular dynamics simulations are 2.8(Æ0.5)% and
2.7(Æ0.3)% lower than the respective experimental values[23,24] (see Table 4). In the case of DNP, the density fromsimulations at 298 K is 2.5(Æ0.3)% lower than experiment[25], and the enthalpy of vaporization is 1.0(Æ0.5)% higherthan the reported value [23] (see Table 4). Overall, the calcu-lated densities and enthalpies of vaporization of DNE andDNP are in close agreement with experimental values.
The enthalpy of vaporization of BDNPF at 400 K wasobtained based on isothermal-isochoric (NVT) MD simulationsin a cubic box (see Table 4); the force field predicts a value of 22.6(Æ0.1) kcal=mol for this quantity. However, no direct
experimental measurements of the enthalpy of vaporization forBDNPF are available in the literature. Hence an approximatevalue was estimated by reading the vapor-pressure (P ) curve
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for BDNPF [26] and using the Clausius-Clapeyron equation to
obtain the enthalpy of vaporization (DE vap ):
d ln P
dT ¼DE vap
RT 2; ð8Þ
where R is the universal gas constant and T is the absolute tem-perature. The approximate value thus obtained for the enthalpyof vaporization of BDNPF at 400 K is 17.9(Æ0.4) kcal=mol.
Molecular dynamics simulations were performed on a mix-ture of 32 molecules of BDNPF and 30 molecules of BDNPA(i.e., the 50=50-wt% eutectic that comprises BDNPF=A plasti-
cizer) to obtain an equilibrium density for the mixture. Theeutectic mixture was allowed to relax initially at lower densi-ties, after which the density of the system was graduallyincreased to the experimental value. After that the systemwas equilibrated using NPT-MD at 298 K, until a steady-fluctu-ating density was achieved. The resulting value was 1.359(Æ0.015)g=cc, which is in excellent agreement (1.7–2.7%lower) with the experimental value of 1.383–1.397 g=cc [26].
Isothermal-isobaric MD simulations of the BDNPF=Aeutectic mixture were also performed at 328K to obtain thespeed of sound in the melt. At constant temperature and pres-sure, the isothermal bulk modulus (bT ) is related to volumefluctuations by [27]
bT ¼ VK BT = dV 2
NPT ; ð9Þ
where K B is Boltzmann constant and V is the average volume of the system at temperature T . From this, the speed of sound C can be obtained using
C ¼
ffiffiffiffiffiffibT
q
s ; ð10Þ
where q is the average density of the system.Experimentalists have used impulsive stimulated light scat-
tering (ISLS) to measure the sound speed in BDNPF=A eutectic
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at 328 K, and obtained a value of 1297.4–1301.9 m=s [26]. The
sound speed from our simulations is found to be 1323(Æ4) m=s, which is in quite reasonable agreement with theexperiments. (We note that, since it is an isentropic measure-ment, the ISLS sound speed should be greater than the corre-sponding isothermal value by perhaps a few percent, but wenevertheless regard the level of agreement obtained as a suc-cessful validation point for the force field.)
Transport Properties
The apparent self-diffusion coefficient for DNP from MDsimulations at 357 K is 0.70 Â 10À9 (Æ0.03 Â 10À9) m2sÀ1 which isabout 30% less than the experimental value of 1.0 Â 10À9m2 sÀ1
[28] (Figure 5). At 345 K it is 0.50Â 10À9(Æ0.02 Â 10À9)m2sÀ1, compared to 0.89 Â 10À9m2sÀ1 from experiment [28].
Figure 5. Comparison of the self-diffusion coefficient for DNP
obtained from MD simulations using the force field developedin this work to experimental results. (Calculated error bars weresmaller than the symbol size and hence not included in the plot.)
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Zero-frequency shear viscosities of the BDNPF=A eutectic
were calculated in the temperature interval 450 –700 K, in50 K increments, using the Einstein relation [27]
g ¼ limt!1
V
6K BTt
Xa6¼b
ðLabðtÞ À Labð0ÞÞ2
* + !; ð11Þ
where LabðtÞ ¼R t
0 P abðt0Þdt0, K B is the Boltzmann constant, T istemperature, t is time, P ab is the symmetric stress sensor, and V is the fixed volume of the simulation box. The lengths of simu-lation trajectories were chosen such that tsim >> sg, where sg isthe viscosity relaxation time defined as
gðsgÞ ¼ ð1 À e À1Þgðtsim ! 1Þ: ð12Þ
The shear viscosity was calculated by averaging the appar-ent viscosity data obtained from the Einstein equation for thespecified time interval. The details of the methodology usedto estimate the apparent average shear viscosity can be foundin our previous work on HMX [29]. Even with this approach,we could not compare directly our calculated shear viscosityto experimental values, which were measured in the vicinityof room temperature, since the required simulation lengthswould have been impractical. Therefore, we used temperatureextrapolation to obtain the shear viscosity of the BDNPF=A
eutectic at 323 K and at atmospheric pressure.The measured and calculated results for the BDNPF=A
shear viscosity are shown in Figure 6, along with the tempera-ture extrapolation. The experimental value of the shear viscos-ity at 323 K is reported to be 59 cP [26]; our extrapolatedprediction to that temperature is 62 cP. The calculated appar-ent activation energies are 5.6 and 6.7 kcal=mol for shear visc-osity and self diffusion, respectively, in the temperatureinterval 450–700K. The activation energy for shear viscosityextracted from the experimental data [26] in the temperatureinterval 280–323 K is 10.2 kcal=mol. According to the Eyring
expression for dense fluids [30], the simple relation (DE vap ¼nDE vis , where 2 n 5) holds for more than 100 substances,including associated liquids. The energy of vaporization is
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approximately equal to the cohesive energy; hence, it is possibleto compare DE vap and DE vis determined directly from atomisticsimulations. We obtain DE vap ¼ 22:3kcal=mol at 450 K, yield-ing a ratio DE vap =DE vis ¼ 3:9, which is entirely consistent withthe Eyring correlation.
5. Conclusions
We have developed a complete bonded and nonbonded forcefield for a series of energetic dinitro compounds representativeof bis(2,2-dinitropropyl)formal=acetal (BDNPF=A) based uponextensive ab initio electronic structure calculations of geome-tries and energies. This potential was successfully used foratomistic simulations of 2,2-dinitropropane (DNP), 1,1-
dinitroethane (DNE), and BDNPF=A. The densities for DNEand DNP obtained from MD simulations match experimentalvalues to within 3%, whereas the enthalpies of vaporization
Figure 6. ‘‘Arrhenius plot’’ for zero-frequency shear viscosityof BDNPF=A plasticizer.
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were within 7% of experimental values at 298 K and atmo-
spheric pressure. The force field also reproduced the speed of sound in BDNPF=A to within a few percent. Predictions of transport behavior (self-diffusion coefficients for DNP andzero-frequency shear viscosities for BDNPF=A) were consistentwith experiment. Based on these validation studies, we thinkthe force field can be used with reasonable confidence for simu-lations of a variety of dinitro compounds. Further, at this pointforce-field development has been completed for all importantconstituents of the plastic-bonded explosive PBX-9501, thusenabling detailed investigations into the physico-chemicalinteractions that occur in that material.
Acknowledgments
This research is funded by the University of Utah Center for theSimulation of Accidental Fires and Explosions (C-SAFE),funded by Department of Energy, Lawrence LivermoreNational Laboratory, under Subcontract B341493. T.D.S. isfunded by Los Alamos, which is supported by the United StatesDepartment of Energy under contract number W-7405-ENG-36with the University of California. T.D.S. wishes to thankRichard Browning (Los Alamos) for useful discussions; andBob Sander, Dana Dattelbaum, and Mike Whitehead (LosAlamos) for permission to use their ISLS-based sound speedsin the present article.
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