TY - JOUR
T1 - CL-20热膨胀和相变的ReaxFF-lg分子动力学模拟
AU - Li, Chang Lin
AU - Gan, Qiang
AU - Feng, Chang Gen
AU - Hu, Jing Wei
AU - Zhu, Shuang Fei
AU - Cheng, Nian Shou
N1 - Publisher Copyright:
© 2021, Editorial Board of Chinese Journal of Energetic Materials. All right reserved.
PY - 2021/4/25
Y1 - 2021/4/25
N2 - In order to analyze high temperature phase transformation of hexanitrohexaazaisowurtzitane (CL-20), phase transformation temperatures and coefficients of thermal expansion of ε-, β-, and γ-CL-20 were studied via ReaxFF-lg reactive force field molecular dynamics, with modified valence potential intercept. To validate the applicability of selected force field, the density, cell constant, lattice energy, and sublimation enthalpy for three types of CL-20 at room temperature were calculated. The third order Birch-Murnaghan equation of state was used to fit the p-V curve of ε-CL-20, with pressure ranging from 0 to 280 GPa. And the variation of bulk modulus (B0) and its partial derivative to pressure (B'0) with the increase of pressure is analyzed. High temperature phase transformation analysis shows that ε-and γ-CL-20 change phases at 398-423 K, of which the ε→γ phase transition occurs at atmospheric pressure, while the γ→ε phase transition needs 0.5 GPa or higher pressure; β-CL-20 transforms to ε crystal form at 448 K. The thermal expansion coefficient analysis shows that there is no obvious anisotropy in the high temperature thermal expansion process of ε-CL-20, while β- and γ-CL-20 show anisotropy in c direction and b direction, respectively. Results show that the modified ReaxFF-lg reactive force field is suitable for the study of phase transition of ε-, β-, and γ-CL-20 at high temperature and high pressure, while the accuracy of thermal expansion of β- and γ-CL-20 needs to be further improved.
AB - In order to analyze high temperature phase transformation of hexanitrohexaazaisowurtzitane (CL-20), phase transformation temperatures and coefficients of thermal expansion of ε-, β-, and γ-CL-20 were studied via ReaxFF-lg reactive force field molecular dynamics, with modified valence potential intercept. To validate the applicability of selected force field, the density, cell constant, lattice energy, and sublimation enthalpy for three types of CL-20 at room temperature were calculated. The third order Birch-Murnaghan equation of state was used to fit the p-V curve of ε-CL-20, with pressure ranging from 0 to 280 GPa. And the variation of bulk modulus (B0) and its partial derivative to pressure (B'0) with the increase of pressure is analyzed. High temperature phase transformation analysis shows that ε-and γ-CL-20 change phases at 398-423 K, of which the ε→γ phase transition occurs at atmospheric pressure, while the γ→ε phase transition needs 0.5 GPa or higher pressure; β-CL-20 transforms to ε crystal form at 448 K. The thermal expansion coefficient analysis shows that there is no obvious anisotropy in the high temperature thermal expansion process of ε-CL-20, while β- and γ-CL-20 show anisotropy in c direction and b direction, respectively. Results show that the modified ReaxFF-lg reactive force field is suitable for the study of phase transition of ε-, β-, and γ-CL-20 at high temperature and high pressure, while the accuracy of thermal expansion of β- and γ-CL-20 needs to be further improved.
KW - CL-20
KW - High temperature and pressure phase transfromation
KW - Modified valence angle potential energy
KW - ReaxFF-lg reactive force field
KW - Thermal expansion
UR - http://www.scopus.com/inward/record.url?scp=85105661983&partnerID=8YFLogxK
U2 - 10.11943/CJEM2020157
DO - 10.11943/CJEM2020157
M3 - 文章
AN - SCOPUS:85105661983
SN - 1006-9941
VL - 29
SP - 325
EP - 331
JO - Hanneng Cailiao/Chinese Journal of Energetic Materials
JF - Hanneng Cailiao/Chinese Journal of Energetic Materials
IS - 4
ER -