Pressure-driven crystal structure evolution in RbB2C4 compounds

doi:10.1088/1674-1056/adb271

中国物理B ›› 2025, Vol. 34 ›› Issue (4): 46201-046201.doi: 10.1088/1674-1056/adb271

所属专题： SPECIAL TOPIC — Structures and properties of materials under high pressure

Pressure-driven crystal structure evolution in RbB₂C₄ compounds

Jinyu Liu(刘金禹)¹, Ailing Liu(刘爱玲)¹, Yujia Wang(王雨佳)¹, Lili Gao(高丽丽)¹, Xiangyi Luo(罗香怡)^2,†, and Miao Zhang(张淼)^1,‡

1 Department of Physics, School of Sciences, Beihua University, Jilin 132013, China;
2 College of Physics and Electronic Information, Baicheng Normal University, Baicheng 137000, China

收稿日期:2025-01-02 修回日期:2025-01-28 接受日期:2025-02-05 出版日期:2025-04-15 发布日期:2025-04-15
通讯作者: Xiangyi Luo, Miao Zhang E-mail:luoxylgq@163.com;zhangmiaolmc@126.com
基金资助:
Project supported by the Jilin Provincial Science and Technology Development Joint Fund Project (Grant No. YDZJ202201ZYTS581). This work is also supported by the Scientific and Technological Research Project of Jilin Provincial Education Department (Grant No. JJKH20240077KJ).

Pressure-driven crystal structure evolution in RbB₂C₄ compounds

Jinyu Liu(刘金禹)¹, Ailing Liu(刘爱玲)¹, Yujia Wang(王雨佳)¹, Lili Gao(高丽丽)¹, Xiangyi Luo(罗香怡)^2,†, and Miao Zhang(张淼)^1,‡

1 Department of Physics, School of Sciences, Beihua University, Jilin 132013, China;
2 College of Physics and Electronic Information, Baicheng Normal University, Baicheng 137000, China

Received:2025-01-02 Revised:2025-01-28 Accepted:2025-02-05 Online:2025-04-15 Published:2025-04-15
Contact: Xiangyi Luo, Miao Zhang E-mail:luoxylgq@163.com;zhangmiaolmc@126.com
Supported by:
Project supported by the Jilin Provincial Science and Technology Development Joint Fund Project (Grant No. YDZJ202201ZYTS581). This work is also supported by the Scientific and Technological Research Project of Jilin Provincial Education Department (Grant No. JJKH20240077KJ).

摘要/Abstract

摘要： As an extreme physical condition, high pressure serves as a potent means to substantially modify the interatomic distances and bonding patterns within condensed matter, thereby enabling the macroscopic manipulation of material properties. We employed the CALYPSO method to predict the stable structures of RbB$_{2}$C$_{4}$ across the pressure range from 0 GPa to 100 GPa and investigated its physical properties through first-principles calculations. Specially, we found four novel structures, namely, $P$6$_{3}$/mcm-, Amm2-, $P$1-, and $I$4/mmm-RbB$_{2}$C$_{4}$. Under pressure conditions, electronic structure calculations reveal that all of them exhibit metallic characteristics. The calculation results of formation enthalpy show that the $P$6$_{3}$/mcm structure can be synthesized within the pressure range of 0-40 GPa. Specially, the Amm2, $P1$, and $I$4/mmm structures can be synthesized above 4 GPa, 6 GPa, 10 GPa, respectively. Moreover, the estimated Vickers hardness value of $I$4/mmm-RbB$_{2}$C$_{4}$ compound is 47 GPa, suggesting that it is a superhard material. Interestingly, this study uncovers the continuous transformation of the crystal structure of RbB$_{2}$C$_{4}$ from a layered configuration to folded and tubular forms, ultimately attaining a stabilized cage-like structure under the pressure span of 0-100 GPa. The application of pressure offers a formidable impetus for the advancement and innovation in condensed matter physics, facilitating the exploration of novel states and functions of matter.

关键词: first-principles calculation, high pressure, RbB$_{2}$C$_{4}$ compounds, crystal structure prediction

Abstract: As an extreme physical condition, high pressure serves as a potent means to substantially modify the interatomic distances and bonding patterns within condensed matter, thereby enabling the macroscopic manipulation of material properties. We employed the CALYPSO method to predict the stable structures of RbB$_{2}$C$_{4}$ across the pressure range from 0 GPa to 100 GPa and investigated its physical properties through first-principles calculations. Specially, we found four novel structures, namely, $P$6$_{3}$/mcm-, Amm2-, $P$1-, and $I$4/mmm-RbB$_{2}$C$_{4}$. Under pressure conditions, electronic structure calculations reveal that all of them exhibit metallic characteristics. The calculation results of formation enthalpy show that the $P$6$_{3}$/mcm structure can be synthesized within the pressure range of 0-40 GPa. Specially, the Amm2, $P1$, and $I$4/mmm structures can be synthesized above 4 GPa, 6 GPa, 10 GPa, respectively. Moreover, the estimated Vickers hardness value of $I$4/mmm-RbB$_{2}$C$_{4}$ compound is 47 GPa, suggesting that it is a superhard material. Interestingly, this study uncovers the continuous transformation of the crystal structure of RbB$_{2}$C$_{4}$ from a layered configuration to folded and tubular forms, ultimately attaining a stabilized cage-like structure under the pressure span of 0-100 GPa. The application of pressure offers a formidable impetus for the advancement and innovation in condensed matter physics, facilitating the exploration of novel states and functions of matter.

Key words: first-principles calculation, high pressure, RbB$_{2}$C$_{4}$ compounds, crystal structure prediction

中图分类号: (High-pressure effects in solids and liquids)

62.50.-p

74.62.Bf (Effects of material synthesis, crystal structure, and chemical composition) 63.20.dk (First-principles theory)

Jinyu Liu(刘金禹), Ailing Liu(刘爱玲), Yujia Wang(王雨佳), Lili Gao(高丽丽), Xiangyi Luo(罗香怡), and Miao Zhang(张淼). Pressure-driven crystal structure evolution in RbB₂C₄ compounds[J]. 中国物理B, 2025, 34(4): 46201-046201.

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Pressure-driven crystal structure evolution in RbB₂C₄ compounds

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