Souvatzis P, Eriksson O, Katsnelson M I, Rudin S P
Department of Physics, Uppsala University, Box 530, SE-75121, Uppsala, Sweden.
Phys Rev Lett. 2008 Mar 7;100(9):095901. doi: 10.1103/PhysRevLett.100.095901. Epub 2008 Mar 5.
Conventional methods to calculate the thermodynamics of crystals evaluate the harmonic phonon spectra and therefore do not work in frequent and important situations where the crystal structure is unstable in the harmonic approximation, such as the body-centered cubic (bcc) crystal structure when it appears as a high-temperature phase of many metals. A method for calculating temperature dependent phonon spectra self-consistently from first principles has been developed to address this issue. The method combines concepts from Born's interatomic self-consistent phonon approach with first principles calculations of accurate interatomic forces in a supercell. The method has been tested on the high-temperature bcc phase of Ti, Zr, and Hf, as representative examples, and is found to reproduce the observed high-temperature phonon frequencies with good accuracy.
计算晶体热力学的传统方法评估的是简谐声子谱,因此在晶体结构在简谐近似下不稳定的常见且重要的情形中并不适用,比如体心立方(bcc)晶体结构作为许多金属的高温相出现时。为了解决这个问题,已经开发出一种从第一性原理自洽计算温度相关声子谱的方法。该方法将玻恩的原子间自洽声子方法中的概念与超胞中精确原子间力的第一性原理计算相结合。已将该方法应用于Ti、Zr和Hf的高温bcc相作为代表性实例进行测试,发现其能以良好的精度再现观测到的高温声子频率。