氧化镁和铼压标不确定度量化研究:基于贝叶斯统计方法OA
Quantification of Uncertainty in Magnesium Oxide and Rhenium Pressure Standards Based on Bayesian Statistical Methods
静高压实验中精确的压力测量依赖于标准材料的物态方程,而物态方程参数的不确定度会显著影响压力预测的准确性.以氧化镁(MgO,B1 相)和铼(Re,密排六方相)为研究对象,采用贝叶斯统计方法与马尔可夫链蒙特卡罗模拟技术,系统量化了其在金刚石对顶砧实验中的压力预测不确定度.通过均匀分布先验和正态似然函数构建贝叶斯框架,整合了多组实验数据进行参数校准.结果表明,贝叶斯统计方法成功量化了物态方程参数的后验分布,并揭示了参数间的强相关性,如 MgO的 Grüneisen参数与初始体积呈负相关,Re的体模量与Grüneisen参数呈正相关.MgO和Re的压力预测不确定度随着压力升高而显著增大;Re的压力预测不确定度随温度升高而显著增大,MgO则没有明显规律.研究结果为提升高压实验压力测量精度提供了具有不确定度的压标,可为提升材料科学和地球物理研究中的实验数据可靠性提供重要参考.
Accurate pressure measurement in static high-pressure experiments relies on the equation of state(EOS)of standard materials,where uncertainties in EOS parameters can significantly affect the accuracy of pressure predictions.This study focuses on magnesium oxide(MgO,B1 phase)and rhenium(Re,hexagonal close packed phase),employing Bayesian statistical methods and Markov Chain Monte Carlo(MCMC)simulation techniques to systematically quantify the uncertainty in pressure prediction during diamond anvil cell(DAC)experiments.By constructing a Bayesian framework with uniform prior distributions and normal likelihood functions,and integrating multiple sets of experimental data for parameter calibration,the results demonstrate that the Bayesian statistical approach successfully quantifies the posterior distribution of EOS parameters,revealing strong correlations between them,e.g.,a negative correlation between Grüneisen parameter and initial volume for MgO,and a positive correlation between bulk modulus and Grüneisen parameter for Re.The uncertainty in pressure predictions for both MgO and Re increases significantly at higher pressures;for Re,this uncertainty also rises markedly with increasing temperature,whereas no clear trend is observed for MgO.This study provides pressure benchmarks with quantified uncertainties,contributing to improved accuracy in high-pressure experimental measurements.It holds significant reference value for ensuring the reliability of experimental data in materials science and geophysical research.
DAI Feifan;XIANG Shikai;LI Weiwei;ZHANG Ruizhi;ZHANG Jian;LUO Guoqiang;WU Run;XIAN Yunting
State Key Laboratory of Advanced Technology for Materials Synthesis and Processing,Wuhan University of Technology,Wuhan 430070,Hubei,China||Institute of Fluid Physics,China Academy of Engineering Physics,Mianyang 621999,Sichuan,ChinaInstitute of Fluid Physics,China Academy of Engineering Physics,Mianyang 621999,Sichuan,ChinaState Key Laboratory of Advanced Technology for Materials Synthesis and Processing,Wuhan University of Technology,Wuhan 430070,Hubei,ChinaState Key Laboratory of Advanced Technology for Materials Synthesis and Processing,Wuhan University of Technology,Wuhan 430070,Hubei,ChinaState Key Laboratory of Advanced Technology for Materials Synthesis and Processing,Wuhan University of Technology,Wuhan 430070,Hubei,ChinaState Key Laboratory of Advanced Technology for Materials Synthesis and Processing,Wuhan University of Technology,Wuhan 430070,Hubei,ChinaInstitute of Fluid Physics,China Academy of Engineering Physics,Mianyang 621999,Sichuan,ChinaInstitute of Fluid Physics,China Academy of Engineering Physics,Mianyang 621999,Sichuan,China
数理科学
贝叶斯统计方法马尔科夫链蒙特卡罗物态方程不确定度量化
Bayesian statistical methodMarkov Chain Monte Carloequation of stateuncertainty quantification
《高压物理学报》 2026 (1)
133-145,13
国家重点研发计划(2021YFB3802300)国家自然科学基金(12372370)
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