A Review of the Experimental Determination of the Melting Curve of Iron at Ultrahigh Pressures
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摘要: 铁是典型的d电子过渡金属之一,其在高压下的熔化行为对于揭示地核的成分、热结构和热演化至关重要。在实验室中创造极端高温高压条件以及诊断和测量凝聚介质的熔化行为和熔化温度比较困难,导致长期以来不同实验之间以及实验与理论之间获得的铁的高压熔化线存在较大争议。近年来,随着高压实验技术的发展,对铁高压熔化线的认识逐渐趋于一致。本文介绍了用于研究铁在高压下熔化行为和熔化温度的动、静高压实验技术,总结了高压下诊断铁和过渡金属熔化的方法及其优缺点,并分析了不同实验之间产生差异的原因。基于目前关于铁高压熔化温度的实验和理论研究结果,铁在内外核边界压力(约330 GPa)下的熔化温度可限定为5900~6300 K。系统总结铁在高压下的熔化行为对于进一步认识熔化的物理机制、研究其他过渡金属的高压熔化行为等具有重要的指导和借鉴意义。Abstract: Iron is one of the typical d-orbital transition metals. Its melting behavior and melting curve at high pressure are of great importance for revealing the composition, thermal structure, and thermal evolution of the Earth’s core. Creating the extreme high pressure-temperature conditions and measuring the melting temperatures of the condensed matters in the laboratory are quite challenging, resulting in a long-term controversy on the melting curves of iron at high pressures among various experiments and between experiments and theories. With the development of various experimental techniques, the results between experimental and theoretical studies are generally consistent with each other. This review presents the main static and dynamic compression techniques that have been used to study the high-pressure melting curve of iron in recent years; it also explores the advantages and disadvantages of melting diagnostics for iron and transition metals. The possible reasons for the discrepancy in the melting curves of iron are also discussed. Based on the experimental and theoretical results of the melting curve of iron, the melting temperature of iron can be anchored to 5900–6300 K at the pressure of the inner core boundary (ICB, about 330 GPa). Summarizing the current researches on the melting behaviors of iron under static and dynamic compression has an important implication for studying the melting curves of other transition metals, as well as the melting mechanism.
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Key words:
- iron /
- high-pressure melting /
- static compression /
- dynamic compression /
- Earth’s core temperature
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图 3 金刚石压腔静高压实验中一些典型的用于研究铁高压熔化的诊断方法与标准:(a) XRD[10],(b) SMS[151], (c) XAS[154],(d) 电阻率[155],(e) 激光功率与温度的关系[10]
Figure 3. Some typical diagnostic methods and criteria used to study the melting behavior of iron at high pressures in heated DAC experiments: (a) XRD[10], (b) SMS[151], (c) XAS[154], (d) resistivity[155], (e) relationship between laser power and temperature[10]
图 4 动高压实验中常用的冲击熔化诊断方法[40, 120, 156]:(a) 冲击压力与Hugoniot温度关系的不连续,(b) 沿着冲击绝热线声速的不连续,(c) 冲击下hcp结构的X射线衍射峰消失[120]
Figure 4. Typical diagnostics for the shock-induced melting in dynamic compression experiments[40, 120, 156]: (a) discontinuity of the relationship between shock pressure and Hugoniot temperature, (b) discontinuity of sound velocity along the Hugoniot, (c) the disappearance of XRD peak for hcp structure under shock loading[120]
图 5 铁高压熔化温度的典型静高压实验研究结果[10, 143-155](绿色、红色、蓝色和洋红色图例分别表示采用直接显微观察样品表面、XRD、SMS和XAS获得的LH-DAC静高压实验结果,橙色图例表示采用电阻率作为诊断方法获得的RH-DAC静高压实验结果)
Figure 5. Typical results of the melting temperatures of iron at high pressures using static compression experiments[10, 143-155] (The green, red, blue, and magenta legends represent the experimental results of LH-DAC experiments obtained by direct microscopic observation of sample surface, XRD, SMS, and XAS as diagnostic methods, respectively; the orange legends represent the experimental results of RH-DAC experiments using resistivity measurements as the diagnostic method.)
图 6 铁高压熔化温度的典型动高压实验研究结果[47, 119-120, 143, 157, 161, 163-164](实心图例表示采用多通道瞬态辐射高温计直接测得的铁的Hugoniot温度和熔化温度,其中绿色[143]、蓝色[157]和洋红色[119]图例代表使用微米厚铁膜或铁箔、4~6个波长通道的高温计测得的Hugoniot温度,红色图例[47]代表使用毫米厚块状铁、16个波长通道的高温计测得的Hugoniot温度;空心图例表示高功率激光加载动高压实验中采用XAS和XRD测得的铁的冲击熔化,通过热力学计算得到的Hugoniot温度)
Figure 6. Typical results of the melting temperatures of iron at high pressures by dynamic compression experiments[47, 119-120, 143, 157, 161, 163-164] (The solid legends show that Hugoniot temperatures and melting temperatures of iron are directly measured by a multichannel transient radiation pyrometer; the legends of green[143], blue[157] and magenta[119] represent the Hugoniot temperatures of iron measured by a pyrometer with 4–6 wavelength channels using iron film (foil) sample; the red legend[47] represent the Hugoniot temperatures of iron measured by a pyrometer with 16 wavelength channels using bulk iron sample; the open legends represent that the Hugoniot temperatures of iron are calculated through thermodynamic calculations from the shock melting measurements by XAS and XRD in the dynamic compression experiments of high power laser loading.)
图 7 铁高压熔化温度的典型动高压和静高压实验结果对比[10, 47, 120, 154-155, 163](动高压实验结果与静高压实验结果具有良好的一致性,尤其是采用XAS[154]和XRD[10]作为诊断技术的LH-DAC静高压实验和改进样品靶结构并采用多通道瞬态辐射高温计[47]的动高压实验结果之间)
Figure 7. A comparison of the typical results on the melting temperatures of iron at high pressures obtained by the static and dynamic compression experiments[10, 47, 120, 154–155, 163] (The results are generally consistent with each other between dynamic and static experiments. In particular, the results of LH-DAC static experiments using XAS[154] and XRD[10] as diagnostic techniques are in good agreement with those of dynamic experiments using improved pyrometry[47].)
图 8 铁高压熔化温度的理论模拟和热力学计算结果[129-142](理论研究主要包括两类:基于分子动力学或第一性原理的理论模拟以及基于热力学状态参数的热力学计算)
Figure 8. Melting temperatures of iron at high pressures using theoretical simulations and thermodynamic calculations[129-142] (Theoretical studies mainly include two categories: simulations based on molecular dynamics or first-principles and thermodynamic calculations based on thermodynamic parameters.)
图 9 铁高压熔化线的典型研究结果[10, 47, 119, 129-135, 138-139, 141, 143, 145-146, 155, 157](20年前铁高压熔化线的实验与理论研究结果之间存在较大的差异,而目前实验与理论研究结果之间已经基本吻合)
Figure 9. Typical results of the melting curves of iron at high pressures[10, 47, 119, 129-135, 138-139, 141, 143, 145-146, 155, 157] (Twenty years ago, there was a big difference in the melting curves of iron between experimental and theoretical studies, while the current studies show an overall agreement between experimental and theoretical results.)
表 1 高压下铁的熔化温度的实验和理论研究总结
Table 1. Summary of experimental and theoretical studies on the melting temperature of iron at high pressures
Technique Method Melting diagnostic Expt. and theo. conditions TM, ICB/K Reference, year p/GPa TM(TH)/K Theory Ab initio DFT Free energies 50–350 3020–6860 6680±600 Ref.[129], 1999 Thermodynamics Database 0–330 1811–5790 5790 Ref.[130], 2000 AIMD Free energies 60–330 2460–7100 7100 Ref.[131], 2000 FP-MD A single potential 100–330 2830–5400 5400±400 Ref.[132], 2000 Ab initio DFT Free energies 50–350 2550–6380a 6210±600a Ref.[133], 2002 Ab initio DFT Free energies 50–350 2890–6510b 6350±600b Ref.[133], 2002 Thermodynamics Free energy 58–462 2840–7240 6050 Ref.[134], 2003 FP Number of atoms 323–332 6270–6440 6370±100 Ref.[135], 2009 Monte Carlo Free energies 330 6900 6900±400 Ref.[136], 2009 Thermodynamics Database 0–353 1810–5080 4900 Ref.[137], 2010 AIMD Free energies 190–1500 4500–12500 6150 Ref.[138], 2013 AIMD Structure 0–365 1700–6740 6350 Ref.[139], 2015 Thermodynamics Database 107–350 3790–6020 5880 Ref.[140], 2017 AIMD Free energies 330 6170 6170±200 Ref.[141], 2018 SMM LC 0–350 1810–5720 5570 Ref.[142], 2021 Static LH-DAC(s) Textural 0–102 1750–4180 7600±500 Ref.[143], 1987 Motion 16–197 2220–3860 4850±200 Ref.[144-145], 1993 Visual bservation 0–144 1811–3530 6130±350 Ref.[146], 1994 XRD 11–80 2100–3090 Ref.[147-148], 2004 XRD 60–105 2750–3510 5800±200 Ref.[149], 2004 XRD 27–130 2580–3180 Ref.[150], 2008 SMS 20–82 2220–3030 Ref.[151], 2013 Fast XRD 57–158 3140–4470 6230±500 Ref.[10], 2013 XANES 75–117 2840–3090 Ref.[152], 2015 SMS 19–60 2120–2800 5700±200 Ref.[153], 2016 XANES 43–133 2660–4700 Ref.[154], 2018 RH-DAC Resistivity 6–290 1900–5360 5500±220 Ref.[155], 2019 Dynamic
(shock wave)TSLGG SVD 40–400 655–10024c 5800±500 Ref.[156], 1986 TSLGG T-p discontinuity 202–301 5500–9370* 7600±500 Ref.[143], 1987 TSLGG T-p discontinuity 203–300 5200–8990* 7800±500 Ref.[157], 1987 TSLGG T-p discontinuity 159–339 4460–8360* 6830±500 Ref.[119], 1993 TSLGG SVD 84–171 4380–5440e* 6000 Ref.[158-159], 2001 PG SVD 14–73 1820–2780f 5300±400 Ref.[160], 2002 TSLGG SVD 225–260 5100–6100d 6350±500 Ref.[40], 2004 HP laser SED 50–150 4000–5000# 7800±1200 Ref.[41], 2005 HP laser EXAFS 90–560 1320–8160# 6400 Ref.[161], 2013 TSLGG SVD 73–127 3240–3680e 5885±500 Ref.[162], 2009 HP laser XANES 260–420 5680–10800# Ref.[163], 2015 HP laser EXAFS 40–500 660–17000# Ref.[164], 2016 HP laser XRD 144–273 3100–5560# 6400 Ref.[120], 2020 TSLGG SVD 120–256 4250–5500* 5950±500 Ref.[47], 2020 Note: Superscript lowercase letters “a” and “b” represent the theoretical results of ab initio molecular dynamics simulation
without and with free-energy correction, respectively; “c” and “d” represent that the Hugoniot temperatures were calculated
based on the measurements of sound velocities of iron and preheated iron, respectively; “e” represents the porous iron was
used in shock compression experiments; “*” represents that the Hugoniot temperatures were measured by a multi-channel
quasi-spectral optical pyrometer; “#” represents that the Hugoniot temperatures were calculated through thermodynamic
calculations based on the results of dynamic compression experiments of high power laser loading.
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