Equations of state of iron and nickel to the pressure at the center of the Earth

Table 1. Conditions of each experimental run.

Run No.	Diamond anvil geometry^a (μm)	PTM^b	Scale	P range (GPa)
Fe 1	500	He	Pt + ruby	5–20
Fe 2	350	He	Ruby	0–54
Fe 3	35/250/350	None	Pt	0–296
Fe 4	28/250/350	None	Pt	219–354
Ni 1	500	MEW^c	Ruby	0–10
Ni 2	500	He	Pt	0–21
Ni 3	100/300	None	Pt	2–179
Ni 4	27/250/450	None	Pt	257–368
Ni 5	50/230/450	None	Pt	163–202

Two runs in the lower pressure range were performed under hydrostatic or quasi-hydrostatic conditions using a pressure-transmitting medium (PTM). The pressure was determined using a revised ruby scale derived from Dewaele’s ruby scale27 by correcting the pressure difference between the Pt-EOSs of Fratanduono et al.19 and Dewaele et al.27 (see Fig. S1 in the supplementary material). The other experimental runs in the high-pressure range were performed under nonhydrostatic conditions, without any PTM. The single and second bevel angles were 8.5° and 15°, respectively. The latest Pt-EOS19 was used to determine the pressure. The pressure uncertainty was estimated to be within ±1% from the error of the lattice constant of Pt. In applying the latest Pt-EOS scale, the Au- and Pt-EOS scales were crosschecked up to 150 GPa using our previous x-ray diffraction data,28 and the consistency between both EOS scales was confirmed (see Fig. S2 in the supplementary material).

III. RESULTS AND DISCUSSION

A. Iron

We observed that Fe underwent a phase transition from the body-centered cubic (bcc-Fe, or α-Fe) phase to the hexagonal close-packed (hcp-Fe, or ε-Fe) phase at ∼15 GPa under quasi-hydrostatic pressure at room temperature, which is in good agreement with the results of a previous study.29 In the present study, it was clarified that the hcp-Fe phase remained stable up to a maximum pressure of 354 GPa at 298 K, as shown in Fig. 1 (the observed diffraction image is shown in Fig. S3 in the supplementary material). Table II lists the d-values of the hcp-Fe and fcc-Pt diffraction lines observed at the highest pressure. Seven diffraction lines were identified for hcp-Fe, from which the lattice constants a, c, and c/a were estimated to be 2.1294(17) Å, 3.390(5) Å, and 1.592(4), respectively. For the hcp-Fe phase, 165 patterns were collected in the pressure range of 14–354 GPa in the four experimental runs.

$Representative x-ray diffraction pattern (red crosses) and Rietveld simulation (green line) for hcp-Fe at 354 GPa. The blue line shows a residual. Lattice constants are calculated to be a = 2.1294(17) Å and c = 3.390(5) Å for hcp-Fe and a = 3.4049(11) Å for fcc-Pt.$

Figure 1.Representative x-ray diffraction pattern (red crosses) and Rietveld simulation (green line) for hcp-Fe at 354 GPa. The blue line shows a residual. Lattice constants are calculated to be a = 2.1294(17) Å and c = 3.390(5) Å for hcp-Fe and a = 3.4049(11) Å for fcc-Pt.

Table 2. 2θ and d-values (d_o) of the observed diffraction lines with λ = 0.4176 Å for the pattern at 354 GPa, indices for these lines, and calculated d-values (d_c) for the hcp-Fe and fcc-Pt phases. Calculated lattice constants are also listed.

Table 2. 2θ and d-values (d_o) of the observed diffraction lines with λ = 0.4176 Å for the pattern at 354 GPa, indices for these lines, and calculated d-values (d_c) for the hcp-Fe and fcc-Pt phases. Calculated lattice constants are also listed.

2θ (deg)	d_o (Å)	hcp-Fe			fcc-Pt
		a = 2.1294(17) (Å)			a = 3.4049(11) (Å)
		c = 3.390(5) (Å)
		Index	d_c (Å)	d_o − d_c (Å)	Index	d_c (Å)	d_o − d_c (Å)
12.193	1.9661				111	1.9658	0.0003
12.970	1.8487	010	1.8441	0.0046
14.090	1.7024	(002)			200	1.7025	−0.0001
14.833	1.6176	011	1.6200	−0.0024
19.290	1.2463	012	1.2480	−0.0017
20.004	1.2022				220	1.2038	−0.0016
22.639	1.0638	110	1.0647	−0.0009
23.451	1.0275				311	1.0266	0.0008
24.518	0.9834				222	0.9829	0.0005
25.003	0.9646	013	0.9636	0.0010
26.808	0.9007	112	0.9016	−0.0009
27.113	0.8908	021	0.8897	0.0010
28.406	0.8510				400	0.8512	−0.0002

Figure 2 shows the compression curve of hcp-Fe obtained from the pressure–volume (P–V) data at 298 K, together with the results of previous studies (P–V data for hcp-Fe are listed in Table SI in the supplementary material). The P–V data for hcp-Fe were fitted to the Vinet equation.30 This fit took the form $P (x) = 3 K_{0} (1 - x^{1 / 3}) x^{- 2 / 3} \exp [\frac{3}{2} (K_{0}^{'} - 1) (1 - x^{1 / 3})],$ (1)where x = V/V₀, V₀ is the ambient atomic volume of hcp-Fe, and K₀ and $K_{0}^{'}$ are the bulk modulus at ambient pressure and its derivative with respect to pressure. We obtained K₀ = 159.27(99) GPa and $K_{0}^{'}$ = 5.86(4) with a fixed V₀ of 11.215(29) Å³, which are listed in Table III, along with existing data. The numbers in parentheses for K₀ and $K_{0}^{'}$ represent the estimated standard deviation (e.s.d.) of the error. There are negative and strong correlations between the EOS fitting parameters K₀ and $K_{0}^{'}$ , leading to a strong trade-off between elastic parameters.31 This indicates that increasing the value of K₀ shifts $K_{0}^{'}$ toward lower values, and vice versa, as shown in Fig. S5 of the supplementary material. The V₀ of the high-pressure phase is normally unknown. In this analysis, assuming the appropriate value of V₀, both K₀ and $K_{0}^{'}$ were estimated by the least-squares method. The standard deviation of the observed value of the volume V_obs(P) for the obtained EOS curve was estimated for V₀. The value of V₀ was then varied to find the optimal V₀ that minimized this standard deviation. The minimum standard deviation is shown as an error of V₀.

Figure 2.Compression curve of Fe up to a pressure of 354 GPa, together with curves from previous reports. Solid black, green, blue, and red curves correspond to the experimental results of the present study and those conducted by Mao et al.,³ Dubrovinsky et al.,⁴ and Dewaele et al.,⁵ respectively. ΔV_a denotes the deviations of the atomic volume for each previous curve from the present one.

Table 3. Parameters of the Vinet EOS obtained by a least-squares fit of the experimental compression data for hcp-Fe, together with those from previous reports. The parameters of these EOSs are the atomic volume V₀, bulk modulus K₀, and its pressure derivative $K_{0}^{'}$ under ambient conditions.

Table 3. Parameters of the Vinet EOS obtained by a least-squares fit of the experimental compression data for hcp-Fe, together with those from previous reports. The parameters of these EOSs are the atomic volume V₀, bulk modulus K₀, and its pressure derivative $K_{0}^{'}$ under ambient conditions.

V₀ (Å³)	K₀ (GPa)	$K_{0}^{'}$	P Range (GPa)	P Gauge	Formula	PTM	References
11.215(29)	159.27(99)	5.86(4)	14–354	Ruby or Pt	Vinet	He or none	Present
11.176(17)	164.8(3.6)	5.33(9)	35–300	Pt	B-M^a	Ar or none	Mao et al.³
11.1780(2)	160.67(5)	5.36(1)			B-M		Corrected EOS
11.1989	156	5.81	20–200	Pt	B-M	None (heating)	Dubrovinsky et al.⁴
11.2022(1)	151.65(2)	5.854(3)			B-M		Corrected EOS
11.214(49)	163.4(7.9)	5.38(16)	17–197	Ruby or W	Vinet	He	Dewaele et al.⁵
11.214	156.7(9)	5.8(1.0)			Vinet		Corrected EOS

To compare the present and previously reported EOS curves, we extrapolated the previous EOS curves to 365 GPa. Furthermore, the pressures on the EOS curves of Mao et al.,3 Dubrovinsky et al.,4 and Dewaele et al.5 were corrected based on the latest Pt scale.14 The Pt-EOS curve reported by Dewaele et al.,5 which was determined based on the ruby scale proposed by Dewaele et al.,27 indicates a pressure lower by ∼25 GPa at 365 GPa on the latest Pt-EOS pressure scale. Therefore, their EOS curve for hcp-Fe before correction is below our EOS curve. The deviation of their atomic volume from the present EOS curve, ΔV_a, at 365 GPa was −0.15 Å³. In other words, their EOS curve underestimates the volume by 2.3% at 365 GPa compared with our EOS curve. When the pressure value is corrected, ΔV_a of the previous studies is within ±0.05 Å³, i.e., ±0.7% at 365 GPa. Therefore, it could be considered that this significant deviation of the EOS curve of Dewaele et al.5 is due to the pressure scale.

B. Nickel

At ambient pressure, the 3d transition metal Ni has a face-centered cubic (fcc) structure and does not show any structural phase transition up to 368 GPa, revealing that the fcc structure is stable up to the maximum pressure investigated in this study. In the diffraction pattern of 368 GPa shown in Fig. 3 (the diffraction image is shown in Fig. S3 in the supplementary material), six diffraction lines were observed for fcc-Ni, and eight diffraction lines were identified for Pt. From the Rietveld analysis32 of this pattern, the lattice constant a of fcc-Ni was estimated to be 2.9521(10) Å, and the volume compression ratio V/V₀ was 0.5880. The diffraction angles 2θ and d-values of each diffraction line are listed in Table IV.

$Representative x-ray diffraction pattern (red crosses) and Rietveld simulation (blue line) for Ni at 368 GPa. The green line shows a residual. The estimated lattice constants a for fcc-Ni and fcc-Pt are 2.9521(10) and 3.3977(6) Å, respectively.$

Figure 3.Representative x-ray diffraction pattern (red crosses) and Rietveld simulation (blue line) for Ni at 368 GPa. The green line shows a residual. The estimated lattice constants a for fcc-Ni and fcc-Pt are 2.9521(10) and 3.3977(6) Å, respectively.

Table 4. 2θ and d-values (d_o) of the observed diffraction lines with λ = 0.4134 Å for the pattern at 368 GPa and indices for these lines and calculated d-values (d_c) for the fcc-Ni and fcc-Pt phases. Calculated lattice constants are also listed.

Table 4. 2θ and d-values (d_o) of the observed diffraction lines with λ = 0.4134 Å for the pattern at 368 GPa and indices for these lines and calculated d-values (d_c) for the fcc-Ni and fcc-Pt phases. Calculated lattice constants are also listed.

2θ (deg)	d_o (Å)	fcc-Ni			fcc-Pt
		a = 2.9521(10) (Å)			a = 3.3977(6) (Å)
		Index	d_c (Å)	d_o − d_c (Å)	Index	d_c (Å)	d_o − d_c (Å)
12.048	1.9614				111	1.9616	−0.0001
13.856	1.7065	111	1.7053	0.0011	(200)
16.008	1.4783	200	1.4769	0.0015
19.722	1.2020				220	1.2012	0.0008
22.757	1.0434	220	1.0443	−0.0008
23.186	1.0243				311	1.0244	−0.0001
24.244	0.9803				222	0.9808	−0.0005
26.746	0.8900	311	0.8906	−0.0005
27.969	0.8518	222	0.8527	−0.0004	(400)
30.613	0.7798				331	0.7794	0.0003
31.446	0.7596				420	0.7597	−0.0001
32.359	0.7387	400	0.7384	0.0001

Figure 4 shows the pressure dependence of the atomic volume V_a for fcc-Ni at 298 K obtained from five separate experimental runs, together with existing data.6,14 The present P–V data for Ni (Table SII in the supplementary material) were also fitted to the Vinet equation.30 With a fixed ambient atomic volume V₀ of 10.9376(4) Å³, K₀ and $K_{0}^{'}$ were estimated to be 173.5(1.4) GPa and 5.55(5), respectively. These values are listed in Table V, along with the existing data.

Figure 4.Compression curve of Ni up to a pressure of 368 GPa, together with curves from previous reports. Solid black, green, and red curves are Vinet EOS fits to the experimental data from the present study, Kennedy and Keeler,¹⁴ and Dewaele et al.,⁶ respectively.

Table 5. Parameters of the Vinet EOS obtained by a least-squares fit of the experimental compression data for Ni, together with those from previous reports. The parameters of these EOSs are the atomic volume V₀, bulk modulus K₀, and its pressure derivative $K_{0}^{'}$ , under ambient conditions.

Table 5. Parameters of the Vinet EOS obtained by a least-squares fit of the experimental compression data for Ni, together with those from previous reports. The parameters of these EOSs are the atomic volume V₀, bulk modulus K₀, and its pressure derivative $K_{0}^{'}$ , under ambient conditions.

V₀ (Å³)	K₀ (GPa)	$K_{0}^{'}$	Method	P Range (GPa)	Formula	References
10.9376(4)	173.5(1.4)	5.55(5)	DAC	0–368	Vinet	Present
⋯	183(3)	⋯	Ultrasonic	⋯	⋯	Yamamoto¹⁵
10.940	176.7(2.5)	5.23(9)	DAC	0–156	Vinet	Dewaele et al.⁶
10.940	169.3(8)	5.67(18)			Vinet	Corrected EOS
10.9376	187.8(5)	4.89(4)	Shock wave	0–120	Vinet	Kennedy and Keeler¹⁴

By comparing the present data and the extrapolated curve from the previous report by Dewaele et al.,6 the latter underestimated the volume by ∼1.5% (ΔV_a = −0.097 Å³) above 365 GPa. This discrepancy can also be attributed to the difference in the pressure scale. Dewaele et al.6 used their own calibrated ruby scale.27 Comparing the Pt-EOS27 obtained using this ruby scale with the latest Pt-EOS19 used in this study (see Fig. S1 in the supplementary material), their Pt-EOS27 scale was underestimated by ∼25 GPa at 365 GPa. It is found that our Ni compression curve shows perfect agreement with the compression curve (the red dashed line in Fig. 4), which was obtained by correcting this pressure difference.

A sample compressed between two anvils without any PTM is generally under nonhydrostatic stress conditions. We examined the presence of nonhydrostatic stress using the diffraction data for fcc-Pt at 354 GPa and for fcc-Pt and fcc-Ni at 368 GPa, listed in Tables II and IV, respectively. The stress state in the diamond anvil sample possesses axial symmetry and can be defined by its components σ₃ and σ₁ in the axial and radial directions, respectively.33 The equivalent hydrostatic pressure and uniaxial stress component are given by σ_P = (σ₃ + 2σ₁)/3 and t = σ₃ − σ₁ ≤ σ_Y = 2τ, respectively, where σ_Y is the yield stress and τ is the shear strength of the sample material at σ_P.

For a cubic system,34 the a_m(hkl) vs 3(1–3 sin² θ) Γ(hkl) plot (gamma plot) for the data obtained in the conventional (parallel) geometry can be approximated by a straight line with slope M₁ and intercept M₀, where $Γ (h k l) = (h^{2} k^{2} + k^{2} l^{2} + l^{2} h^{2}) / {(h^{2} + k^{2} + l^{2})}^{2}$ . A very good estimate of αtS can be obtained from the relation $α t S \approx - 3 M_{1} / M_{0},$ (2)where S = S₁₁ − S₁₂ − S₄₄/2. The parameter α describes the continuity of stress and strain across grain boundaries of the sample and takes a value between 1 and 0. In the following discussion, we assume α = 1, which gives the lower bound for t. Because the values of the elastic compliance S at high pressure for Pt and Ni could be estimated using theoretically calculated data,35,36 the gamma plots for the fcc-Pt data at 354 and 368 GPa and for the fcc-Ni data at 368 GPa were constructed (see Fig. 5), and the t value was determined using Eq. (2). The obtained t-values for fcc-Pt at 354 and 368 GPa were −0.12 and 0.47, respectively, and the t-value for fcc-Ni at 368 GPa was 0.91 GPa. These values were within the uncertainty of pressure, suggesting that the uniaxial stress effect is negligible.

Figure 5.Gamma plots constructed using (a) the fcc-Pt data at 354 GPa from Table II, (b) the fcc-Pt data at 368 GPa from Table IV, and (c) the fcc-Ni data at 368 GPa from Table IV.

C. Geophysical implication

Figure 6 shows the room-temperature densities of hcp-Fe and fcc-Ni as functions of pressure in the Earth’s core, compared with the density profile of the core from the seismic Preliminary Reference Earth Model (PREM).37 The new experimental compression data are essential because density data at the range of pressures in the Earth’s inner core can then be directly constrained without the need to extrapolate the data to inner core conditions. From the new EOSs based on our compression data at room temperature, the densities of hcp-Fe and fcc-Ni at 365 GPa are 14.10(5) and 15.16(7) g/cm³, respectively, and the densities at the pressure of the inner core boundary (ICB), 329 GPa, are 13.78(5) and 14.81(7) g/cm³, respectively. The density of hcp-Fe at the ICB pressure obtained from our data is in excellent agreement with the density, 13.8(1) g/cm³, from the previous compression EOS reported by Mao et al.3 using Pt as an internal pressure standard.

Figure 6.Densities of Fe, Ni, and Fe_0.91Ni_0.09 at 298 K as functions of pressure. The Preliminary Reference Earth Model (PREM)³⁷ is also shown for comparison.