Crystallization of silicon dioxide and compositional evolution of the Earth’s core
At a Glance
Section titled “At a Glance”| Metadata | Details |
|---|---|
| Publication Date | 2017-02-21 |
| Journal | Nature |
| Authors | Kei Hirose, G. Morard, Ryosuke Sinmyo, Koichiro Umemoto, J. W. Hernlund |
| Institutions | Sorbonne Université, Centre National de la Recherche Scientifique |
| Citations | 227 |
| Analysis | Full AI Review Included |
Technical Documentation & Analysis: MPCVD Diamond for Extreme Geophysics
Section titled “Technical Documentation & Analysis: MPCVD Diamond for Extreme Geophysics”Executive Summary
Section titled “Executive Summary”This research utilizes Laser-Heated Diamond Anvil Cells (LH-DAC) to simulate the extreme pressure and temperature conditions of the Earth’s core, demonstrating the crystallization behavior of silicon dioxide (SiO₂) from liquid iron alloys. This work highlights the critical role of high-quality Single Crystal Diamond (SCD) in advancing high-pressure geophysics.
- Core Achievement: Demonstrated that liquid Fe-Si-O alloy crystallizes solid SiO₂ at uppermost core pressures (133-194 GPa) and temperatures (up to 4,560 K).
- Geophysical Impact: The wide liquidus field of SiO₂ suggests that the early Earth’s core crystallized SiO₂, releasing sufficient compositional buoyancy to power the geodynamo from the Hadean eon.
- Methodology: Experiments relied on high-strength diamond anvils (90 µm to 300 µm culets) combined with spectro-radiometric laser heating and advanced electron microscopy (FE-EPMA, EDX).
- Material Requirement: The success of the LH-DAC technique hinges on the mechanical integrity and optical purity of the diamond anvils used to contain the sample under multi-megabar pressures.
- 6CCVD Value Proposition: 6CCVD provides the necessary Optical Grade SCD materials, custom-fabricated to precise culet dimensions and ultra-low surface roughness (Ra < 1 nm), essential for reliable, high-fidelity HPHT research.
Technical Specifications
Section titled “Technical Specifications”The following hard data points were extracted from the experimental results and methodology sections, demonstrating the extreme conditions required for this research:
| Parameter | Value | Unit | Context |
|---|---|---|---|
| Maximum Pressure Achieved | 194 | GPa | Run 5 (Highest pressure experiment) |
| Maximum Temperature Achieved | 4,560 | K | Run 5 (Highest temperature experiment) |
| Typical Liquid/Solid Boundary T | 3,860 - 3,990 | K | Estimated temperature at 142-145 GPa |
| Diamond Anvil Culet Sizes Used | 90, 120, 300 | µm | Required for generating core pressures |
| Heating Duration | 3 - 5 | s | Limited duration to avoid complex melting textures |
| Laser Spot Diameter | ~20 | µm | Area of flat energy distribution for heating |
| Starting Material Thickness | 5 - 8 | µm | Fe-Si-O alloy coating thickness |
| Starting Material Grain Size | < 5 | nm | Ultrafine-grained metal and oxide homogeneity |
| Pressure Uncertainty | ±10 | % | Overall experimental pressure error |
| Temperature Uncertainty | ±3 | % | Spectro-radiometric temperature error |
Key Methodologies
Section titled “Key Methodologies”The experiment successfully simulated core conditions using a highly controlled, multi-stage process centered on the Laser-Heated Diamond Anvil Cell (LH-DAC):
- Starting Material Synthesis: Fe-Si-O alloys (5-8 µm thickness) were synthesized via magnetron cathodic sputtering in reactive mode under vacuum (10-6 mbar), yielding ultrafine-grained material (<5 nm) with high chemical homogeneity.
- DAC Assembly: Samples were loaded into pre-indented Rhenium (Re) gaskets. High-purity SCD anvils with specific culet sizes (90 µm, 120 µm, 300 µm) were used, often insulated by Al2O3 layers.
- High P/T Generation: Samples were compressed to target pressures (52-194 GPa). Heating was performed from both sides using 100-W single-mode Yb fiber lasers for short durations (3-5 s) to achieve temperatures up to 4,560 K.
- Temperature Profiling: Radial temperature distributions were measured using the spectro-radiometric method to accurately estimate the temperature at the liquid/solid SiO₂ boundary.
- Pressure Calibration: Pressures were measured at room temperature after heating based on the Raman shift of the diamond culet and corrected for thermal pressure effects.
- Post-Experiment Characterization: Recovered samples were cross-sectioned using a focused Ga ion beam (FEI Versa 3D DualBeam) and analyzed for chemical composition and texture using Field-Emission Electron Microprobe (FE-EPMA) and Energy-Dispersive X-ray (EDX) analysis.
6CCVD Solutions & Capabilities
Section titled “6CCVD Solutions & Capabilities”The successful execution of high-pressure geophysics experiments, particularly those involving LH-DACs, relies entirely on the quality and precision of the diamond anvils. 6CCVD is uniquely positioned to supply the materials and customization services required to replicate and extend this research on planetary core dynamics.
Applicable Materials
Section titled “Applicable Materials”To achieve and maintain pressures up to 194 GPa and temperatures exceeding 4,500 K, the following 6CCVD materials are required:
- Optical Grade Single Crystal Diamond (SCD): Essential for DAC anvils. Our SCD material offers superior mechanical strength, high thermal stability, and extremely low birefringence, ensuring reliable pressure generation and optimal optical access for laser heating and spectro-radiometry.
- High-Purity SCD Substrates: Available in thicknesses from 0.1 µm up to 500 µm for use as specialized windows, insulation layers, or backing plates in complex HPHT assemblies.
Customization Potential
Section titled “Customization Potential”The research explicitly required custom culet dimensions (90 µm, 120 µm, 300 µm) and high surface quality. 6CCVD’s advanced fabrication capabilities directly address these needs:
| Research Requirement | 6CCVD Custom Capability | Technical Specification |
|---|---|---|
| Precision Culet Geometry | Custom laser cutting and shaping services. | Plates/wafers up to 125 mm (PCD) or custom SCD dimensions. |
| Ultra-Low Surface Roughness | Advanced mechanical and chemical polishing. | Ra < 1 nm (SCD); Ra < 5 nm (Inch-size PCD). |
| Metalization for Heating/Sensors | In-house thin-film deposition capability. | Custom metalization layers (Au, Pt, Pd, Ti, W, Cu) for electrodes or resistive heating elements (e.g., in BDD). |
| Boron Doping (BDD) | Custom doping levels available. | Boron-Doped Diamond (BDD) for integrated resistive heating elements or high-pressure electrical conductivity measurements. |
Engineering Support
Section titled “Engineering Support”Replicating the complex Fe-Si-O phase relations at core conditions demands precise material specifications. 6CCVD’s in-house PhD team provides expert consultation to optimize material selection for similar high-pressure geophysics projects:
- Material Selection: Assistance in choosing the optimal SCD grade and crystal orientation for maximum strength and minimal failure risk at multi-megabar pressures.
- Design Optimization: Support for designing custom diamond components, including specific culet angles and dimensions, to maximize pressure generation efficiency and experimental longevity.
- Global Logistics: Global shipping (DDU default, DDP available) ensures rapid delivery of critical components to research facilities worldwide.
For custom specifications or material consultation, visit 6ccvd.com or contact our engineering team directly.