​SiC Diamond Al Composite

SiC Diamond Al  Composite

Low-temperature synthesizing SiC on diamond surface and its improving effects on thermal conductivity

and stability of diamond/Al composite

At DiaSemi, our mission is to deliver high-performance, reliable thermal interface materials leveraging

the superior thermal conductivity of diamond-reinforced metal matrix composites. Recent studies

reinforce our strategic direction, particularly regarding the role of interface engineering in maintaining

long-term performance under harsh environmental conditions.

Key Insights on Diamond/Aluminum (Diamond/Al) Composites Performance:

1. Challenge with Conventional Diamond/Al Composites:

Traditional diamond/Al composites suffer from thermal conductivity degradation during exposure to

moisture due to the formation and hydrolysis of Al₄C₃ (aluminum carbide) at the diamond/Al interface.

Hydrolysis of Al₄C₃ leads to the formation of Al(OH)₃ and methane gas, causing:

Interface deterioration (pores and cracks),

Weakened bonding, and

Sharp decline in thermal conductivity over time.

2. SiC Coating: A Strategic Interface Solution

To address this, DiaSemi supports the use of a SiC (silicon carbide) interfacial layer on diamond particles.

The key benefits include:

Suppression of Al₄C₃ formation, thereby improving moisture resistance.

Stable thermal performance under long-term water immersion.

Only a 6.31% reduction in thermal conductivity (from 666 to 624 W/m·K) after 500 hours of water

soaking.

This validates SiC coating as an effective barrier that minimizes diamond-Al direct contact, reduces

interfacial reactions, and enhances composite durability.

3. Thermal Conductivity Stability Modeled by Gaussian Fit

Thermal conductivity degradation follows a Gaussian trend, reflecting three distinct stages:

Stage Behavior Interpretation

Region I Gradual decline Minimal initial hydrolysis

Region II Rapid drop Accelerated Al₄C₃ breakdown and pore formation

Region III Slowed degradation Most reactive phases consumed

4. Experimental Confirmation:

SEM imaging shows heavy degradation on uncoated diamonds, while SiC-coated surfaces remain largely

intact.

XRD analysis confirms presence of Al(OH)₃ only in uncoated composites.

Coated composites exhibit no detectable Al(OH)₃, reinforcing the protective effect of the SiC layer.

5. Competitive Advantage in Thermal Conductivity:

Interlayer         TC (W/m·K)                Moisture Resistance

SiC (DiaSemi)  666                            Excellent

TiC                    650                           Moderate

ZrC                    572                           Moderate

WC                    500                           Fair

Mo₂C                 362                            Low

DiaSemi’s Position: 

This study confirms DiaSemi’s material design strategy—leveraging SiC-coated diamond

reinforcements—as a robust approach to achieving both high thermal conductivity and long-term

environmental stability in metal matrix composites.

We will continue refining our low-temperature SiC synthesis processes to enhance interfacial bonding

while preserving the thermal integrity essential for applications in power electronics, aerospace, and

high-performance computing.