| Image | Part Number | Description / PDF | Quantity | Rfq |
|---|---|---|---|---|
 |
Laird - Performance Materials |
TPUTTY 403 360CC CARTRIDGE |
18 |
|
 |
MG Chemicals |
GREASE SILVER CONDUCTIVE 0.25OZ |
2 |
|
 |
Chip Quik, Inc. |
HEAT SINK COMPOUND - GREY ULTRA |
19 |
|
 |
t-Global Technology |
THERMAL POTTING EPOXY 0.75KG PAC |
123 |
|
 |
MG Chemicals |
EPOXY |
0 |
|
 |
Aavid |
THERMAL PASTE |
21 |
|
 |
MG Chemicals |
SUPER THERMAL GREASE |
46 |
|
 |
t-Global Technology |
NON-SILICONE THERMAL PUTTY 4OZ D |
16 |
|
 |
Laird - Performance Materials |
THERMAL GREASE 30CC TGREASE 880 |
0 |
|
 |
Aavid |
THERMALCOTE GREASE TUBE 1OZ |
181 |
|
 |
Parker Chomerics |
THERM-A-GAP TC50 5.2W/M-K 300CC |
0 |
|
 |
Parker Chomerics |
THERM-A-GAP GEL30 300CC |
354 |
|
 |
Taica Corporation |
THERMAL PASTE, 30CC SYRINGE |
3 |
|
 |
t-Global Technology |
HIGH PERFORMANCE SILICONE GREASE |
0 |
|
 |
MG Chemicals |
FAST CURE THERM COND ADH FLOW |
25 |
|
 |
t-Global Technology |
NON-SILICONE THERMAL GREASE 30G |
51 |
|
 |
CAIG Laboratories, Inc. |
SILICONE HEAT SINK COMPOUND SQUE |
14 |
|
 |
Aavid |
THERMALBOND EPOXY 7OZ PACKET |
27 |
|
 |
Parker Chomerics |
T670 3W/M-K GREASE 80CC JAR |
12 |
|
 |
Henkel / Bergquist |
LIQUID GAP FILLER THERMAL CONDU |
0 |
|
Thermal interface materials (TIMs) are specialized substances designed to enhance heat transfer between mating surfaces. These materials fill microscopic air gaps and reduce thermal resistance in electronic, mechanical, and industrial systems. With increasing power densities in modern devices, effective thermal management has become critical for reliability, performance, and longevity.
| Type | Functional Characteristics | Application Examples |
|---|---|---|
| Thermal Adhesives | Permanently bond surfaces while conducting heat. Available in conductive/dielectric variants. | CPU heatsink bonding, LED module assembly |
| Epoxy Systems | Two-part compounds with high structural strength and thermal conductivity. | Power module encapsulation, motor controller assembly |
| Thermal Greases | Non-curing compounds with optimal gap-filling properties. | GPU cooling, automotive sensor mounting |
| Phase Change Materials | Temperature-activated compounds that optimize interface at operational temperatures. | Server processors, high-frequency amplifiers |
Typical formulations include:
Material microstructure is engineered to balance thermal performance with mechanical compliance.
| Parameter | Significance | Typical Range |
|---|---|---|
| Thermal Conductivity | Primary measure of heat transfer efficiency | 1-8 W/m K |
| Operating Temperature | Determines application environment suitability | -50 C to 200 C |
| Viscosity | Affects application method and gap coverage | 500-500,000 cP |
| Dielectric Strength | Electrical insulation capability | 5-30 kV/mm |
| Curing Time/Temperature | Production process compatibility | Room temp-150 C |
| Manufacturer | Key Products | Specialty |
|---|---|---|
| 3M | TC-2810 Adhesive | High-conductivity die attach |
| Dow | SYLGARD 8660 | Low-outgassing space applications |
| Henkel | Berger TIM 880 | Phase-change processor pads |
| Master Bond | EP42HT-2AO | Two-part conductive epoxy |
Key considerations:
Case Study: A server manufacturer reduced CPU operating temperatures by 12 C by switching from standard grease to a phase-change material with optimized melt profile.
Emerging developments include: