A Thermoelectric Cat Warmer from Microprocessor Waste Heat

1. A Thermoelectric Cat Warmer from Microprocessor Waste Heat Simha Sethumadhavan Doug Burger Department of Computer Sciences The University of Texas at Austin

2. Motivation • Hot laptops • Cold cats • Frozen whiskers • Reduced pest control

3. Solution Purr On chip Thermoelectric Generator Heat Current This talk

4. Hot End Cold End TH Tc i Thermoelectricity • Thermoelectricity: Electricity produced from heat • First observed by Seebeck in 1822 Wire Replica of the apparatus V = S.T Thomas Seebeck

5. Traditional Uses Seiko “Thermic” watches 5°C body heat, 60W Doped Poly Si, .3% efficiency Cassini space probe 32.8Kg radioactive plutonium fuel, InGaAs thermocouple, 628 Watts, 3-4% efficiency

6. Cat Mutator Docile Cat Radioactive Plutonium Pellet

7. e Electrons: current flow Phonons: heat flow p The Physics When a wire is heated electrons and phonons diffuse • Electrons • Higher electron diffusion  more current (good) • Phonons • Collide with other phonons and increase heat flow (bad) or • Either transfer their momentum to electrons (good) or • Lose their momentum due to boundary collisions (good) e e e e e p p p p p p e e e e Hot end Cold end

8. Traditional Materials Ideally for large thermoelectric current • Low phonon flow • Const temperature difference  Low thermalconductivity • Many high energy electrons • Small resistance  High electrical conductivity • Many phonon electron collisions • Large voltage per unit temperature difference  High Seebeck constant Nanotech allows constants be controlled independently & precisely

9. New Thin-film Wires • Thin film and metal boundary do not align • More phonon boundary collisions • More electron phonon collisions • Figure of Merit (M = seebeck2. elec/therm) • Traditional Poly Si is 0.4 • Thin-film Bismuth Tellurideis 2.38 • [Venkatasubramanium et al. Nature 2001] e e e e e p p p p p p e e e e Cold end Hot end Thin film (few nanometers)

10. Generator Efficiency Maximum theoretical efficiency of any generator Chip temperatures • Cold end (Tc) • 27°C • Hot end (TH) • 77° C, 52 ° C • M for Bismuth Telluride • 6x better

11. Horizontal Generator Horizontal Generator (nanowire bundles) Hot end Cold end Wiring Layers Die • Run a bundle of Bismuth Telluride nanowires from processor hot spot to cold spot • Temperature difference: ~50 degrees

12. Vertical Generator Wiring Layers Hot surface Die Cold surface Vertical Generator • Run a bundle of Bismuth Telluride nanowires from logic level to the heat spreader • Temperature difference: ~20 degrees

13. Multiple Generators Vertical Generator Purr Cold surface Die Hot surface

14. Rough Estimates For Bismuth Telluride: • Seebeck coefficienct 243V/K • Resistivity: 1.2 x 10-5 ohm/meter

15. Conclusions • Limitations • Manufacturing • Engineering: Hinders cooling, peripheral circuitry overheads • Only cats are supported • Final thoughts • Thermoelectric heat extraction looks interesting • Newer materials can improve power output further • How far can this be pushed? • When does this become interesting to architects? Thank You!