Al films on Si were vacuum-annealed for 3 to 9 h at 400°C and 550°C, which are lower
than the eutectic temperature of Al-Si systems. At hypoeutectic temperatures, compressive stress is developed in the films due to the larger thermal expansion of Al film than Si substrate, and this stress facilitates diffusional flow of Al atoms followed by outward diffusion of Si atoms. This interdiffusion of Al and Si atoms resulted in Al-Si alloy microparticles with rough surfaces, which were spontaneously granulated at the cost of the initial Al film. The density, average size, and the composition of the microparticles could be controlled click here by adjusting several parameters such as the film thickness, annealing temperature, and time. The surfaces of the microparticles and the residual Al film turned out to be oxidized,
presumably during cooling and at ambient condition. As a consequence of the microparticle formation, the sheet resistance of Al film on Si substrate increased 27-fold after 9 h annealing at 550°C. This simple technique for the formation of Al-Si microparticles on Si substrate would be a stepping stone for the systematic study of the S3I-201 chemical structure thermoelectric performance of heterogeneous systems based on Al-Si alloys. Acknowledgements This research was supported by the Gachon University. The author thanks Professor Kwang S. Suh of Korea University for his assistance. References 1. Yang J, Stabler FR: Automotive applications buy Alectinib of thermoelectric materials. J Electron Mater 2009, 38:1245–1251.CrossRef 2. Sirtuin activator inhibitor Korzhuev MA, Katin IV: On the placement of thermoelectric generators in automobiles. J Electron Mater 2010, 39:1390–1394.CrossRef 3. Patyk A: Thermoelectrics: impacts on the environment and sustainability. J Electron Mater 2010, 39:2023–2028.CrossRef 4. Goldsmid HJ: Thermoelectric Refrigeration. New York: Plenum; 1963. 5. Majumdar A:
Thermoelectricity in semiconductor nanostructures. Science 2004, 303:777–778.CrossRef 6. Dresselhaus MS, Dresselhaus G, Sun X, Zhang Z, Cronin SB, Koga T: Low-dimensional thermoelectric materials. Phys Sol State 1999, 41:679–682.CrossRef 7. Dresselhaus MS, Chen G, Tang MY, Yang R, Lee H, Wang D, Ren Z, Fleurial JP, Gogna P: New directions for low-dimensional thermoelectric materials. Adv Mater 2007, 19:1043–1053.CrossRef 8. Boukai AI, Bunimovich Y, Tahir-Kheli J, Yu JK, Goddard WA III, Heath JR: Silicon nanowires as efficient thermoelectric materials. Nature 2007, 451:168–171.CrossRef 9. Heremans JP, Dresselhaus MS, Bell LE, Morelli DT: When thermoelectrics reached the nanoscale. Nature Nanotech 2013, 8:471–473.CrossRef 10. Hsu KF, Loo S, Guo F, Chen W, Dyck JS, Uher C, Hogan T, Polychroniadis EK, Kanatzidis MG: Cubic AgPb m SbTe 2+m : bulk thermoelectric materials with high figure of merit. Science 2004, 303:818–821.CrossRef 11.