Ananoscale heat source (or Nano-Heater) which allows intense, localized, rapid and controlled one-time heating of nanostructures.
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Backgound Active use of heat to alter the geometry, structure and properties of solids is central to material removal, deposition, joining, shaping and transformation processes in macroscale manufacturing. In modern nanoscale engineering, however, similar thermal routes appear to encroach upon fundamental technical limits. In microelectronics, for example, rapid thermal processing (RTP) of semiconductor wafers in lamp or hotwall reactors is routinely used, but typically poses constraints to the process sequence because of the destructive consequences of long “thermal budgets” to sensitive pre-fabricated device structures. In general, such limitations arise because the characteristic lengths and times of heat transfer in macroscale reactors by traditional sources are incompatible with the spatial/temporal dimensions of nanoscale structures and phenomena. Therefore, there is an outstanding need for new disruptive heat source technologies, enabling fine local selectivity and time-exposure control in thermal processing at the nanoscale level. Such heat sources will revolutionize manufacturing, as well as on-board thermal actuation and autonomous powering during operation of miniature devices and systems Technology UMass Lowell faculty, Julie Chen along with her collaborators from Northeastern University and the University of Cyprus, have invented a nanoscale heat source (or Nano-Heater) which allows intense, localized, rapid and controlled one-time heating of nanostructures with the potential for repeated heating through the delivery of a controlled flow of reactants [1]. This invention introduces a revolutionary development in nanothechnology and nanomanufacturing. The nano-heater exploits exothermic material transformations of reactive thin films separated by nano-thick dielectric interlayers with transverse nano-channel pores. The nano-heater technology utilizes significant advances in nanoscience research to address the current technical constraints with thermal heating in nanomanufacturing [2]. The selectivity and control of Nano-Heaters will lead to dramatic reduction in thermal budgets and superior processing quality in annealing, oxidation and chemical vapor deposition (CVD) of semiconductors. Thermal self-processing of electronics with layered sources patterns will obviate the compromised performance and expense of rapid thermal processing (RTP) reactors and furnaces. Up to now, the need for external connections with macroscale power supplies has negated many of the benefits of miniaturization. Applications New disruptive or enabling technologies emerge for thermal manufacturing and laboratory experimentation at the nanoscale level. In microelectronics, the fine selectivity and fast control of nano-heaters will lead to dramatic reduction of thermal budgets and superior processing quality in annealing, oxidation, CVD etc. of semiconductors. Self-heatable nanomaterials (powders, fibers, tubes, platelets etc) and nanotemplate tools coated with reactive layers, will enable unique consolidation and guided self-assembly routes for nanostructured and nanocomposite materials, preserving the special properties of their constituents from crude heat treatment. Engineered tissues grown on nanofiber membrane scaffolds with microporous channels shaped by nanoheated particles can be made available for custom perfusion by cells and biomolecules in regenerative medicine. An entire armory of macro-thermal manufacturing processes, such as welding, molding, ablation etc. can be conveniently scaled down to nanoscale production and laboratory research, with the tools offered by low-cost nano-heaters. References [1] H. Jogdand, G. Gulsoy, T. Ando, J. Chen, C. Doumanidis, Z. Gu, C. Rebholz, P. Wong . Fabrication and characterization of nanoscale heating sources ("nanoheaters") for nanomanufacturing. Technical Proceedings of the 2008 NSTI Nanotechnology Conference and Trade Show, NSTI-Nanotech, Nanotechnology 2008, Volume 1, Pages 280-283 [2] Zhiyong Gua, Qingzhou Cuia, Julie Chen et al. Fabrication, characterization and applications of novel nanoheater structures. Surface and Coating Technology. (2013) Proceedings of the 39th International Conference on Metallurgical Coatings and Thin Films (ICMCTF) — ICMCTF 2012. Volume 215, Pages 493–502