Quantifying thermal transport in buried semiconductor nanostructures

Managing thermal transport in nanostructures became a major challenge in the development of active microelectronic, optoelectronic and thermoelectric devices, stalling the famous Moore's law of clock speed increase of microprocessors for more than a decade. To find the solution to this and link...

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Detalles Bibliográficos
Autores: Spièce, Jean, Evangeli, Charalambos|||0000-0003-3867-8530, Robson, Alexander J., Sachat, Alexandros el|||0000-0003-3798-9724, Haenel, Linda, Alonso, M. Isabel, Garriga, Miquel|||0000-0002-6683-0790, Robinson, Benjamin James|||0000-0001-8676-6469, Oehme, Michael|||0000-0002-1637-1338, Schulze, Jörg, Alzina, Francesc|||0000-0002-7082-0624, Sotomayor Torres, Clivia, Kolosov, Oleg Victor|||0000-0003-3278-9643
Tipo de recurso: artículo
Fecha de publicación:2021
País:España
Institución:Universitat Autònoma de Barcelona
Repositorio:Dipòsit Digital de Documents de la UAB
Idioma:inglés
OAI Identifier:oai:ddd.uab.cat:248673
Acceso en línea:https://ddd.uab.cat/record/248673
https://dx.doi.org/urn:doi:10.1039/d0nr08768h
Access Level:acceso abierto
Palabra clave:Cross-sectional scanning
Interfacial thermal resistance
Multilayer nanostructures
Nanoscale thermal transport
Opto-electronic materials
Scanning thermal microscopy
Semiconductor nanostructures
Thermoreflectance measurement
Descripción
Sumario:Managing thermal transport in nanostructures became a major challenge in the development of active microelectronic, optoelectronic and thermoelectric devices, stalling the famous Moore's law of clock speed increase of microprocessors for more than a decade. To find the solution to this and linked problems, one needs to quantify the ability of these nanostructures to conduct heat with adequate precision, nanoscale resolution, and, essentially, for the internal layers buried in the 3D structure of modern semiconductor devices. Existing thermoreflectance measurements and "hot wire"3ω methods cannot be effectively used at lateral dimensions of a layer below a micrometre; moreover, they are sensitive mainly to the surface layers of a relatively high thickness of above 100 nm. Scanning thermal microscopy (SThM), while providing the required lateral resolution, provides mainly qualitative data of the layer conductance due to undefined tip-surface and interlayer contact resistances. In this study, we used cross-sectional SThM (xSThM), a new method combining scanning probe microscopy compatible Ar-ion beam exit nano-cross-sectioning (BEXP) and SThM, to quantify thermal conductance in complex multilayer nanostructures and to measure local thermal conductivity of oxide and semiconductor materials, such as SiO2, SiGex and GeSny. By using the new method that provides 10 nm thickness and few tens of nm lateral resolution, we pinpoint crystalline defects in SiGe/GeSn optoelectronic materials by measuring nanoscale thermal transport and quantifying thermal conductivity and interfacial thermal resistance in thin spin-on materials used in extreme ultraviolet lithography (eUV) fabrication processing. The new capability of xSThM demonstrated here for the first time is poised to provide vital insights into thermal transport in advanced nanoscale materials and devices.