Development of Novel Spin Caloritronic Materials and Devices for Heat Management in Nanoelectronic Systems. Spin caloritronics is a new field that combines concepts from spintronics and thermoelectricity. This project is inspired by spin Seebeck effect observed in magnetic insulators and motivated by the basic requirements of nanoscale heat management devices. Such devices are the key components promising to surmount fundamental limits of microelectronic technologies with heat dissipation and p ....Development of Novel Spin Caloritronic Materials and Devices for Heat Management in Nanoelectronic Systems. Spin caloritronics is a new field that combines concepts from spintronics and thermoelectricity. This project is inspired by spin Seebeck effect observed in magnetic insulators and motivated by the basic requirements of nanoscale heat management devices. Such devices are the key components promising to surmount fundamental limits of microelectronic technologies with heat dissipation and power consumption as the size of charge-based logic devices shrinks into nanometre scale. This program is aimed at experimental and theoretical development of novel spin caloritronic materials with spin Seebeck effect at ambient temperature, which is orders of magnitude higher than state-of-the-art materials, for heat management in nanoelectronic systems.Read moreRead less
Sustainability in Computing: A Holistic View. Green computing must provide sustainable processing capabilities with high energy efficiency (lower carbon footprint) and increased product longevity (reducing the need for product replacement). While advances in technology have afforded significant reduction in power requirements, they come with inherent challenges due to uncertainties in micro-scale behaviour, high complexity of quantifying/optimising energy cost or system lifetime in extreme scale ....Sustainability in Computing: A Holistic View. Green computing must provide sustainable processing capabilities with high energy efficiency (lower carbon footprint) and increased product longevity (reducing the need for product replacement). While advances in technology have afforded significant reduction in power requirements, they come with inherent challenges due to uncertainties in micro-scale behaviour, high complexity of quantifying/optimising energy cost or system lifetime in extreme scale computing, and the interaction of non-computing components with individual computing systems. This project addresses these challenges via a holistic, multi-scale paradigm for modelling, analysis, and optimisation of energy cost, carbon footprint, and product lifetime in emerging computing systems.Read moreRead less