Symposium NM7-Semiconductor Nanowires for Energy Applications

Nanowires of a variety of materials (e.g., metals, group IV, III-V, II-VI semiconductors, oxides, chalcogenides, etc.) are promising building blocks for many existing and emerging applications. In particular, semiconductor nanowires can play an important role in next generation energy harvesting, conversion and storage. Nanowires allow new designs that are not possible with thin film or bulk counterparts.

For achieving functional devices, the synthesis of semiconductor nanowires with user-defined dimensions, compositions, crystal structures, and heterointerfaces are required. Also, the spatial control of nanowire position and assembly is essential, either pre or post-synthesis.

This symposium will highlight the latest developments and breakthroughs in synthesis, characterization and device fabrication of semiconductor nanowires with an emphasis on their implementation in energy applications. Experimental studies that access nanowire chemistry, structure, or properties in-situ as well as modeling at all length scales are encouraged. Novel syntheses that offer advanced control of nanowire diameter, composition, heterostructure and doping are sought. The symposium also aims to focus on methods that direct the organization of nanowires into large area assemblies with targeted composite properties. Single nanowire and large-area energy harvesting, conversion and storage devices are of interest, from the theoretical and experimental points of view.

The combination of different disciplines (from synthesis to devices) will bring together leading researchers that will help identify innovative directions where semiconductor nanowires will push the frontiers of nano-energy.

• Integration of nanowires into flexible and functional
• Energy storage: batteries, supercapacitors
• Energy scavenging: mechanical, thermoelectric
• Nanowire arrays, networks, and hierarchical systems
• New synthesis methods
• Modeling of novel energy related device designs based on nanowires
• Solar Energy conversion and storage: photovoltaic, solar fuels
• Chemical, structural, optical and electrical characterization at multiple length scales (1 – 100 nm)

• NM7_Semiconductor Nanowires for Energy Applications_0 (California Institute of Technology, USA)
• NM7_Semiconductor Nanowires for Energy Applications_1 (TU Eindhoven, Netherlands)
• NM7_Semiconductor Nanowires for Energy Applications_2 (Hong Kong Polytechnic University, Hong Kong)
• NM7_Semiconductor Nanowires for Energy Applications_3 (Helmholz-Center Berlin, Germany)
• NM7_Semiconductor Nanowires for Energy Applications_4 (Stanford University, USA)
• NM7_Semiconductor Nanowires for Energy Applications_5 (AMOLF, Netherlands)
• NM7_Semiconductor Nanowires for Energy Applications_6 (Massachusetts Institute of Technology, USA)
• NM7_Semiconductor Nanowires for Energy Applications_7 (University of California, Los Angeles, USA)
• NM7_Semiconductor Nanowires for Energy Applications_8 (Australian National University, Australia)
• NM7_Semiconductor Nanowires for Energy Applications_9 (Lund University, Sweden)
• NM7_Semiconductor Nanowires for Energy Applications_10 (Cologne University, Germany)
• NM7_Semiconductor Nanowires for Energy Applications_11 (Georgia Institute of Technology, USA)
• NM7_Semiconductor Nanowires for Energy Applications_12 (Montreal Technical University, Canada)
• NM7_Semiconductor Nanowires for Energy Applications_13 (Ecole Polytechnique, France)
• NM7_Semiconductor Nanowires for Energy Applications_14 (IREC, Spain)
• NM7_Semiconductor Nanowires for Energy Applications_15 (Paris-Sud University, France)
• NM7_Semiconductor Nanowires for Energy Applications_16 (Georgia Institute of Technology, USA)
• NM7_Semiconductor Nanowires for Energy Applications_17 (University of California, Berkeley, USA)
• NM7_Semiconductor Nanowires for Energy Applications_18 (Basel University, Switzerland)
• SM7-Sohini_Kar-Narayan (University of Cambridge, United Kingdom)