Seebeck Tuning in Chalcogenide Nanoplate Assemblies by Nanoscale Heterostructuring

Citations Over TimeTop 10% of 2010 papers

Abstract

Chalcogenide nanostructures offer promise for obtaining nanomaterials with high electrical conductivity, low thermal conductivity, and high Seebeck coefficient. Here, we demonstrate a new approach of tuning the Seebeck coefficient of nanoplate assemblies of single-crystal pnictogen chalcogenides by heterostructuring the nanoplates with tellurium nanocrystals. We synthesized bismuth telluride and antimony telluride nanoplates decorated with tellurium nanorods and nanofins using a rapid, scalable, microwave-stimulated organic surfactant-directed technique. Heterostructuring permits two- to three-fold factorial tuning of the Seebeck coefficient, and yields a 40% higher value than the highest reported for bulk antimony telluride. Microscopy and spectroscopy analyses of the nanostructures suggest that Seebeck tunability arises from carrier-energy filtration effects at the Te-chalcogenide heterointerfaces. Our approach of heterostructuring nanoscale building blocks is attractive for realizing high figure-of-merit thermoelectric nanomaterials.

Related Papers

• → Phosphorene and Phosphorene‐Based Materials – Prospects for Future Applications(2016)480 cited
• → Epitaxial Synthesis of Blue Phosphorene(2018)172 cited
• → Unzipping of black phosphorus to form zigzag-phosphorene nanobelts(2020)95 cited
• → Vacancy defected blue and black phosphorene nanoribbons as gas sensor of NOx and SOx molecules(2020)41 cited
• Research Progress of Tellurium-based Chalcogenide Long-wave Infrared Transmitting Fibers(2014)