Nanogap near-field thermophotovoltaics

Anthony Fiorino; Linxiao Zhu; Dakotah Thompson; Rohith Mittapally; Pramod Reddy; Edgar Meyhofer

doi:10.1038/s41565-018-0172-5

Nanogap near-field thermophotovoltaics

Anthony Fiorino, Linxiao Zhu, Dakotah Thompson, Rohith Mittapally, Pramod Reddy, Edgar Meyhofer

Mechanical Engineering

Research output: Contribution to journal › Letter › peer-review

87 Scopus citations

Abstract

Conversion of heat to electricity via solid-state devices is of great interest and has led to intense research of thermoelectric materials^1,2. Alternative approaches for solid-state heat-to-electricity conversion include thermophotovoltaic (TPV) systems where photons from a hot emitter traverse a vacuum gap and are absorbed by a photovoltaic (PV) cell to generate electrical power. In principle, such systems may also achieve higher efficiencies and offer more versatility in use. However, the typical temperature of the hot emitter remains too low (<1,000 K) to achieve a sufficient photon flux to the PV cell, limiting practical applications. Theoretical proposals^3–12 suggest that near-field (NF) effects^13–18 that arise in nanoscale gaps may be leveraged to increase the photon flux to the PV cell and significantly enhance the power output. Here, we describe functional NFTPV devices consisting of a microfabricated system and a custom-built nanopositioner and demonstrate an ~40-fold enhancement in the power output at nominally 60 nm gaps relative to the far field. We systematically characterize this enhancement over a range of gap sizes and emitter temperatures, and for PV cells with two different bandgap energies. We anticipate that this technology, once optimized, will be viable for waste heat recovery applications.

Original language	English (US)
Pages (from-to)	806-811
Number of pages	6
Journal	Nature nanotechnology
Volume	13
Issue number	9
DOIs	https://doi.org/10.1038/s41565-018-0172-5
State	Published - Sep 1 2018

All Science Journal Classification (ASJC) codes

Bioengineering
Atomic and Molecular Physics, and Optics
Biomedical Engineering
Materials Science(all)
Condensed Matter Physics
Electrical and Electronic Engineering

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title = "Nanogap near-field thermophotovoltaics",

abstract = "Conversion of heat to electricity via solid-state devices is of great interest and has led to intense research of thermoelectric materials1,2. Alternative approaches for solid-state heat-to-electricity conversion include thermophotovoltaic (TPV) systems where photons from a hot emitter traverse a vacuum gap and are absorbed by a photovoltaic (PV) cell to generate electrical power. In principle, such systems may also achieve higher efficiencies and offer more versatility in use. However, the typical temperature of the hot emitter remains too low (<1,000 K) to achieve a sufficient photon flux to the PV cell, limiting practical applications. Theoretical proposals3–12 suggest that near-field (NF) effects13–18 that arise in nanoscale gaps may be leveraged to increase the photon flux to the PV cell and significantly enhance the power output. Here, we describe functional NFTPV devices consisting of a microfabricated system and a custom-built nanopositioner and demonstrate an ~40-fold enhancement in the power output at nominally 60 nm gaps relative to the far field. We systematically characterize this enhancement over a range of gap sizes and emitter temperatures, and for PV cells with two different bandgap energies. We anticipate that this technology, once optimized, will be viable for waste heat recovery applications.",

author = "Anthony Fiorino and Linxiao Zhu and Dakotah Thompson and Rohith Mittapally and Pramod Reddy and Edgar Meyhofer",

note = "Funding Information: P.R. and E.M. acknowledge support from the Army Research Office under awards W911NF-16-1-0195 and W911NF-18-1-0004 (nanopositing and instrumentation), from the Department of Energy-Basic Energy Science under award DE-SC0004871 (scanning probes and experimental design) and the National Science Foundation under award CBET 1509691 (computational modelling). We acknowledge the Lurie Nanofabrication Facility for facilitating the fabrication of devices.",

year = "2018",

month = sep,

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doi = "10.1038/s41565-018-0172-5",

language = "English (US)",

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journal = "Nature Nanotechnology",

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TY - JOUR

T1 - Nanogap near-field thermophotovoltaics

AU - Fiorino, Anthony

AU - Zhu, Linxiao

AU - Thompson, Dakotah

AU - Mittapally, Rohith

AU - Reddy, Pramod

AU - Meyhofer, Edgar

N1 - Funding Information: P.R. and E.M. acknowledge support from the Army Research Office under awards W911NF-16-1-0195 and W911NF-18-1-0004 (nanopositing and instrumentation), from the Department of Energy-Basic Energy Science under award DE-SC0004871 (scanning probes and experimental design) and the National Science Foundation under award CBET 1509691 (computational modelling). We acknowledge the Lurie Nanofabrication Facility for facilitating the fabrication of devices.

PY - 2018/9/1

Y1 - 2018/9/1

N2 - Conversion of heat to electricity via solid-state devices is of great interest and has led to intense research of thermoelectric materials1,2. Alternative approaches for solid-state heat-to-electricity conversion include thermophotovoltaic (TPV) systems where photons from a hot emitter traverse a vacuum gap and are absorbed by a photovoltaic (PV) cell to generate electrical power. In principle, such systems may also achieve higher efficiencies and offer more versatility in use. However, the typical temperature of the hot emitter remains too low (<1,000 K) to achieve a sufficient photon flux to the PV cell, limiting practical applications. Theoretical proposals3–12 suggest that near-field (NF) effects13–18 that arise in nanoscale gaps may be leveraged to increase the photon flux to the PV cell and significantly enhance the power output. Here, we describe functional NFTPV devices consisting of a microfabricated system and a custom-built nanopositioner and demonstrate an ~40-fold enhancement in the power output at nominally 60 nm gaps relative to the far field. We systematically characterize this enhancement over a range of gap sizes and emitter temperatures, and for PV cells with two different bandgap energies. We anticipate that this technology, once optimized, will be viable for waste heat recovery applications.

AB - Conversion of heat to electricity via solid-state devices is of great interest and has led to intense research of thermoelectric materials1,2. Alternative approaches for solid-state heat-to-electricity conversion include thermophotovoltaic (TPV) systems where photons from a hot emitter traverse a vacuum gap and are absorbed by a photovoltaic (PV) cell to generate electrical power. In principle, such systems may also achieve higher efficiencies and offer more versatility in use. However, the typical temperature of the hot emitter remains too low (<1,000 K) to achieve a sufficient photon flux to the PV cell, limiting practical applications. Theoretical proposals3–12 suggest that near-field (NF) effects13–18 that arise in nanoscale gaps may be leveraged to increase the photon flux to the PV cell and significantly enhance the power output. Here, we describe functional NFTPV devices consisting of a microfabricated system and a custom-built nanopositioner and demonstrate an ~40-fold enhancement in the power output at nominally 60 nm gaps relative to the far field. We systematically characterize this enhancement over a range of gap sizes and emitter temperatures, and for PV cells with two different bandgap energies. We anticipate that this technology, once optimized, will be viable for waste heat recovery applications.

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