Broadband Epsilon-near-Zero Reflectors Enhance the Quantum Efficiency of Thin Solar Cells at Visible and Infrared Wavelengths.

The engineering of broadband absorbers to harvest white light in thin-film semiconductors is a major challenge in developing renewable materials for energy harvesting. Many solution-processed materials with high manufacturability and low cost, such as semiconductor quantum dots, require the use of film structures with thicknesses on the order of 1 μm to absorb incoming photons completely. The electron transport lengths in these media, however, are 1 order of magnitude smaller than this length, hampering further progress with this platform. Herein, we show that, by engineering suitably disordered nanoplasmonic structures, we have created a new class of dispersionless epsilon-near-zero composite materials that efficiently harness white light. Our nanostructures localize light in the dielectric region outside the epsilon-near-zero material with characteristic lengths of 10-100 nm, resulting in an efficient system for harvesting broadband light when a thin absorptive film is deposited on top of the structure. By using a combination of theory and experiments, we demonstrate that ultrathin layers down to 50 nm of colloidal quantum dots deposited atop the epsilon-near-zero material show an increase in broadband absorption ranging from 200% to 500% compared to a planar structure of the same colloidal quantum-dot-absorber average thickness. When the epsilon-near-zero nanostructures were used in an energy-harvesting module, we observed a spectrally averaged 170% broadband increase in the external quantum efficiency of the device, measured at wavelengths between 400 and 1200 nm. Atomic force microscopy and photoluminescence excitation measurements demonstrate that the properties of these epsilon-near-zero structures apply to general metals and could be used to enhance the near-field absorption of semiconductor structures more widely. We have developed an inexpensive electrochemical deposition process that enables scaled-up production of this nanomaterial for large-scale energy-harvesting applications.

[1]  Aram Amassian,et al.  Hybrid passivated colloidal quantum dot solids. , 2012, Nature nanotechnology.

[2]  Joel Jean,et al.  ZnO Nanowire Arrays for Enhanced Photocurrent in PbS Quantum Dot Solar Cells , 2013, Advanced materials.

[3]  R. Egerton Electron energy-loss spectroscopy in the TEM , 2008 .

[4]  Edward H. Sargent,et al.  Self‐Assembled, Nanowire Network Electrodes for Depleted Bulk Heterojunction Solar Cells , 2013, Advanced materials.

[5]  H. Atwater,et al.  Plasmonics for improved photovoltaic devices. , 2010, Nature materials.

[6]  Andrea Fratalocchi,et al.  Dynamic light diffusion, three-dimensional Anderson localization and lasing in inverted opals , 2008 .

[7]  Jianfeng Huang,et al.  Harnessing structural darkness in the visible and infrared wavelengths for a new source of light. , 2016, Nature nanotechnology.

[8]  U. Leonhardt Optical Conformal Mapping , 2006, Science.

[9]  Moungi G. Bawendi,et al.  Improved performance and stability in quantum dot solar cells through band alignment engineering , 2014, Nature materials.

[10]  Shana O Kelley,et al.  Direct genetic analysis of ten cancer cells: tuning sensor structure and molecular probe design for efficient mRNA capture. , 2011, Angewandte Chemie.

[11]  Yuri S. Kivshar,et al.  Energy equipartition and unidirectional emission in a spaser nanolaser , 2016 .

[12]  Edward H Sargent,et al.  Photojunction field-effect transistor based on a colloidal quantum dot absorber channel layer. , 2015, ACS nano.

[13]  Peter Nordlander,et al.  Compact solar autoclave based on steam generation using broadband light-harvesting nanoparticles , 2013, Proceedings of the National Academy of Sciences.

[14]  G. Konstantatos,et al.  Hybrid graphene-quantum dot phototransistors with ultrahigh gain. , 2011, Nature nanotechnology.

[15]  Ratan Debnath,et al.  Depleted-heterojunction colloidal quantum dot solar cells. , 2010, ACS nano.

[16]  D. R. Smith,et al.  Transformation Optics and Subwavelength Control of Light , 2012, Science.

[17]  Shana O Kelley,et al.  Chip-based nanostructured sensors enable accurate identification and classification of circulating tumor cells in prostate cancer patient blood samples. , 2013, Analytical chemistry.

[18]  Tobias Hanrath,et al.  Solution‐Processed Nanocrystal Quantum Dot Tandem Solar Cells , 2011, Advanced materials.

[19]  Edward H. Sargent,et al.  Jointly tuned plasmonic-excitonic photovoltaics using nanoshells. , 2013, Nano letters.

[20]  Peter Nordlander,et al.  Solar vapor generation enabled by nanoparticles. , 2013, ACS nano.

[21]  Nader Engheta,et al.  Experimental verification of n = 0 structures for visible light. , 2013, Physical review letters.

[22]  Jin Young Kim,et al.  Conformal fabrication of colloidal quantum dot solids for optically enhanced photovoltaics. , 2015, ACS nano.

[23]  Vladimir Bulovic,et al.  Photodetectors based on treated CdSe quantum-dot films , 2005 .

[24]  Andrea Fratalocchi,et al.  Colloidal quantum dot solar cells exploiting hierarchical structuring. , 2015, Nano letters.

[25]  L Angelani,et al.  Condensation in disordered lasers: theory, 3D+1 simulations, and experiments. , 2008, Physical review letters.

[26]  Florian Libisch,et al.  Hot electrons do the impossible: plasmon-induced dissociation of H2 on Au. , 2013, Nano letters.

[27]  H. Queisser,et al.  Detailed Balance Limit of Efficiency of p‐n Junction Solar Cells , 1961 .

[28]  V. Shalaev Nonlinear Optics of Random Media: Fractal Composites and Metal-Dielectric Films , 1999 .

[29]  Johann Osmond,et al.  Solution-processed inorganic bulk nano-heterojunctions and their application to solar cells , 2012, Nature Photonics.

[30]  S. Adachi The Handbook on Optical Constants of Metals:In Tables and Figures , 2012 .

[31]  Larissa Levina,et al.  Fast, sensitive and spectrally tuneable colloidal-quantum-dot photodetectors. , 2009, Nature nanotechnology.

[32]  J. Parsons,et al.  Experimental realization of an epsilon-near-zero metamaterial at visible wavelengths , 2013, Nature Photonics.

[33]  Ludovic S. Live,et al.  Solution-based circuits enable rapid and multiplexed pathogen detection , 2013, Nature Communications.

[34]  Thomas F. Krauss,et al.  Enhanced energy storage in chaotic optical resonators , 2013, Nature Photonics.

[35]  Ratan Debnath,et al.  Depleted Bulk Heterojunction Colloidal Quantum Dot Photovoltaics , 2011, Advanced materials.

[36]  Edward H. Sargent,et al.  Broadband solar absorption enhancement via periodic nanostructuring of electrodes , 2013, Scientific Reports.

[37]  Mark I. Stockman,et al.  CHAOS AND SPATIAL CORRELATIONS FOR DIPOLAR EIGENPROBLEMS , 1997 .

[38]  E Di Fabrizio,et al.  Hot-electron nanoscopy using adiabatic compression of surface plasmons. , 2013, Nature nanotechnology.

[39]  Thomas F. Krauss,et al.  Triggering extreme events at the nanoscale in photonic seas , 2015, Nature Physics.

[40]  Nader Engheta,et al.  Tunneling of electromagnetic energy through subwavelength channels and bends using epsilon-near-zero materials. , 2006, Physical review letters.

[41]  Shana O Kelley,et al.  Hierarchical nanotextured microelectrodes overcome the molecular transport barrier to achieve rapid, direct bacterial detection. , 2011, ACS nano.

[42]  Ratan Debnath,et al.  Ordered Nanopillar Structured Electrodes for Depleted Bulk Heterojunction Colloidal Quantum Dot Solar Cells , 2012, Advanced materials.

[43]  G. Konstantatos,et al.  Ultrasensitive solution-cast quantum dot photodetectors , 2006, Nature.