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2. Roadmap on optical energy conversion

Author

Boriskina, Svetlana V, Green, Martin A, Catchpole, Kylie, Yablonovitch, Eli, Beard, Matthew C, Okada, Yoshitaka, Lany, Stephan, Gershon, Talia, Zakutayev, Andriy, Tahersima, Mohammad H, Sorger, Volker J, Naughton, Michael J, Kempa, Krzysztof, Dagenais, Mario, Yao, Yuan, Xu, Lu, Sheng, Xing, Bronstein, Noah D, Rogers, John A, Alivisatos, A Paul, Nuzzo, Ralph G, Gordon, Jeffrey M, Wu, Di M, Wisser, Michael D, Salleo, Alberto, Dionne, Jennifer, Bermel, Peter, Greffet, Jean-Jacques, Celanovic, Ivan, Soljacic, Marin, Manor, Assaf, Rotschild, Carmel, Raman, Aaswath, Zhu, Linxiao, Fan, Shanhui, and Chen, Gang

Subjects
Engineering, Electrical Engineering, Atomic, Molecular and Optical Physics, Physical Sciences, optical energy conversion, light harvesting, solar technology, photovoltaics, solar cell
Abstract

For decades, progress in the field of optical (including solar) energy conversion was dominated by advances in the conventional concentrating optics and materials design. In recent years, however, conceptual and technological breakthroughs in the fields of nanophotonics and plasmonics combined with a better understanding of the thermodynamics of the photon energy-conversion processes reshaped the landscape of energy-conversion schemes and devices. Nanostructured devices and materials that make use of size quantization effects to manipulate photon density of states offer a way to overcome the conventional light absorption limits. Novel optical spectrum splitting and photon-recycling schemes reduce the entropy production in the optical energy-conversion platforms and boost their efficiencies. Optical design concepts are rapidly expanding into the infrared energy band, offering new approaches to harvest waste heat, to reduce the thermal emission losses, and to achieve noncontact radiative cooling of solar cells as well as of optical and electronic circuitries. Light-matter interaction enabled by nanophotonics and plasmonics underlie the performance of the third- and fourth-generation energy-conversion devices, including up- and down-conversion of photon energy, near-field radiative energy transfer, and hot electron generation and harvesting. Finally, the increased market penetration of alternative solar energy-conversion technologies amplifies the role of cost-driven and environmental considerations. This roadmap on optical energy conversion provides a snapshot of the state of the art in optical energy conversion, remaining challenges, and most promising approaches to address these challenges. Leading experts authored 19 focused short sections of the roadmap where they share their vision on a specific aspect of this burgeoning research field. The roadmap opens up with a tutorial section, which introduces major concepts and terminology. It is our hope that the roadmap will serve as an important resource for the scientific community, new generations of researchers, funding agencies, industry experts, and investors.

Published
2016

3. Metamaterial Broadband Angular Selectivity

Author

Shen, Yichen, Ye, Dexin, Wang, Zhiyu, Wang, Li, Celanovic, Ivan, Ran, Lixin, Joannopoulos, John D, and Soljacic, Marin

Subjects
Physics - Optics
Abstract

We demonstrate how broadband angular selectivity can be achieved with stacks of one-dimensionally periodic photonic crystals, each consisting of alternating isotropic layers and effective anisotropic layers, where each effective anisotropic layer is constructed from a multilayered metamaterial. We show that by simply changing the structure of the metamaterials, the selective angle can be tuned to a broad range of angles; and, by increasing the number of stacks, the angular transmission window can be made as narrow as desired. As a proof of principle, we realize the idea experimentally in the microwave regime. The angular selectivity and tunability we report here can have various applications such as in directional control of electromagnetic emitters and detectors., Comment: 5 pages, 5 figures

Published
2014
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4. Near-field thermal radiation transfer controlled by plasmons in graphene

Author

Ilic, Ognjen, Jablan, Marinko, Joannopoulos, John D., Celanovic, Ivan, Buljan, Hrvoje, and Soljačić, Marin

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

It is shown that thermally excited plasmon-polariton modes can strongly mediate, enhance and \emph{tune} the near-field radiation transfer between two closely separated graphene sheets. The dependence of near-field heat exchange on doping and electron relaxation time is analyzed in the near infra-red within the framework of fluctuational electrodynamics. The dominant contribution to heat transfer can be controlled to arise from either interband or intraband processes. We predict maximum transfer at low doping and for plasmons in two graphene sheets in resonance, with orders-of-magnitude enhancement (e.g. $10^2$ to $10^3$ for separations between $0.1\mu m$ to $10nm$) over the Stefan-Boltzmann law, known as the far field limit. Strong, tunable, near-field transfer offers the promise of an externally controllable thermal switch as well as a novel hybrid graphene-graphene thermoelectric/thermophotovoltaic energy conversion platform., Comment: 4 pages, 3 figures

Published
2012
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5. Frequency-selective near-field enhancement of radiative heat transfer via photonic-crystal slabs: a general computational approach for arbitrary geometries and materials

Author

Rodriguez, Alejandro W., Ilic, Ognjen, Bermel, Peter, Celanovic, Ivan, Joannopoulos, John D., Soljacic, Marin, and Johnson, Steven G.

Subjects
Condensed Matter - Materials Science
Abstract

We demonstrate the possibility of achieving enhanced frequency-selective near-field radiative heat transfer between patterned (photonic crystal) slabs at designable frequencies and separations, exploiting a general numerical approach for computing heat transfer in arbitrary geometries and materials based on the finite-difference time-domain method. Our simulations reveal a tradeoff between selectivity and near-field enhancement as the slab--slab separation decreases, with the patterned heat transfer eventually reducing to the unpatterned result multiplied by a fill factor (described by a standard proximity approximation). We also find that heat transfer can be further enhanced at selective frequencies when the slabs are brought into a glide-symmetric configuration, a consequence of the degeneracies associated with the non-symmorphic symmetry group.

Published
2011
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11. Practical emitters for thermophotovoltaics: a review

Author

Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Physics, Massachusetts Institute of Technology. Research Laboratory of Electronics, Sakakibara, Reyu, Stelmakh, Veronika, Chan, Walker R, Ghebrebrhan, Michael, Joannopoulos, John, Soljacic, Marin, Celanovic, Ivan L., Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Physics, Massachusetts Institute of Technology. Research Laboratory of Electronics, Sakakibara, Reyu, Stelmakh, Veronika, Chan, Walker R, Ghebrebrhan, Michael, Joannopoulos, John, Soljacic, Marin, and Celanovic, Ivan L.

Abstract

© 2019 Society of Photo-Optical Instrumentation Engineers (SPIE) Thermophotovoltaic (TPV) systems are promising for harnessing solar energy, waste heat, and heat from radioisotope decay or fuel combustion. TPV systems work by heating an emitter that emits light that is converted to electricity. One of the key challenges is designing an emitter that not only preferentially emits light in certain wavelength ranges but also simultaneously satisfies other engineering constraints. To elucidate these engineering constraints, we first provide an overview of the state of the art, by classifying emitters into three categories based on whether they have been used in prototype system demonstrations, fabricated and measured, or simulated. We then present a systematic approach for assessing emitters. This consists of five metrics: optical performance, ability to scale to large areas, stability at high temperatures, ability to integrate into the system, and cost. Using these metrics, we evaluate and discuss the reported results of emitters used in system demonstrations. Although there are many emitters with good optical performance, more studies on their practical attributes are required, especially for those that are not yet used in prototype systems. This framework can serve as a guide for the development of emitters for long-lasting, high-performance TPV systems.

Published
2022

14. Thermophotovoltaic and thermoelectric portable power generators

Author

Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Physics, Chan, Walker R, Waits, Christopher M., Joannopoulos, John, Celanovic, Ivan L., Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Physics, Chan, Walker R, Waits, Christopher M., Joannopoulos, John, and Celanovic, Ivan L.

Abstract

The quest for developing clean, quiet, and portable high energy density, and ultra-compact power sources continues. Although batteries offer a well known solution, limits on the chemistry developed to date constrain the energy density to 0.2 kWh/kg, whereas many hydrocarbon fuels have energy densities closer to 13 kWh/kg. The fundamental challenge remains: how efficiently and robustly can these widely available chemical fuels be converted into electricity in a millimeter to centimeter scale systems? Here we explore two promising technologies for high energy density power generators: thermophotovoltaics (TPV) and thermoelectrics (TE). These heat to electricity conversion processes are appealing because they are fully static leading to quiet and robust operation, allow for multifuel operation due to the ease of generating heat, and offer high power densities. We will present some previous work done in the TPV and TE fields. In addition we will outline the common technological barriers facing both approaches, as well as outline the main differences. Performance for state of the art research generators will be compared as well as projections for future practically achievable systems. A viable TPV or TE power source for a ten watt for one week mission can be built from a <10% efficient device which is achievable with current state of the art technology such as photonic crystals or advanced TE materials. © 2014 SPIE., Army Research Office (Contracts DAAD-19-02-D0002 and W911NF-07-D0004)

Published
2021

15. Thermophotovoltaic and thermoelectric portable power generators

Author

Chan, Walker R., Waits, Christopher M., Joannopoulos, John D., Celanovic, Ivan, Chan, Walker R., Waits, Christopher M., Joannopoulos, John D., and Celanovic, Ivan

Abstract

The quest for developing clean, quiet, and portable high energy density, and ultra-compact power sources continues. Although batteries offer a well known solution, limits on the chemistry developed to date constrain the energy density to 0.2 kWh/kg, whereas many hydrocarbon fuels have energy densities closer to 13 kWh/kg. The fundamental challenge remains: how efficiently and robustly can these widely available chemical fuels be converted into electricity in a millimeter to centimeter scale systems? Here we explore two promising technologies for high energy density power generators: thermophotovoltaics (TPV) and thermoelectrics (TE). These heat to electricity conversion processes are appealing because they are fully static leading to quiet and robust operation, allow for multifuel operation due to the ease of generating heat, and offer high power densities. We will present some previous work done in the TPV and TE fields. In addition we will outline the common technological barriers facing both approaches, as well as outline the main differences. Performance for state of the art research generators will be compared as well as projections for future practically achievable systems. A viable TPV or TE power source for a ten watt for one week mission can be built from a <10% efficient device which is achievable with current state of the art technology such as photonic crystals or advanced TE materials. © 2014 SPIE.

Published
2021

16. Fabrication of an Omnidirectional 2D Photonic Crystal Emitter for Thermophotovoltaics

Author

Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Physics, Stelmakh, Veronika, Chan, Walker R, Ghebrebrhan, M, Soljacic, Marin, Joannopoulos, John, Celanovic, Ivan L., Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Physics, Stelmakh, Veronika, Chan, Walker R, Ghebrebrhan, M, Soljacic, Marin, Joannopoulos, John, and Celanovic, Ivan L.

Abstract

In a thermophotovoltaic (TPV) system, a heat source brings an emitter to incandescence and the spectrally confined thermal radiation is converted to electricity by a low-bandgap photovoltaic (PV) cell. Efficiency is dominated by the emitter's ratio of in-band emissivity (convertible by the PV cell) to out-of-band emissivity (inconvertible). Two-dimensional photonic crystals (PhCs) offer high in-band emissivity and low out-of-band emissivity at normal incidence, but have reduced in-band emissivity off-normal. According to Lambert's law, most thermal radiation occurs off-normal. An omnidirectional PhC capable of high in-band emissivity at all angles would increase total in-band power by 55% at 1200°C. In this work, we present the first experimental demonstration an omnidirectional hafnia-filled 2D tantalum PhC emitter suitable for TPV applications such as combustion, radioisotope, and solar TPV. Dielectric filling improved the hemispherical performance without sacrificing stability or ease of fabrication. The numerical simulations, fabrication processes, and optical and thermal characterizations of the PhC are presented in this paper., U.S. Army Research Laboratory and the U.S. Army Research Office (Contract W911NF-13-D-0001)

Published
2021

17. Improved Omnidirectional 2D Photonic Crystal Selective Emitter for Thermophotovoltaics

Author

Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Physics, Sakakibara, Reyu, Stelmakh, Veronika, Chan, Walker R, Ghebrebrhan, Michael, Joannopoulos, John, Soljacic, Marin, Celanovic, Ivan L., Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Physics, Sakakibara, Reyu, Stelmakh, Veronika, Chan, Walker R, Ghebrebrhan, Michael, Joannopoulos, John, Soljacic, Marin, and Celanovic, Ivan L.

Abstract

Hafnia-filled, two dimensional (2D) tantalum (Ta) photonic crystals (PhCs) are promising emitters for high performance thermophotovoltaic (TPV) systems because they enable, for a wide range of incidence angles, efficient spectral tailoring of thermal radiation. However, fabricating these PhCs to the required tolerances has proven to be a challenging task. In this paper, we use both focused ion beam (FIB) imaging and simulations to investigate the effects of fabrication imperfections on the emittance of a fabricated hafnia-filled PhC and to identify critical geometric features that drive the overall PhC performance. We demonstrate that, more so than uniform cavity filling, the key to the best filled PhC performance is the precise cavity period and radius values and thickness of the top hafnia layer.

Published
2020

18. Banshee distribution network benchmark and prototyping platform for hardware‐in‐the‐loop integration of microgrid and device controllers

Author

Salcedo, Reynaldo, primary, Corbett, Edward, additional, Smith, Christopher, additional, Limpaecher, Erik, additional, Rekha, Raajiv, additional, Nowocin, John, additional, Lauss, Georg, additional, Fonkwe, Edwin, additional, Almeida, Murilo, additional, Gartner, Peter, additional, Manson, Scott, additional, Nayak, Bharath, additional, Celanovic, Ivan, additional, Dufour, Christian, additional, Faruque, M.Omar, additional, Schoder, Karl, additional, Brandl, Ron, additional, Kotsampopoulos, Panos, additional, Ham Ha, Thrung, additional, Davoudi, Ali, additional, Dehkordi, Ali, additional, and Strunz, Kai, additional

Published
2019
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19. Nanoengineered Surfaces for Thermal Energy Conversion

Author

Massachusetts Institute of Technology. Department of Physics, Bhatia, Bikram, Preston, Daniel John, Bierman, David Matthew, Miljkovic, Nenad, Lenert, Andrej, Enright, Ryan, Nam, Young Suk, Lopez, Ken, Dou, Nicholas G., Sack, Jean H., Chan, Walker R, Celanovic, Ivan L., Soljacic, Marin, Wang, Evelyn N, Massachusetts Institute of Technology. Department of Physics, Bhatia, Bikram, Preston, Daniel John, Bierman, David Matthew, Miljkovic, Nenad, Lenert, Andrej, Enright, Ryan, Nam, Young Suk, Lopez, Ken, Dou, Nicholas G., Sack, Jean H., Chan, Walker R, Celanovic, Ivan L., Soljacic, Marin, and Wang, Evelyn N

Abstract

We provide an overview of the impact of using nanostructured surfaces to improve the performance of solar thermophotovoltaic (STPV) energy conversion and condensation systems. We demonstrated STPV system efficiencies of up to 3.2%, compared to ≤1% reported in the literature, made possible by nanophotonic engineering of the absorber and emitter. For condensation systems, we showed enhanced performance by using scalable superhydrophobic nanostructures via jumping-droplet condensation. Furthermore, we observed that these jumping droplets carry a residual charge which causes the droplets to repel each other mid-flight. Based on this finding of droplet residual charge, we demonstrated electric-field-enhanced condensation and jumping-droplet electrostatic energy harvesting.

Published
2019

20. Towards a portable mesoscale thermophotovoltaic generator

Author

Massachusetts Institute of Technology. Department of Physics, Massachusetts Institute of Technology. Research Laboratory of Electronics, Chan, Walker R., Stelmakh, Veronika, Karnani, Sunny, Waits, Christopher M., Soljacic, Marin, Joannopoulos, John, Celanovic, Ivan, Massachusetts Institute of Technology. Department of Physics, Massachusetts Institute of Technology. Research Laboratory of Electronics, Chan, Walker R., Stelmakh, Veronika, Karnani, Sunny, Waits, Christopher M., Soljacic, Marin, Joannopoulos, John, and Celanovic, Ivan

Abstract

Thermophotovoltaics (TPV) is the conversion of fuel to electricity with heat and light as intermediaries, and is a promising source of high energy density power at the mesoscale. This work describes our transition from our bench-top experiments to a fully-integrated portable generator. Specifically, we redesigned the microcombustor for propane-air combustion from the previous propane-oxygen design. Next, we validated vacuum package of the microcombustor, necessary to preserve the photonic crystal, in a 50+ day experiment in which there was no degradation of vacuum level. Finally, we vacuum packaged a microcombustor with integrated photonic crystals in a housing with two infrared-transparent windows to transmit the thermal radiation to external PV cells. Although considerable challenges remain, this work demonstrates the feasibility of a mesoscale TPV system., United States. Army Research Office (Grant W911NF-13-D-0001)

Published
2019

21. An integrated microcombustor and photonic crystal emitter for thermophotovoltaics

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Physics, Massachusetts Institute of Technology. Research Laboratory of Electronics, Chan, Walker R., Stelmakh, Veronika, Allmon, William R., Waits, Christopher M., Soljacic, Marin, Joannopoulos, John, Celanovic, Ivan, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Physics, Massachusetts Institute of Technology. Research Laboratory of Electronics, Chan, Walker R., Stelmakh, Veronika, Allmon, William R., Waits, Christopher M., Soljacic, Marin, Joannopoulos, John, and Celanovic, Ivan

Abstract

Thermophotovoltaic (TPV) energy conversion is appealing for portable millimeter- scale generators because of its simplicity, but it relies on a high temperatures. The performance and reliability of the high-temperature components, a microcombustor and a photonic crystal emitter, has proven challenging because they are subjected to 1000-1200 C and stresses arising from thermal expansion mismatches. In this paper, we adopt the industrial process of diffusion brazing to fabricate an integrated microcombustor and photonic crystal by bonding stacked metal layers. Diffusion brazing is simpler and faster than previous approaches of silicon MEMS and welded metal, and the end result is more robust.

Published
2019

22. Nanoimprinted superlattice metallic photonic crystal as ultraselective solar absorber

Author

Rinnerbauer, V., Lausecker, E., Schäffler, F., Reininger, P., Strasser, G., Geil, R. D., Joannopoulos, John, Soljacic, Marin, Celanovic, Ivan L., Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Physics, Joannopoulos, John, Soljacic, Marin, and Celanovic, Ivan L.

Abstract

A two-dimensional superlattice metallic photonic crystal (PhC) and its fabrication by nanoimprint lithography on tantalum substrates are presented. The superior tailoring capacity of the superlattice PhC geometry is used to achieve spectrally selective solar absorption optimized for high-temperature and high-efficiency solar-energy-conversion applications. The scalable fabrication route by nanoimprint lithography allows for a high-throughput and high-resolution replication of this complex pattern over large areas. Despite the high fill factor, the pattern of polygonal cavities is accurately replicated into a resist that hardens under ultraviolet radiation over an area of 10 mm². In this way, cavities of 905 nm and 340 nm width are achieved with a period of 1 μm. After pattern transfer into tantalum via a deep reactive ion-etching process, the achieved cavities are 2.2 μm deep, separated by 85–95 nm wide ridges with vertical sidewalls. The room-temperature reflectance spectra of the fabricated samples show excellent agreement with simulated results, with a high spectral absorptance approaching blackbody absorption in the range from 300 to 1900 nm and a steep cutoff. The calculated solar absorptivity of this superlattice PhC is 96% and its thermal transfer efficiency is 82.8% at an operating temperature of 1500 K and an irradiance of 1000 kW/m²., United States. Army Research Office (W911NF-13-D-0001), United States. Department of Energy (DE-SC0001299)

Published
2015

25. A nanophotonic solar thermophotovoltaic device

Author

Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Mechanical Engineering, Massachusetts Institute of Technology. Department of Physics, Massachusetts Institute of Technology. Research Laboratory of Electronics, Wang, Evelyn N., Lenert, Andrej, Bierman, David Matthew, Nam, Youngsuk, Chan, Walker R., Soljacic, Marin, Celanovic, Ivan, Wang, Evelyn, Celanovic, Ivan L., Nam, Young Suk, Chan, Walker R, Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Mechanical Engineering, Massachusetts Institute of Technology. Department of Physics, Massachusetts Institute of Technology. Research Laboratory of Electronics, Wang, Evelyn N., Lenert, Andrej, Bierman, David Matthew, Nam, Youngsuk, Chan, Walker R., Soljacic, Marin, Celanovic, Ivan, Wang, Evelyn, Celanovic, Ivan L., Nam, Young Suk, and Chan, Walker R

Abstract

The most common approaches to generating power from sunlight are either photovoltaic, in which sunlight directly excites electron–hole pairs in a semiconductor, or solar–thermal, in which sunlight drives a mechanical heat engine. Photovoltaic power generation is intermittent and typically only exploits a portion of the solar spectrum efficiently, whereas the intrinsic irreversibilities of small heat engines make the solar–thermal approach best suited for utility-scale power plants. There is, therefore, an increasing need for hybrid technologies for solar power generation. By converting sunlight into thermal emission tuned to energies directly above the photovoltaic bandgap using a hot absorber–emitter, solar thermophotovoltaics promise to leverage the benefits of both approaches: high efficiency, by harnessing the entire solar spectrum; scalability and compactness, because of their solid-state nature; and dispatchablility, owing to the ability to store energy using thermal or chemical means. However, efficient collection of sunlight in the absorber and spectral control in the emitter are particularly challenging at high operating temperatures. This drawback has limited previous experimental demonstrations of this approach to conversion efficiencies around or below 1% (refs 9, 10, 11). Here, we report on a full solar thermophotovoltaic device, which, thanks to the nanophotonic properties of the absorber–emitter surface, reaches experimental efficiencies of 3.2%. The device integrates a multiwalled carbon nanotube absorber and a one-dimensional Si/SiO[subscript 2] photonic-crystal emitter on the same substrate, with the absorber–emitter areas optimized to tune the energy balance of the device. Our device is planar and compact and could become a viable option for high-performance solar thermophotovoltaic energy conversion., United States. Dept. of Energy. Office of Basic Energy Sciences (DE-FG02-09ER46577), Martin Family Society of Fellows for Sustainability, MIT Energy Initiative, National Science Foundation (U.S.). Graduate Research Fellowship, Korea (South). Ministry of Science, ICT and Future Planning (National Research Foundation of Korea. Basic Science Research Program 2012R1A1A1014845)

Published
2015

26. Tantalum-tungsten alloy photonic crystals for high-temperature energy conversion systems

Author

Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Physics, Stelmakh, Veronika, Chan, Walker R., Senkevich, Jay J., Joannopoulos, John D., Soljacic, Marin, Celanovic, Ivan, Rinnerbauer, Veronika, Chan, Walker R, Senkevich, Jay, Joannopoulos, John, Celanovic, Ivan L., Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Physics, Stelmakh, Veronika, Chan, Walker R., Senkevich, Jay J., Joannopoulos, John D., Soljacic, Marin, Celanovic, Ivan, Rinnerbauer, Veronika, Chan, Walker R, Senkevich, Jay, Joannopoulos, John, and Celanovic, Ivan L.

Abstract

A tantalum tungsten (Ta-W) solid solution alloy, Ta 3% W, based 2D photonic crystal (PhC) was designed and fabricated for high-temperature energy conversion applications. Metallic PhCs are promising as high performance selective thermal emitters for solid-state thermal-to-electricity energy conversion concepts including thermophotovoltaic (TPV) energy conversion, as well as highly selective solar absorbers/emitters for solar thermal and solar TPV applications due to the ability to tune their spectral properties and achieve highly selective emission. The mechanical and thermal stability of the substrate was characterized as well as the optical properties of the fabricated PhC. The Ta 3% W alloy presents advantages compared to the non-alloys as it combines the better high-temperature thermo-mechanical properties of W with the more compliant material properties of Ta, allowing for a direct system integration path of the PhC as selective emitter/absorber into a spectrum of energy conversion systems. Furthermore, the thermo-mechanical properties can be fine-tuned by the W content. A 2D PhC was designed to have high spectral selectivity matched to the bandgap of a TPV cell using numerical simulations and fabricated using standard semiconductor processes. The emittance of the Ta 3% W PhC was obtained from near-normal reflectance measurements at room temperature before and after annealing at 1200°C for 24h in vacuum with a protective coating of 40nm HfO2, showing high selectivity in agreement with simulations. SEM images of the cross section of the PhC prepared by FIB confirm the structural stability of the PhC after anneal, i.e. the coating effectively prevented structural degradation due to surface diffusion., Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies (Contract DAAD-19-02-D0002), Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies (Contract W911NF-07-D000), United States. Dept. of Energy. Office of Science (Solid-State Solar-Thermal Energy Conversion Center Grant DE-SC0001299)), Austrian Science Fund (J3161-N20)

Published
2015

27. Optical characteristics of one-dimensional Si/SiO2 photonic crystals for thermophotovoltaic applications.

Author

O'Sullivan, Francis, Celanovic, Ivan, Jovanovic, Natalija, Kassakian, John, Akiyama, Shoji, and Wada, Kazumi

Subjects
*PHOTOVOLTAIC power systems, *CRYSTALS, *PHOTONS, *PHOTOVOLTAIC power generation, *CRYSTALLOGRAPHY, *SOLAR power plants
Abstract

This article presents a detailed exploration of the optical characteristics of various one-dimensional photonic crystal structures designed for use as a means of improving the efficiency and power density of thermophotovoltaic (TPV) devices. The crystals being investigated have a ten-layer quarter-wave periodic structure, and are based on Si/SiO2 and Si/SiON material systems. For TPV applications the crystals are designed to act as filters, transmitting photons with wavelengths below 1.78 μm to a GaSb photodiode, while reflecting photons of longer wavelengths back to the source of thermal radiation. In the case of the Si/SiO2 structure, the Si and SiO2 layers were designed to be 170 and 390 nm thick, respectively. This structure was fabricated using low-pressure chemical vapor deposition. Reflectance and transmittance measurements of the fabricated Si/SiO2 photonic crystals were taken from 0.8 to 3.3 μm for both polarizations and for a range of incident angles. Measurement results were found to correlate well with simulation results for the ideal structure. Measurement results were used to predict the TPV system efficiency, power density and spectral efficiency using an ideal thermodynamic model of a TPV system. [ABSTRACT FROM AUTHOR]

Published
2005
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28. Resonant-cavity enhanced thermal emission

Author

Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Laboratory for Electromagnetic and Electronic Systems, Perreault, David J., Celanovic, Ivan, Kassakian, John G., Celanovic, Ivan L., Perreault, David J, Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Laboratory for Electromagnetic and Electronic Systems, Perreault, David J., Celanovic, Ivan, Kassakian, John G., Celanovic, Ivan L., and Perreault, David J

Abstract

In this paper we present a vertical-cavity enhanced resonant thermal emitter—a highly directional, narrow-band, tunable, partially coherent thermal source. This device enhances thermal emittance of a metallic or any other highly reflective structure to unity near a cavity resonant frequency. The structure consists of a planar metallic surface (e.g., silver, tungsten), a dielectric layer on top of the metal that forms a vertical cavity, followed by a multilayer dielectric stack acting as a partially transparent cavity mirror. The resonant frequency can easily be tuned by changing the cavity thickness (thus shifting resonant emission peak), while the angle at which the maximum emittance appears can be tuned as well by changing the number of dielectric stack layers. The thermal emission exhibits an extremely narrow angular emission lobe, suggesting increased spatial coherence. Furthermore, we show that we can enhance the thermal emission of an arbitrarily low-emittance material, choosing a properly designed thermal cavity, to near unity., MIT/Industry Consortium on Advanced Automotive Electrical/Electronic Components and Systems

Published
2014

29. High-Speed Real-Time Digital Emulation for Hardware-in-the-Loop Testing of Power Electronics: A New Paradigm in the Field of Electronic Design Automation (EDA) for Power Electronics Systems

Author

Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Lincoln Laboratory, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Kinsy, Michel A., Majstorovic, Dusan, Haessig, Pierre, Poon, Jason, Celanovic, Nikola, Celanovic, Ivan, Devadas, Srinivas, Celanovic, Ivan L., Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Lincoln Laboratory, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Kinsy, Michel A., Majstorovic, Dusan, Haessig, Pierre, Poon, Jason, Celanovic, Nikola, Celanovic, Ivan, Devadas, Srinivas, and Celanovic, Ivan L.

Abstract

This paper details the design and application of a new ultra-high speed real-time simulation for Hardware-in-the-Loop (HiL) testing and design of high-power power electronics systems. Our real-time hardware emulation for HiL system is based on a custom, heterogeneous, reconfigurable, multicore processor design that emulates power electronics, and includes a circuit compiler that translates graphic system models into processor executable machine code. We present digital processor architecture details, and describe the process of power electronic circuit compilation. This approach to real-time emulation yields real-time execution in the order of 1µs simulation time step (including input/output latency) for a broad class of power electronics converters. In addition, we present HiL simulation experimental results for three representative systems: namely, a variable speed induction motor drive, a utility grid connected photovoltaic converter system, and a hybrid electric vehicle motor drive.

Published
2014

30. Design and optimization of one-dimensional photonic crystals for thermophotovoltaic applications

Author

Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, MIT Energy Initiative, Perreault, David J., Celanovic, Ivan, O'Sullivan, Francis Martin, Ilak, Milos, Kassakian, John G., Perreault, David J, Celanovic, Ivan L., Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, MIT Energy Initiative, Perreault, David J., Celanovic, Ivan, O'Sullivan, Francis Martin, Ilak, Milos, Kassakian, John G., Perreault, David J, and Celanovic, Ivan L.

Abstract

We explore the optical characteristics and fundamental limitations of one-dimensional (1D) photonic crystal (PhC) structures as means for improving the efficiency and power density of thermophotovoltaic (TPV) and microthermophotovoltaic (MTPV) devices. We analyze the optical performance of 1D PhCs with respect to photovoltaic diode efficiency and power density. Furthermore, we present an optimized dielectric stack design that exhibits a significantly wider stop band and yields better TPV system efficiency than a simple quarter-wave stack. The analysis is done for both TPV and MTPV devices by use of a unified modeling framework., MIT/Industry Consortium on Advanced Automotive Electrical/Electronic Components and Systems

Published
2014

31. Recent developments in high-temperature photonic crystals for energy conversion

Author

Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Physics, Massachusetts Institute of Technology. Research Laboratory of Electronics, Soljacic , Marin, Rinnerbauer, Veronika, Ndao, Sidy, Yeng, YiXiang, Chan, Walker R., Senkevich, Jay, Joannopoulos, John D., Soljacic, Marin, Celanovic, Ivan, Chan, Walker R, Joannopoulos, John, Celanovic, Ivan L., Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Physics, Massachusetts Institute of Technology. Research Laboratory of Electronics, Soljacic , Marin, Rinnerbauer, Veronika, Ndao, Sidy, Yeng, YiXiang, Chan, Walker R., Senkevich, Jay, Joannopoulos, John D., Soljacic, Marin, Celanovic, Ivan, Chan, Walker R, Joannopoulos, John, and Celanovic, Ivan L.

Abstract

After decades of intense studies focused on cryogenic and room temperature nanophotonics, scientific interest is also growing in high-temperature nanophotonics aimed at solid-state energy conversion. These latest extensive research efforts are spurred by a renewed interest in high temperature thermal-to-electrical energy conversion schemes including thermophotovoltaics (TPV), solar–thermophotovoltaics, solar–thermal, and solar–thermochemical energy conversion systems. This field is profiting tremendously from the outstanding degree of control over the thermal emission properties that can be achieved with nanoscale photonic materials. The key to obtaining high efficiency in this class of high temperature energy conversion is the spectral and angular matching of the radiation properties of an emitter to those of an absorber. Together with the achievements in the field of high-performance narrow bandgap photovoltaic cells, the ability to tailor the radiation properties of thermal emitters and absorbers using nanophotonics facilitates a route to achieving the impressive efficiencies predicted by theoretical studies. In this review, we will discuss the possibilities of emission tailoring by nanophotonics in the light of high temperature thermal-to-electrical energy conversion applications, and give a brief introduction to the field of TPV. We will show how a class of large area 2D metallic photonic crystals can be designed and employed to efficiently control and tailor the spectral and angular emission properties, paving the way towards new and highly efficient thermophotovoltaic systems and enabling other energy conversion schemes based on high-performance high-temperature nanoscale photonic materials., United States. Dept. of Energy (Solid-State Solar-Thermal Energy Conversion Center Grant DE-SC0001299), United States. Army Research Office (Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies Contract DAAD-19-02-D0002), United States. Army Research Office (Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies Contract W911NF-07-D000)

Published
2013

32. Overcoming the black body limit in plasmonic and graphene near-field thermophotovoltaic systems

Author

Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Physics, Ilic, Ognjen, Joannopoulos, John D., Celanovic, Ivan, Soljacic, Marin, Jablan, Marinko, Joannopoulos, John, Celanovic, Ivan L., Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Physics, Ilic, Ognjen, Joannopoulos, John D., Celanovic, Ivan, Soljacic, Marin, Jablan, Marinko, Joannopoulos, John, and Celanovic, Ivan L.

Abstract

Near-field thermophotovoltaic (TPV) systems with carefully tailored emitter-PV properties show large promise for a new temperature range (600 – 1200K) solid state energy conversion, where conventional thermoelectric (TE) devices cannot operate due to high temperatures and far-field TPV schemes suffer from low efficiency and power density. We present a detailed theoretical study of several different implementations of thermal emitters using plasmonic materials and graphene. We find that optimal improvements over the black body limit are achieved for low bandgap semiconductors and properly matched plasmonic frequencies. For a pure plasmonic emitter, theoretically predicted generated power density of 14[W over cm[superscript 2]] and efficiency of 36% can be achieved at 600K (hot-side), for 0.17eV bandgap (InSb). Developing insightful approximations, we argue that large plasmonic losses can, contrary to intuition, be helpful in enhancing the overall near-field transfer. We discuss and quantify the properties of an optimal near-field photovoltaic (PV) diode. In addition, we study plasmons in graphene and show that doping can be used to tune the plasmonic dispersion relation to match the PV cell bangap. In case of graphene, theoretically predicted generated power density of 6(120)[W over cm[superscript 2]] and efficiency of 35(40)% can be achieved at 600(1200)K, for 0.17eV bandgap. With the ability to operate in intermediate temperature range, as well as high efficiency and power density, near-field TPV systems have the potential to complement conventional TE and TPV solid state heat-to-electricity conversion devices.

Published
2013

33. Design and global optimization of high-efficiency solar thermal systems with tungsten cermets

Author

Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, MIT Materials Research Laboratory, Massachusetts Institute of Technology. Department of Physics, Massachusetts Institute of Technology. Research Laboratory of Electronics, Chester, David A., Bermel, Peter A., Joannopoulos, John D., Soljacic, Marin, Celanovic, Ivan, Joannopoulos, John, Celanovic, Ivan L., Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, MIT Materials Research Laboratory, Massachusetts Institute of Technology. Department of Physics, Massachusetts Institute of Technology. Research Laboratory of Electronics, Chester, David A., Bermel, Peter A., Joannopoulos, John D., Soljacic, Marin, Celanovic, Ivan, Joannopoulos, John, and Celanovic, Ivan L.

Abstract

Solar thermal, thermoelectric, and thermophotovoltaic (TPV) systems have high maximum theoretical efficiencies; experimental systems fall short because of losses by selective solar absorbers and TPV selective emitters. To improve these critical components, we study a class of materials known as cermets. While our approach is completely general, the most promising cermet candidate combines nanoparticles of silica and tungsten. We find that 4-layer silica-tungsten cermet selective solar absorbers can achieve thermal transfer efficiencies of 84.3% at 400 K, and 75.59% at 1000 K, exceeding comparable literature values. Three layer silica-tungsten cermets can also be used as selective emitters for InGaAsSb-based thermophotovoltaic systems, with projected overall system energy conversion efficiencies of 10.66% at 1000 K using realistic design parameters. The marginal benefit of adding more than 4 cermet layers is small (less than 0.26%, relative)., National Science Foundation (U.S.). Materials Research Science and Engineering Centers (Program) (Award DMR-0819762), United States. Dept. of Energy. Office of Science (Grant DE-SC0001299), Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies (Contract DAAD-19-02-D0002), Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies (Contract W911NF-07-D0004)

Published
2013

35. Frequency-Selective Near-Field Radiative Heat Transfer between Photonic Crystal Slabs: A Computational Approach for Arbitrary Geometries and Materials

Author

Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Mathematics, Massachusetts Institute of Technology. Department of Physics, Johnson, Steven G., Rodriguez-Wong, Alejandro, Ilic, Ognjen, Bermel, Peter A., Celanovic, Ivan, Joannopoulos, John D., Soljacic, Marin, Celanovic, Ivan L., Joannopoulos, John, Johnson, Steven G, Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Mathematics, Massachusetts Institute of Technology. Department of Physics, Johnson, Steven G., Rodriguez-Wong, Alejandro, Ilic, Ognjen, Bermel, Peter A., Celanovic, Ivan, Joannopoulos, John D., Soljacic, Marin, Celanovic, Ivan L., Joannopoulos, John, and Johnson, Steven G

Abstract

We demonstrate the possibility of achieving enhanced frequency-selective near-field radiative heat transfer between patterned (photonic-crystal) slabs at designable frequencies and separations, exploiting a general numerical approach for computing heat transfer in arbitrary geometries and materials based on the finite-difference time-domain method. Our simulations reveal a tradeoff between selectivity and near-field enhancement as the slab-slab separation decreases, with the patterned heat transfer eventually reducing to the unpatterned result multiplied by a fill factor (described by a standard proximity approximation). We also find that heat transfer can be further enhanced at selective frequencies when the slabs are brought into a glide-symmetric configuration, a consequence of the degeneracies associated with the nonsymmorphic symmetry group., United States. Defense Advanced Research Projects Agency (Contract No. N66001-09-1-2070-DOD), Solid-State Solar-Thermal Energy Conversion Center, United States. Dept. of Energy. Office of Basic Energy Sciences (Grant No. DE-SC0001299), United States. Army Research Office (Contract No. W911NF-07-D-0004), United States. Army Research Office. Institute for Soldier Nanotechnologies

Published
2012

36. Enabling high-temperature nanophotonics for energy applications

Author

Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Materials Science and Engineering, Massachusetts Institute of Technology. Department of Physics, Massachusetts Institute of Technology. Research Laboratory of Electronics, Celanovic, Ivan L., Yeng, YiXiang, Ghebrebrhan, Michael, Bermel, Peter A., Chan, Walker R., Joannopoulos, John D., Soljacic, Marin, Celanovic, Ivan, Chan, Walker R, Joannopoulos, John, Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Materials Science and Engineering, Massachusetts Institute of Technology. Department of Physics, Massachusetts Institute of Technology. Research Laboratory of Electronics, Celanovic, Ivan L., Yeng, YiXiang, Ghebrebrhan, Michael, Bermel, Peter A., Chan, Walker R., Joannopoulos, John D., Soljacic, Marin, Celanovic, Ivan, Chan, Walker R, and Joannopoulos, John

Abstract

The nascent field of high-temperature nanophotonics could potentially enable many important solid-state energy conversion applications, such as thermophotovoltaic energy generation, selective solar absorption, and selective emission of light. However, special challenges arise when trying to design nanophotonic materials with precisely tailored optical properties that can operate at high-temperatures (> 1,100 K). These include proper material selection and purity to prevent melting, evaporation, or chemical reactions; severe minimization of any material interfaces to prevent thermomechanical problems such as delamination; robust performance in the presence of surface diffusion; and long-range geometric precision over large areas with severe minimization of very small feature sizes to maintain structural stability. Here we report an approach for high-temperature nanophotonics that surmounts all of these difficulties. It consists of an analytical and computationally guided design involving high-purity tungsten in a precisely fabricated photonic crystal slab geometry (specifically chosen to eliminate interfaces arising from layer-by-layer fabrication) optimized for high performance and robustness in the presence of roughness, fabrication errors, and surface diffusion. It offers near-ultimate short-wavelength emittance and low, ultra-broadband long-wavelength emittance, along with a sharp cutoff offering 4∶1 emittance contrast over 10% wavelength separation. This is achieved via Q-matching, whereby the absorptive and radiative rates of the photonic crystal’s cavity resonances are matched. Strong angular emission selectivity is also observed, with short-wavelength emission suppressed by 50% at 75° compared to normal incidence. Finally, a precise high-temperature measurement technique is developed to confirm that emission at 1,225 K can be primarily confined to wavelengths shorter than the cutoff wavelength., TeraGrid (Grant Number TG-MCA94P014), Solid-State Solar-Thermal Energy Conversion Center (Grant number DE-SC0001299), United States. Army Research Office. Institute for Soldier Nanotechnologies (Contract DAAD-19-02- D0002), United States. Army Research Office. Institute for Soldier Nanotechnologies (Contract W911NF-07-D0004)

Published
2012

37. Photonic crystals: shaping the flow of thermal radiation

Author

Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Physics, Kassakian, John, Celanovic, Ivan, Ghebrebrhan, Michael, Yeng, YiXiang, Kassakian, John G., Soljacic, Marin, Joannopoulos, John D., Celanovic, Ivan L., Joannopoulos, John, Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Physics, Kassakian, John, Celanovic, Ivan, Ghebrebrhan, Michael, Yeng, YiXiang, Kassakian, John G., Soljacic, Marin, Joannopoulos, John D., Celanovic, Ivan L., and Joannopoulos, John

Abstract

In this paper we explore theory, design, and fabrication of photonic crystal (PhC) based selective thermal emitters. In particular, we focus on tailoring spectral and spatial properties by means of resonant enhancement in PhC’s. Firstly, we explore narrow-band resonant thermal emission in photonic crystals exhibiting strong spectral and directional selectivity. We demonstrate two interesting designs based on resonant Q-matching: a vertical cavity enhanced resonant thermal emitter and 2D silicon PhC slab Fano-resonance based thermal emitter. Secondly, we examine the design of 2D tungsten PhC as a broad-band selective emitter. Indeed, based on the resonant cavity coupled resonant modes we demonstrate a highly selective, highly-spectrally efficient thermal emitter. We show that an emitter with a photonic cut-off anywhere from 1.8 mm to 2.5 mm can be designed., United States. Army Research Office (Institute for Soldier Nanotechnologies)

Published
2012

38. Angular photonic band gap

Author

MIT Materials Research Laboratory, Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Physics, Massachusetts Institute of Technology. Research Laboratory of Electronics, Soljacic, Marin, Hamam, Rafif E., Celanovic, Ivan, Celanovic, Ivan L., MIT Materials Research Laboratory, Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Physics, Massachusetts Institute of Technology. Research Laboratory of Electronics, Soljacic, Marin, Hamam, Rafif E., Celanovic, Ivan, and Celanovic, Ivan L.

Abstract

We present detailed numerical simulations of a class of material systems that strongly discriminate light based primarily on the angle of incidence, over a broad range of frequencies, and independent of the polarization. Unique properties of these systems emerge from exploring photonic crystals whose constituents have an anisotropic dielectric response., National Science Foundation (U.S.). Materials Research Science and Engineering Centers (Program) (Grant no. DMR-0819762), United States. Dept. of Energy. Office of Basic Energy Sciences (S3TEC grant no. DE-SC0001299), Massachusetts Institute of Technology. Energy Initiative

Published
2011

39. Tailoring thermal emission via Q matching of photonic crystal resonances

Author

Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Physics, Massachusetts Institute of Technology. Research Laboratory of Electronics, Joannopoulos, John D., Ghebrebrhan, Michael, Bermel, Peter A., Yeng, YiXiang, Celanovic, Ivan, Soljacic, Marin, Celanovic, Ivan L., Joannopoulos, John, Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Physics, Massachusetts Institute of Technology. Research Laboratory of Electronics, Joannopoulos, John D., Ghebrebrhan, Michael, Bermel, Peter A., Yeng, YiXiang, Celanovic, Ivan, Soljacic, Marin, Celanovic, Ivan L., and Joannopoulos, John

Abstract

We develop a model for predicting the thermal emission spectrum of a two-dimensional metallic photonic crystal for arbitrary angles based on coupled-mode theory. Calculating the appropriate coupled-mode parameters over a range of geometrical parameters allows one to tailor the emissivity spectrum to a specific application. As an example, we design an emitter with a step-function cutoff suppressing long-wavelength emission, which is necessary for high-efficiency thermophotovoltaic systems. We also confirm the accuracy of the results of our model with finite-difference time-domain simulations., National Science Foundation (U.S.). Materials Research Science and Engineering Center Program (grant DMR 0819762), United States. Dept. of Energy. MIT S3TEC Energy Research Frontier Center (grant DESC0001299), United States. Army Research Office (Institute for Soldier Nanotechnologies) (contract DAAD-19-02-D0002)

Published
2011

40. Low-Power Maximum Power Point Tracker with Digital Control for Thermophotovoltaic Generators

Author

Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Perreault, David J., Pilawa, Robert, Pallo, Nathan A., Chan, Walker R., Celanovic, Ivan, Pilawa-Podgurski, Robert C. N., Chan, Walker R, Perreault, David J, Celanovic, Ivan L., Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Perreault, David J., Pilawa, Robert, Pallo, Nathan A., Chan, Walker R., Celanovic, Ivan, Pilawa-Podgurski, Robert C. N., Chan, Walker R, Perreault, David J, and Celanovic, Ivan L.

Abstract

This paper describes the design, optimization, and evaluation of the power electronics circuitry for a low-power portable thermophotovotaic (TPV) generator system. TPV system is based on a silicon micro-reactor design and low-bandgap photovoltaic (PV) diodes. We outline critical system-level challenges associated with TPV power generation, and propose a power electronics architecture that addresses these challenges. We present experimental data from a compact, highly efficient peak power tracker and show how the proposed architecture enables increased energy extraction compared to conventional methods. The operation of the power tracker is verified with low-bandgap PV cells illuminated by a quartz halogen lamp producing a PV diode output power of 0.5 W, and above 99% tracking efficiency is demonstrated. Additionally, the complete system operation is verified with the power tracker connected to GaInAsSb PV diodes and a silicon micro-reactor, producing 150 mW of electrical power., United States. Army Research Office, Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies

Published
2011

41. Improved Thermal Emitters for Thermophotovoltaic Energy Conversion

Author

Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Physics, Stelmakh, Veronika, Chan, Walker R, Joannopoulos, John, Soljacic, Marin, Celanovic, Ivan L., Sablon, Kimberly, Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Physics, Stelmakh, Veronika, Chan, Walker R, Joannopoulos, John, Soljacic, Marin, Celanovic, Ivan L., and Sablon, Kimberly

Abstract

Thermophotovoltaic (TPV) energy conversion enables millimeter scale power generation required for portable microelectronics, robotics, etc. In a TPV system, a heat source heats a selective emitter to incandescence, the radiation from which is incident on a low bandgap TPV cell. The selective emitter tailors the photonic density of states to produce spectrally confined selective emission of light matching the bandgap of the photovoltaic cell, enabling high heat-to-electricity conversion efficiency. The selective emitter requires: thermal stability at high-temperatures for long operational lifetimes, simple and relatively low-cost fabrication, as well as spectrally selective emission over a large uniform area. Generally, the selective emission can either originate from the natural material properties, such as in ytterbia or erbia emitters, or can be engineered through microstructuring. Our approach, the 2D photonic crystal fabricated in refractory metals, offers high spectral selectivity and high-temperature stability while being fabricated by standard semiconductor processes. In this work, we present a brief comparison of TPV system efficiencies using these different emitter technologies. We then focus on the design, fabrication, and characterization of our current 2D photonic crystal, which is a square lattice of cylindrical holes fabricated in a refractory metal substrate. The spectral performance and thermal stability of the fabricated photonic crystal thermal emitters are demonstrated and the efficiency gain of our model TPV system is characterized.

Published
2017

42. Photonic Crystal Enabled Thermophotovoltaics for a Portable Microgenerator

Author

Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Physics, Chan, Walker R, Stelmakh, Veronika, Soljacic, Marin, Joannopoulos, John, Celanovic, Ivan L., Waits, Christopher M, Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Physics, Chan, Walker R, Stelmakh, Veronika, Soljacic, Marin, Joannopoulos, John, Celanovic, Ivan L., and Waits, Christopher M

Abstract

This work presents the design and characterization of a first-of-a-kind millimeter- scale thermophotovoltaic (TPV) system using a metallic microburner, photonic crystal emitter, and low-bandgap photovoltaic (PV) cells. In our TPV system, combustion heats the emitter to incandescence and the resulting thermal radiation is converted to electricity by the low bandgap PV cells. Our motivation is to harness the high specific energy of hydrocarbon fuels at the micro- and millimeter-scale in order to meet the increasing power demands of micro robotics and portable electronics. Our experimental demonstration lays the groundwork for developing a TPV microgenerator as a viable battery replacement., United States. Dept. of Energy. Office of Basic Energy Sciences (DE-SC0001299), United States. Dept. of Energy. Office of Basic Energy Sciences (DE-FG02-09ER4657), Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies (contract W911NF-13-D-0001)

Published
2017

43. A Thermophotovoltaic System Using a Photonic Crystal Emitter

Author

Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Physics, Chan, Walker R, Stelmakh, Veronika, Soljacic, Marin, Joannopoulos, John, Celanovic, Ivan L., Waits, Christopher M., Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Physics, Chan, Walker R, Stelmakh, Veronika, Soljacic, Marin, Joannopoulos, John, Celanovic, Ivan L., and Waits, Christopher M.

Abstract

The increasing power demands of portable electronics and micro robotics has driven recent interest in millimeter-scale microgenerators. Many technologies (fuel cells, Stirling, thermoelectric, etc.) that potentially enable a portable hydrocarbon microgenerator are under active investigation. Hydrocarbon fuels have specific energies fifty times those of batteries, thus even a relatively inefficient generator can exceed the specific energy of batteries. We proposed, designed, and demonstrated a first-of-a-kind millimeter-scale thermophotovoltaic (TPV) system with a photonic crystal emitter. In a TPV system, combustion heats an emitter to incandescence and the resulting thermal radiation is converted to electricity by photovoltaic cells. Our approach uses a moderate temperature (1000–1200°C) metallic microburner coupled to a high emissivity, high selectivity photonic crystal selective emitter and low bandgap PV cells. This approach is predicted to be capable of up to 30% efficient fuel-to-electricity conversion within a millimeter-scale form factor. We have performed a robust experimental demonstration that validates the theoretical framework and the key system components, and present our results in the context of a TPV microgenerator. Although considerable technological barriers need to be overcome to realize a TPV microgenerator, we predict that 700–900 Wh/kg is possible with the current technology., Micro Autonomous Consortium Systems and Technology (Contract 892730), Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies (W911NF-13-D- 0001)

Published
2017

44. Prototype of radioisotope thermophotovoltaic system using photonic crystal spectral control

Author

Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Physics, Wang, X., Chan, Walker R, Stelmakh, Veronika, Soljacic, Marin, Joannopoulos, John, Celanovic, Ivan L., Fisher, Peter H, Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Physics, Wang, X., Chan, Walker R, Stelmakh, Veronika, Soljacic, Marin, Joannopoulos, John, Celanovic, Ivan L., and Fisher, Peter H

Abstract

This work describes a prototype of a small-size radioisotope thermophotovoltaic (RTPV) system with the two-dimensional metallic photonic crystal emitter and the low bandgap TPV cell. The project demonstrates the simulation and measurement of a system powered by an electrical heat source that mimics the radioisotope fuel pellet. The photonic crystal and the polished Ta3%W substrate are both used as the emitting surfaces to demonstrate the benefits of spectral control. The rest of the system is thermally insulated to increase the overall system efficiency. The photonic crystal emitter demonstrates four times more output power over a flat metal emitter from the 1 cm[superscript 2] TPV cell. With more cell areas, better TPV cells and improved insulation design, the system is expected to reach an efficiency of 7.8%.

Published
2017

45. Roadmap on optical energy conversion

Author

Massachusetts Institute of Technology. Department of Mechanical Engineering, Boriskina, Svetlana V, Chen, Gang, Green, Martin A, Catchpole, Kylie, Yablonovitch, Eli, Beard, Matthew C, Okada, Yoshitaka, Lany, Stephan, Gershon, Talia, Zakutayev, Andriy, Tahersima, Mohammad H, Sorger, Volker J, Naughton, Michael J, Kempa, Krzysztof, Dagenais, Mario, Yao, Yuan, Xu, Lu, Sheng, Xing, Bronstein, Noah D, Rogers, John A, Alivisatos, A Paul, Nuzzo, Ralph G, Gordon, Jeffrey M, Wu, Di M, Wisser, Michael D, Salleo, Alberto, Dionne, Jennifer, Bermel, Peter, Greffet, Jean-Jacques, Celanovic, Ivan, Soljacic, Marin, Manor, Assaf, Rotschild, Carmel, Raman, Aaswath, Zhu, Linxiao, Fan, Shanhui, Massachusetts Institute of Technology. Department of Mechanical Engineering, Boriskina, Svetlana V, Chen, Gang, Green, Martin A, Catchpole, Kylie, Yablonovitch, Eli, Beard, Matthew C, Okada, Yoshitaka, Lany, Stephan, Gershon, Talia, Zakutayev, Andriy, Tahersima, Mohammad H, Sorger, Volker J, Naughton, Michael J, Kempa, Krzysztof, Dagenais, Mario, Yao, Yuan, Xu, Lu, Sheng, Xing, Bronstein, Noah D, Rogers, John A, Alivisatos, A Paul, Nuzzo, Ralph G, Gordon, Jeffrey M, Wu, Di M, Wisser, Michael D, Salleo, Alberto, Dionne, Jennifer, Bermel, Peter, Greffet, Jean-Jacques, Celanovic, Ivan, Soljacic, Marin, Manor, Assaf, Rotschild, Carmel, Raman, Aaswath, Zhu, Linxiao, and Fan, Shanhui

Abstract

For decades, progress in the field of optical (including solar) energy conversion was dominated by advances in the conventional concentrating optics and materials design. In recent years, however, conceptual and technological breakthroughs in the fields of nanophotonics and plasmonics combined with a better understanding of the thermodynamics of the photon energy-conversion processes reshaped the landscape of energy-conversion schemes and devices. Nanostructured devices and materials that make use of size quantization effects to manipulate photon density of states offer a way to overcome the conventional light absorption limits. Novel optical spectrum splitting and photon-recycling schemes reduce the entropy production in the optical energy-conversion platforms and boost their efficiencies. Optical design concepts are rapidly expanding into the infrared energy band, offering new approaches to harvest waste heat, to reduce the thermal emission losses, and to achieve noncontact radiative cooling of solar cells as well as of optical and electronic circuitries. Light–matter interaction enabled by nanophotonics and plasmonics underlie the performance of the third- and fourth-generation energy-conversion devices, including up- and down-conversion of photon energy, near-field radiative energy transfer, and hot electron generation and harvesting. Finally, the increased market penetration of alternative solar energy-conversion technologies amplifies the role of cost-driven and environmental considerations. This roadmap on optical energy conversion provides a snapshot of the state of the art in optical energy conversion, remaining challenges, and most promising approaches to address these challenges. Leading experts authored 19 focused short sections of the roadmap where they share their vision on a specific aspect of this burgeoning research field. The roadmap opens up with a tutorial section, which introduces major concepts and terminology. It is our hope that the roadmap w, United States. Department of Energy (DE-AC36-086038308)

Published
2017

46. Tailoring high-temperature radiation and the resurrection of the incandescent source

Author

Massachusetts Institute of Technology. Department of Mechanical Engineering, Massachusetts Institute of Technology. Research Laboratory of Electronics, Ilic, Ognjen, Chen, Gang, Joannopoulos, John, Celanovic, Ivan L., Soljacic, Marin, Bermel, Peter, Massachusetts Institute of Technology. Department of Mechanical Engineering, Massachusetts Institute of Technology. Research Laboratory of Electronics, Ilic, Ognjen, Chen, Gang, Joannopoulos, John, Celanovic, Ivan L., Soljacic, Marin, and Bermel, Peter

Abstract

In solar cells, the mismatch between the Sun's emission spectrum and the cells’ absorption profile limits the efficiency of such devices, while in incandescent light bulbs, most of the energy is lost as heat. One way to avoid the waste of a large fraction of the radiation emitted from hot objects is to tailor the thermal emission spectrum according to the desired application. This strategy has been successfully applied to photonic-crystal emitters at moderate temperatures but is exceedingly difficult for hot emitters (>1,000 K). Here, we show that a plain incandescent tungsten filament (3,000 K) surrounded by a cold-side nanophotonic interference system optimized to reflect infrared light and transmit visible light for a wide range of angles could become a light source that reaches luminous efficiencies (∼40%) surpassing existing lighting technologies, and nearing a limit for lighting applications. We experimentally demonstrate a proof-of-principle incandescent emitter with efficiency approaching that of commercial fluorescent or light-emitting diode bulbs, but with exceptional reproduction of colours and scalable power. The ability to tailor the emission spectrum of high-temperature sources may find applications in thermophotovoltaic energy conversion and lighting., United States. Army Research Office (W911NF-13-D-0001), United States. Dept. of Energy. Office of Basic Energy Sciences (DE-SC0001299), United States. Dept. of Energy. Office of Basic Energy Sciences (DE-FG02-09ER46577)

Published
2017

47. High-speed real-time digital emulation for hardware-in-the-loop testing of power electronics: A new paradigm in the field of electronic design automation (EDA) for power electronics systems

Author

Kinsy, Michel A., Majstorovic, Dusan, Haessig, Pierre, Poon, Jason, Celanovic, Nikola, Celanovic, Ivan, Devadas, Srinivas, Haessig, Pierre, Computer Science and Artificial Intelligence Laboratory [Cambridge] (CSAIL), Massachusetts Institute of Technology (MIT), Faculty of Technical Sciences [Novi Sad], University of Novi Sad, Systèmes d'Energie pour les Transports et l'Environnement (SATIE SETE), Composants et Systèmes pour l'Energie Electrique (CSEE), Systèmes et Applications des Technologies de l'Information et de l'Energie (SATIE), École normale supérieure - Cachan (ENS Cachan)-Université Paris-Sud - Paris 11 (UP11)-Institut Français des Sciences et Technologies des Transports, de l'Aménagement et des Réseaux (IFSTTAR)-École normale supérieure - Rennes (ENS Rennes)-Université de Cergy Pontoise (UCP), Université Paris-Seine-Université Paris-Seine-Conservatoire National des Arts et Métiers [CNAM] (CNAM)-Centre National de la Recherche Scientifique (CNRS)-École normale supérieure - Cachan (ENS Cachan)-Université Paris-Sud - Paris 11 (UP11)-Institut Français des Sciences et Technologies des Transports, de l'Aménagement et des Réseaux (IFSTTAR)-École normale supérieure - Rennes (ENS Rennes)-Université de Cergy Pontoise (UCP), Université Paris-Seine-Université Paris-Seine-Conservatoire National des Arts et Métiers [CNAM] (CNAM)-Centre National de la Recherche Scientifique (CNRS)-Systèmes et Applications des Technologies de l'Information et de l'Energie (SATIE), Université Paris-Seine-Université Paris-Seine-Conservatoire National des Arts et Métiers [CNAM] (CNAM)-Centre National de la Recherche Scientifique (CNRS), Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Lincoln Laboratory, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Kinsy, Michel A., Majstorovic, Dusan, Poon, Jason, Celanovic, Nikola, Celanovic, Ivan, and Devadas, Srinivas

Subjects
power electronics, [SPI.NRJ]Engineering Sciences [physics]/Electric power, Hardware In the Loop, [SPI.NRJ] Engineering Sciences [physics]/Electric power
Abstract

This paper details the design and application of a new ultra-high speed real-time simulation for Hardware-in-the-Loop (HiL) testing and design of high-power power electronics systems. Our real-time hardware emulation for HiL system is based on a custom, heterogeneous, reconfigurable, multicore processor design that emulates power electronics, and includes a circuit compiler that translates graphic system models into processor executable machine code. We present digital processor architecture details, and describe the process of power electronic circuit compilation. This approach to real-time emulation yields real-time execution in the order of 1µs simulation time step (including input/output latency) for a broad class of power electronics converters. In addition, we present HiL simulation experimental results for three representative systems: namely, a variable speed induction motor drive, a utility grid connected photovoltaic converter system, and a hybrid electric vehicle motor drive.

Published
2011

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