Your search keyword '"Geisz, John F."' showing total 21 results

1. Sub‐0.6 eV Inverted Metamorphic GaInAs Cells Grown on Inp and GaAs Substrates for Thermophotovoltaics and Laser Power Conversion.

Author

Schulte, Kevin L., Friedman, Daniel J., Dada, Titilope, Guthrey, Harvey L., Costa, Edgard W., Tervo, Eric J., France, Ryan M., Geisz, John F., and Steiner, Myles A.

Subjects

SOLAR cells, METAL organic chemical vapor deposition, AUDITING standards, GALLIUM arsenide, REFLECTANCE measurement, LASERS

Abstract

Inverted metamorphic Ga0.3In0.7As photovoltaic converters with sub‐0.60 eV bandgaps grown on InP and GaAs are presented. Threading dislocation densities are 1.3 ± 0.6 × 106 and 8.9 ± 1.7 × 106 cm−2 on InP and GaAs, respectively. The devices generate open‐circuit voltages of 0.386 and 0.383 V, respectively, under irradiance producing a short‐circuit current density of ≈10 A cm−2, yielding bandgap‐voltage offsets of 0.20 and 0.21 V. Power and broadband reflectance measurements are used to estimate thermophotovoltaic (TPV) efficiency. The InP‐based cell is estimated to yield 1.09 W cm−2 at 1100 °C versus 0.92 W cm−2 for the GaAs‐based cell, with efficiencies of 16.8 versus 9.2%. The efficiencies of both devices are limited by sub‐bandgap absorption, with power weighted sub‐bandgap reflectances of 81% and 58%, respectively, the majority of which is assumed to occur in the graded buffers. The 1100 °C TPV efficiencies are estimated to increase to 24.0% and 20.7% in structures with the graded buffer removed, if previously demonstrated reflectance is achieved. These devices also have application to laser power conversion in the 2.0–2.3 µm atmospheric window. Peak laser power converter efficiencies of 36.8% and 32.5% are estimated under 2.0 µm irradiances of 1.86 and 2.81 W cm−2, respectively. [ABSTRACT FROM AUTHOR]

Published

2024

2. Spectral Effects on the Energy Harvesting Efficiency of Two‐ and Four‐Terminal Tandem Photovoltaics.

Author

Witteck, Robert, Geisz, John F., Warren, Emily L., and McMahon, William E.

Subjects

ENERGY consumption, PHOTOVOLTAIC power systems, PHOTOVOLTAIC power generation, ENERGY harvesting, SPECTRAL irradiance, SOLAR cells, GALLIUM arsenide

Abstract

In this work, the effect of a varying spectral irradiance and top cell bandgap on the energy harvesting efficiency of two‐terminal (2T) and four‐terminal (4T) perovskite//silicon tandem solar cells under outdoor operating conditions is investigated. For the comparison, an optoelectronic model employing a 1 year outdoor data set for a 4T mechanical stacked gallium arsenide (GaAs) on crystalline silicon (Si) tandem device is first validated. Then, the verified model is used to simulate perovskite//silicon tandem devices with a varying perovskite top cell bandgap for a location in Golden, Colorado, USA. A spectral binning method to efficiently reduce and improve the visualization of the 1 min‐resolved environmental data while maintaining the simulation accuracy is introduced. The findings reveal that, for a device that is current matched under standard testing conditions, the annual spectral deviation reduces the energy harvesting efficiency by only 2%rel. When additional realistic losses for the 4T are taken into account, 2T devices are shown to have an energy‐harvesting efficiency that is at parity or higher. Deviations in the top cell bandgap are more than 0.1 eV from current matching result in a reduced energy harvesting efficiency of more than 5%rel for the 2T tandem device. [ABSTRACT FROM AUTHOR]

Published

2024

3. Multi-junction solar cells paving the way for super high-efficiency.

Author

Yamaguchi, Masafumi, Dimroth, Frank, Geisz, John F., and Ekins-Daukes, Nicholas J.

Subjects

SOLAR cells, PHOTOVOLTAIC power systems, SOLAR cell efficiency, SOLAR spectra, CLEAN energy, SEMICONDUCTOR materials, ECONOMIC competition

Abstract

In order to realize a clean energy society by using renewable energies, high-performance solar cells are a very attractive proposition. The development of high-performance solar cells offers a promising pathway toward achieving high power per unit cost for many applications. As state-of-the-art of single-junction solar cells are approaching the Shockley–Queisser limit of 32%–33%, an important strategy to raise the efficiency of solar cells further is stacking solar cell materials with different bandgaps to absorb different colors of the solar spectrum. The III–V semiconductor materials provide a relatively convenient system for fabricating multi-junction solar cells providing semiconductor materials that effectively span the solar spectrum as demonstrated by world record efficiencies (39.2% under one-sun and 47.1% under concentration) for six-junction solar cells. This success has inspired attempts to achieve the same with other materials like perovskites for which lower manufacturing costs may be achieved. Recently, Si multi-junction solar cells such as III–V/Si, II–VI/Si, chalcopyrite/Si, and perovskite/Si have become popular and are getting closer to economic competitiveness. Here, we discuss the perspectives of multi-junction solar cells from the viewpoint of efficiency and low-cost potential based on scientific and technological arguments and possible market applications. In addition, this article provides a brief overview of recent developments with respect to III–V multi-junction solar cells, III–V/Si, II–VI/Si, perovskite/Si tandem solar cells, and some new ideas including so-called 3rd generation concepts. [ABSTRACT FROM AUTHOR]

Published

2021

4. High‐Efficiency Solar Cells Grown on Spalled Germanium for Substrate Reuse without Polishing.

Author

Mangum, John S., Rice, Anthony D., Chen, Jie, Chenenko, Jason, Wong, Evan W. K., Braun, Anna K., Johnston, Steve, Guthrey, Harvey, Geisz, John F., Ptak, Aaron J., and Packard, Corinne E.

Subjects

SOLAR cells, GERMANIUM, COST control, OPEN-circuit voltage, EPITAXY, PHOTOVOLTAIC power systems

Abstract

Radical reduction of III–V device costs requires a multifaceted approach attacking both growth and substrate costs. Implementing device removal and substrate reuse provides an opportunity for substrate cost reduction. Controlled spalling allows removal of thin devices from the expensive substrate; however, the fracture‐based process currently generates surfaces with significant morphological changes compared to polished wafers. 49 single junction devices are fabricated across the spalled surface of full 50 mm germanium wafers without chemo‐mechanical polishing before epitaxial growth. Device defects are identified and related to morphological spalling defects—arrest lines, gull wings, and river lines—and their impact on cell performance using physical and functional characterization techniques. River line defects have the most consistent and detrimental effect on cell performance. Devices achieve a single junction efficiency above 23% and open‐circuit voltage of 1.01 V, demonstrating that spalled germanium does not need to be returned to a pristine, polished state to achieve high‐quality device performance. [ABSTRACT FROM AUTHOR]

Published

2022

5. Incorporating photon recycling into the analytical drift-diffusion model of high efficiency solar cells.

Author

Lumb, Matthew P., Steiner, Myles A., Geisz, John F., and Walters, Robert J.

Subjects

DRIFT diffusion models, SOLAR cells, SOLAR reflectors, PHOTONS, GALLIUM arsenide

Abstract

The analytical drift-diffusion formalism is able to accurately simulate a wide range of solar cell architectures and was recently extended to include those with back surface reflectors. However, as solar cells approach the limits of material quality, photon recycling effects become increasingly important in predicting the behavior of these cells. In particular, the minority carrier diffusion length is significantly affected by the photon recycling, with consequences for the solar cell performance. In this paper, we outline an approach to account for photon recycling in the analytical Hovel model and compare analytical model predictions to GaAs-based experimental devices operating close to the fundamental efficiency limit. [ABSTRACT FROM AUTHOR]

Published

2014

6. Optimization of four terminal rear heterojunction GaAs on Si interdigitated back contact tandem solar cells.

Author

Whitehead, Riley C., VanSant, Kaitlyn T., Warren, Emily L., Buencuerpo, Jeronimo, Rienäcker, Michael, Peibst, Robby, Geisz, John F., and Tamboli, Adele C.

Subjects

SILICON solar cells, SOLAR cells, AUDITING standards, HETEROJUNCTIONS, TRANSFER matrix, THIN films

Abstract

High-efficiency, four-terminal tandem solar cells composed of thin GaAs films mechanically stacked onto interdigitated back contact silicon solar cells with a glass interlayer are demonstrated. The optimal thickness of the absorber layer of a rear heterojunction GaAs subcell for use in four terminal tandem solar cells was studied. GaAs top cells with absorber layer thicknesses of 1.5, 1.9, 2.3, 2.8, and 3.5 μm were fabricated on glass and mechanically stacked onto interdigitated back-contact Si bottom cells. All tandem cells were found to have efficiencies above 30% under the AM1.5 G spectrum demonstrating a relatively weak sensitivity to thickness in the four-terminal configuration. We found the 2.8 μm absorber layer cell to have the highest top cell and tandem cell efficiency at 26.38% and 32.57%, respectively. Optical modeling with transfer matrix method for the planar top cell and Lambertian light trapping in the textured Si subcell, along with drift-diffusion Hovel equations, were used to show photon recycling enhancement to the effective diffusion length and VOC of the top cell as a result of the low-index glass interlayer. [ABSTRACT FROM AUTHOR]

Published

2021

7. High Efficiency Inverted GaAs and GaInP/GaAs Solar Cells With Strain‐Balanced GaInAs/GaAsP Quantum Wells.

Author

Steiner, Myles A., France, Ryan M., Buencuerpo, Jeronimo, Geisz, John F., Nielsen, Michael P., Pusch, Andreas, Olavarria, Waldo J., Young, Michelle, and Ekins‐Daukes, Nicholas J.

Subjects

SOLAR cells, QUANTUM well devices, SILICON solar cells, AUDITING standards, QUANTUM wells, CELL junctions

Abstract

High‐efficiency solar cells are essential for high‐density terrestrial applications, as well as space and potentially vehicle applications. The optimum bandgap for the terrestrial spectrum lies beyond the absorption range of a traditional dual junction GaInP/GaAs cell, with the bottom GaAs cell having higher bandgap energy than necessary. Lower energy bandgaps can be achieved with multiple quantum wells (QWs), but such a pathway requires advanced management of the epitaxial growth conditions in order to be useful. Strain‐balanced GaAsP/GaInAs QWs are incorporated into a single junction GaAs solar cell and a dual junction GaInP/GaAs solar cell, leading to 27.2% efficiency in the single junction device and a one‐sun record 32.9% efficiency in the tandem device. Good carrier collection and low non‐radiative recombination are observed in the cells with up to 80 QWs. The GaAs cells employ a rear‐heterojunction architecture to boost the open‐circuit voltage to over 1.04 V in the quantum well device, despite the large number of QWs. [ABSTRACT FROM AUTHOR]

Published

2021

8. Six-Junction Concentrator Solar Cells.

Author

Geisz, John F., Steiner, Myles A., Schulte, Kevin L., Young, Matthew, France, Ryan M., and Friedman, Daniel J.

Subjects

*SOLAR cells, *GALLIUM arsenide, *TUNNEL junction devices, *SOLAR concentrators, *PHOTOVOLTAIC power generation, *PHOTOVOLTAIC power systems

Abstract

We report on six-junction inverted metamorphic (6J IMM) solar cells developed for concentrator applications. Monolithic III-V structures are grown by metal organic vapor phase epitaxy with junction bandgaps of 2.06, 1.70, 1.40, 1.16, 0.94, and 0.70 eV. The top three junctions are lattice-matched to the GaAs substrate, but the bottom three junctions use three consecutive metamorphic compositionally graded buffers to transition the lattice constant to GaxIn1-xAs compositions with the previously listed bandgaps. Performance of 6J IMM devices at one-sun AM1.5 Direct conditions gives VOC = 5.301 V, JSC = 8.05 mA/cm2, fill factor = 83.9%, and efficiency = 35.8%. Promising operation at high concentration is achieved but the spectrum was not controlled to AM1.5D. Tunnel junctions do not limit until at least several hundred suns. High concentration performance appears to be limited by internal heterojunction barriers created by zinc diffusion that decreases the fill factor. The properties of each junction within the 6J IMM have been separately characterized through electroluminescence and luminescent coupling measurements. [ABSTRACT FROM AUTHOR]

Published

2018

9. Printed assemblies of microscale triple‐junction inverted metamorphic GaInP/GaAs/InGaAs solar cells.

Author

Gai, Boju, Geisz, John F., Friedman, Daniel J., Chen, Huandong, and Yoon, Jongseung

Subjects

SOLAR cells, SILICON solar cells, SEMICONDUCTOR wafer bonding, AUDITING standards, TRANSFER printing, CELL size

Abstract

Inverted metamorphic (IMM) multijunction solar cells represent a promising material platform for ultrahigh efficiency photovoltaic systems (UHPVs) with a clear pathway to beyond 50% efficiency. The conventional device processing of IMM solar cells, however, typically involves wafer bonding of a centimeter‐scale die and destructive substrate removal, thereby imposing severe restrictions in achievable cell size, type of module substrate, spatial layout, as well as cost effectiveness. Here, we report material design and fabrication strategies for microscale triple‐junction IMM (3J IMM) Ga0.51In0.49P/GaAs/In0.26Ga0.74As solar cells that can overcome these difficulties. Specialized schemes of delineation and undercut etching enable the defect‐free release of microscale IMM solar cells and printed assemblies on a glass substrate in a manner that preserves the growth substrate, where efficiencies of 27.3% and 33.9% are demonstrated at simulated AM1.5D one‐ and 351 sun illumination, respectively. A composite carrier substrate where released IMM microcells are formed in fully functional, print‐ready configurations allows high‐throughput transfer printing of individual IMM microcells in a programmable spatial layout on versatile choices of module substrate, all desired for CPV applications. [ABSTRACT FROM AUTHOR]

Published

2019

10. Pathway to 50% Efficient Inverted Metamorphic Concentrator Solar Cells.

Author

Geisz, John F., Steiner, Myles A., Jain, Nikhil, Schulte, Kevin L., France, Ryan M., McMahon, William E., Perl, Emmett E., Horowitz, Kelsey A.W., and Friedman, Daniel J.

Subjects

*SOLAR cells, *SOLAR concentrators, *SOLAR cell efficiency, *SOLAR collectors, *SOLAR energy, *PHOTOVOLTAIC power generation

Abstract

Series-connected five (5J) and six junction (6J) concentrator solar cell strategies have the realistic potential to exceed 50% efficiency to enable low-cost CPV systems. We propose three strategies for developing a practical 6J device. We have overcome many of the challenges required to build such concentrator solar cell devices: We have developed 2.1 eV AlGaInP, 1.7 eV AlGaAs, and 1.7 eV GaInAsP junctions with external radiative efficiency greater than 0.1%. We have developed a transparent tunnel junction that absorbs minimal light intended for the second junction yet resists degradation under thermal load. We have developed metamorphic grades from the GaAs to the InP lattice constant that are transparent to sub-GaAs bandgap light. We have grown and compared low bandgap junctions (0.7eV - 1.2 eV) using metamorphic GaInAs, metamorphic GaInAsP, and GaInAsP lattice-matched to InP. And finally, we have demonstrated excellent performance in a high voltage, low current 4 junction inverted metamorphic device using 2.1, 1.7, 1.4, and 1.1 eV junctions with over 8.7 mA/cm2 one-sun current density that operates up to 1000 suns without tunnel junction failure. [ABSTRACT FROM AUTHOR]

Published

2017

11. 100-period InGaAsP/InGaP superlattice solar cell with sub-bandgap quantum efficiency approaching 80%.

Author

Sayed, Islam E. H., Jain, Nikhil, Steiner, Myles A., Geisz, John F., and Bedair, S. M.

Subjects

QUANTUM wells, INDIUM gallium arsenide phosphide, INDIUM gallium phosphide, SUPERLATTICES, SOLAR cells

Abstract

InGaAsP/InGaP quantum well (QW) structures are promising materials for next generation photovoltaic devices because of their tunable bandgap (1.50–1.80 eV) and being aluminum-free. However, the strain-balance limitations have previously limited light absorption in the QW region and constrained the external quantum efficiency (EQE) values beyond the In0.49Ga0.51P band-edge to less than 25%. In this work, we show that implementing a hundred period lattice matched InGaAsP/InGaP superlattice solar cell with more than 65% absorbing InGaAsP well resulted in more than 2× improvement in EQE values than previously reported strain balanced approaches. In addition, processing the devices with a rear optical reflector resulted in strong Fabry-Perot resonance oscillations and the EQE values were highly improved in the vicinity of these peaks, resulting in a short circuit current improvement of 10% relative to devices with a rear optical filter. These enhancements have resulted in an InGaAsP/InGaP superlattice solar cell with improved peak sub-bandgap EQE values exceeding 75% at 700 nm, an improvement in the short circuit current of 26% relative to standard InGaP devices, and an enhanced bandgap-voltage offset (Woc) of 0.4 V. [ABSTRACT FROM AUTHOR]

Published

2017

12. Energy Yield Determination of Concentrator Solar Cells Using Laboratory Measurements.

Author

Geisz, John F., García, Iván, McMahon, William E., Steiner, Myles A., Ochoa, Mario, France, Ryan M., Habte, Aron, and Friedman, Daniel J.

Subjects

*ENERGY consumption, *SOLAR concentrators, *ENERGY conversion, *SOLAR cells, *OPTOELECTRONICS

Abstract

The annual energy conversion efficiency is calculated for a four junction inverted metamorphic solar cell that has been completely characterized in the laboratory at room temperature using measurements fit to a comprehensive optoelectronic model of the multijunction solar cells. A simple model of the temperature dependence is used predict the performance of the solar cell under varying temperature and spectra characteristic of Golden, CO for an entire year. The annual energy conversion efficiency is calculated by integrating the predicted cell performance over the entire year. The effects of geometric concentration, CPV system thermal characteristics, and luminescent coupling are highlighted. [ABSTRACT FROM AUTHOR]

Published

2015

13. Device Characterization For Design Optimization Of 4 Junction Inverted Metamorphic Concentrator Solar Cells.

Author

Geisz, John F., France, Ryan M., García, Iván, Steiner, Myles A., and Friedman, Daniel J.

Subjects

*SOLAR cells, *SOLAR concentrators, *MATHEMATICAL optimization, *ELECTROLUMINESCENCE, *SOLAR radiation

Abstract

Quantitative electroluminescence (EL) and luminescent coupling (LC) analysis, along with more conventional characterization techniques, are combined to completely characterize the subcell JV curves within a fourjunction (4J) inverted metamorphic solar cell (IMM). The 4J performance under arbitrary spectral conditions can be predicted from these subcell JV curves. The internal radiative efficiency (IRE) of each junction has been determined as a function of current density from the external radiative efficiency using optical modeling, but this required the accurate determination of the individual junction current densities during the EL measurement as affected by LC. These measurement and analysis techniques can be applied to any multijunction solar cell. The 4J IMM solar cell used to illustrate these techniques showed excellent junction quality as exhibited by high IRE and a one-sun AM1.5D efficiency of 36.3%. This device operates up to 1000 suns without limitations due to any of the three tunnel junctions. [ABSTRACT FROM AUTHOR]

Published

2014

14. Component Integration Strategies In Metamorphic 4-junction III-V Concentrator Solar Cells.

Author

García, Iván, Geisz, John F., France, Ryan M., Steiner, Myles A., and Friedman, Daniel J.

Subjects

*SOLAR cells, *SOLAR concentrators, *INDIUM gallium arsenide, *SUBSTRATES (Materials science), *SIMULATED annealing, *BUFFER layers, *LATTICE constants

Abstract

Progressing beyond 3-junction inverted-metamorphic multijunction solar cells grown on GaAs substrates, to 4-junction devices, requires the development of high quality metamorphic 0.7 eV GaInAs solar cells. Once accomplished, the integration of this subcell into a full, monolithic, series connected, 4J-IMM structure demands the development of a metamorphic tunnel junction lattice matched to the 1eV GaInAs subcell. Moreover, the 0.7 eV junction adds about 2 hours of growth time to the structure, implying a heavier annealing of the subcells and tunnel junctions grown first. The final 4J structure is above 20 μm thick, with about half of this thickness used by the metamorphic buffers required to change the lattice constant throughout the structure. Thinning of these buffers would help reduce the total thickness of the 4J structure to decrease its growth cost and the annealing time. These three topics: development of a metamorphic tunnel junction for the 4th junction, analysis of the annealing, and thinning of the structure, are tackled in this work. The results presented show the successful implementation of an antimonide-based tunnel junction for the 4th junction and of pathways to mitigate the impact of annealing and reduce the thickness of the metamorphic buffers. [ABSTRACT FROM AUTHOR]

Published

2014

15. Two-terminal metal-inter-connected multijunction III-V solar cells.

Author

Lin, Chieh ‐ Ting, McMahon, William E., Ward, James S., Geisz, John F., Wanlass, Mark W., Carapella, Jeffrey J., Olavarria, Waldo, Perl, Emmett E., Young, Michelle, Steiner, Myles A., France, Ryan M., Kibbler, Alan E., Duda, Anna, Moriarty, Tom E., Friedman, Daniel J., and Bowers, John E.

Subjects

METAL bonding, SOLAR cells, HETEROJUNCTIONS, TOPOLOGY, FLEXIBLE couplings

Abstract

A novel bonding approach with an interface consisting of a metal and dielectric is developed, and a 'pillar-array' metal topology is proposed for minimal optical and electrical loss at the interface. This enables a fully lattice-matched two-terminal, four-junction device that consists of an inverted top two-junction (2J) cell with 1.85 eV GaInP/1.42 eV GaAs, and an upright lower 2J cell with ~1 eV GaInAsP/0.74 eV GaInAs aimed for concentrator applications. The fabrication process and simulation of the metal topology are discussed along with the results of GaAs/GaInAs 2J and (GaInP + GaAs)/GaInAs three-junction bonded cells. Bonding-related issues are also addressed along with optical coupling across the bonding interface. Copyright © 2014 John Wiley & Sons, Ltd. [ABSTRACT FROM AUTHOR]

Published

2015

16. Optimization of 3-junction inverted metamorphic solar cells for high-temperature and high-concentration operation.

Author

Geisz, John F., Duda, Anna, France, Ryan M., Friedman, Daniel J., Garcia, Ivan, Olavarria, Waldo, Olson, Jerry M., Steiner, Myles A., Ward, J. Scott, and Young, Michelle

Subjects

*MATHEMATICAL optimization, *SEMICONDUCTOR junctions, *SOLAR cells, *HIGH temperatures, *BAND gaps, *SOLAR energy

Abstract

Four different band gap combinations of triple-junction inverted metamorphic solar cells are characterized as a function of temperature and concentration up to 120°C and ∼1000 suns. We demonstrate that the standard 1.82/1.40/1.00 eV combination is an excellent choice for typical operating conditions of 1000 suns and 75°C. Improved metal grids and thermal management in such a cell has achieved 42.6% efficiency at 327 suns and 40.9% at 1093 suns at 25°C. [ABSTRACT FROM AUTHOR]

Published

2012

17. Infrared Reflective and Transparent Inverted Metamorphic Triple Junction Solar Cells.

Author

Geisz, John F., Scott Ward, J., Duda, Anna, Olavarria, Waldo, Gedvilas, Lynn, Young, Michelle, Wanlass, Mark W., Carapella, Jeff, Kurtz, Sarah R., Friedman, Daniel J., Romero, Manuel J., and Steiner, Myles A.

Subjects

*SOLAR spectra, *SOLAR cells, *PHOTOVOLTAIC power generation, *EFFICIENCY of solar concentrators, *INFRARED detectors, *SOLAR radiation, *GERMANIUM

Abstract

The infrared (IR) portion of the solar spectrum with photon energies below the lowest bandgap in III-V multijunction photovoltaic devices does not contribute to electrical power and is typically ignored during solar cell design. In a three junction inverted metamorphic multijunction (IMM) solar cell with a 1.0 eV bottom junction, this infrared light makes up 16% of the total power and can be extracted from the cell by reflective or transparent designs. We demonstrate several IMM designs that are about 39% efficient under concentration, allow this IR power to be used elsewhere, and reduce the heat load by about 20% relative to Ge-based solar cells that are also 40% efficient. [ABSTRACT FROM AUTHOR]

Published

2010

18. Non-linear luminescent coupling in series-connected multijunction solar cells.

Author

Steiner, Myles A. and Geisz, John F.

Subjects

*SOLAR cells, *DIRECT energy conversion, *SOLAR energy, *PHOTOVOLTAIC cells, *LUMINESCENCE

Abstract

The assumption of superposition or linearity of photocurrent with solar flux is widespread for calculations and measurements of solar cells. The well-known effect of luminescent coupling in multijunction solar cells has also been assumed to be linear with excess current. Here we show significant non-linearities in luminescent coupling in III-V multijunction solar cells and propose a simple model based on competition between radiative and nonradiative processes in the luminescent junction to explain these non-linearities. We demonstrate a technique for accurately measuring the junction photocurrents under a specified reference spectrum, that accounts for and quantifies luminescent coupling effects. [ABSTRACT FROM AUTHOR]

Published

2012

19. High-efficiency inverted metamorphic 1.7/1.1 eV GaInAsP/GaInAs dual-junction solar cells.

Author

Jain, Nikhil, Schulte, Kevin L., Geisz, John F., Friedman, Daniel J., France, Ryan M., Perl, Emmett E., Norman, Andrew G., Guthrey, Harvey L., and Steiner, Myles A.

Subjects

PHOTOVOLTAIC power generation, INDIUM gallium arsenide, BAND gaps, SOLAR cells, TRANSMISSION electron microscopy

Abstract

Photovoltaic conversion efficiencies of 32.6 ± 1.4% under the AM1.5 G173 global spectrum, and 35.5% ± 1.2% at 38-suns concentration under the direct spectrum, are demonstrated for a monolithic, dual-junction 1.7/1.1 eV solar cell. The tandem cell consists of a 1.7 eV GaInAsP top-junction grown lattice-matched to a GaAs substrate, followed by a metamorphic 1.1 eV GaInAs junction grown on a transparent, compositionally graded metamorphic AlGaInAs buffer. This bandgap combination is much closer to the dual-junction optimum and offers headroom for absolute 3% improvement in efficiency, in comparison to the incumbent lattice-matched GaInP/GaAs (∼1.86/1.41 eV) solar cells. The challenge of growing a high-quality 1.7 eV GaInAsP solar cell is the propensity for phase separation in the GaInAsP alloy. The challenge of lattice-mismatched GaInAs solar cell growth is that it requires minimizing the residual dislocation density during the growth of a transparent compositionally graded buffer to enable efficient metamorphic tandem cell integration. Transmission electron microscopy reveals relatively weak composition fluctuation present in the 1.7 eV GaInAsP alloy, attained through growth control. The threading dislocation density of the GaInAs junction is ∼1 × 106 cm−2, as determined from cathodoluminescence measurements, highlighting the quality of the graded buffer. These material advances have enabled the performance of both junctions to reach over 80% of their Shockley-Queisser limiting efficiencies, with both the subcells demonstrating a bandgap-voltage offset, WOC (=Eg/q-VOC), of ∼0.39 V. [ABSTRACT FROM AUTHOR]

Published

2018

20. Growth of lattice-matched GaInAsP grown on vicinal GaAs(001) substrates within the miscibility gap for solar cells.

Author

Oshima, Ryuji, France, Ryan M., Geisz, John F., Norman, Andrew G., and Steiner, Myles A.

Subjects

*CRYSTAL growth, *SOLAR cells, *CRYSTAL lattices, *INDIUM gallium arsenide, *MISCIBILITY gap, *SUBSTRATES (Materials science)

Abstract

The growth of quaternary Ga 0.68 In 0.32 As 0.35 P 0.65 by metal-organic vapor phase epitaxy is very sensitive to growth conditions because the composition is within a miscibility gap. In this investigation, we fabricated 1 µm-thick lattice-matched GaInAsP films grown on GaAs(001) for application to solar cells. The growth temperature and substrate miscut are varied in order to characterize the effect of the surface diffusion of adatoms on the material quality of alloys. Transmission electron microscopy and two-dimensional in-situ multi-beam optical stress determine that growth temperatures of 650 °C and below enhance the formation of the CuPt B atomic ordering and suppress material decomposition, which is found to occur at the growth surface. The root-mean-square (RMS) roughness is reduced from 33.6 nm for 750 °C to 1.62 nm for 650 °C, determined by atomic force microscopy. Initial investigations show that the RMS roughness can be further reduced using increased miscut angle, and substrates miscut toward (111)A, leading to an RMS roughness of 0.56 nm for the sample grown at 600 °C on GaAs miscut 6° toward (111)A. Using these conditions, we fabricate an inverted hetero-junction 1.62 eV Ga 0.68 In 0.32 As 0.35 P 0.65 solar cell without an anti-reflection coating with a short-circuit current density, open-circuit voltage, fill factor, and efficiency of 12.23 mA/cm 2 , 1.12 V, 86.18%, and 11.80%, respectively. [ABSTRACT FROM AUTHOR]

Published

2017

21. Trapezoidal grid fingers to reduce shadowing loss and improve short circuit current.

Author

Cavalli, Alessandro, Buencuerpo, Jeronimo, Steger, Mark, Perl, Emmett E., Steiner, Myles A., and Geisz, John F.

Subjects

*SHORT circuits, *ELECTRON beams, *SOLAR cells, *OPEN-circuit voltage, *SHORT-circuit currents, *SILICON solar cells

Abstract

Traditional metallic contacts on solar cells can cover a substantial portion of the device area, resulting in shadowing of light that diminishes the amount of current collected. In this paper, we developed trapezoidal electron-beam evaporated Ti/Al front grid fingers on GaAs single-junction solar cells to decrease the optical shadowing and increase the photogenerated current. We observe a high fill factor of 87% at 1-Sun light intensity and we observe no degradation on the open-circuit voltage. The short-circuit current density is found to increase by 0.4 mA/cm2 when compared to previously demonstrated electroplated Ni/Au front grid fingers, resulting in an efficiency improvement of ~0.8% absolute. • Developed front grid fingers with trapezoidal cross section • Contacts fabrication by conventional semiconductor tools • Devices exhibited increased photocurrent and efficiency improvement by 0.8% absolute [ABSTRACT FROM AUTHOR]

Published

2021