R.J. Wehrer scite author profile

We discuss lattice-mismatched (LMM) approaches utilizing compositionally step-graded layers and buffer layers that yield Ill-V photovoltaic devices with performance parameters equaling those of similar latticematched (LM) devices. Our progress in developing highperformance. LMM, InP-based GalnAshAsP materials and devices for thermophotovoltaic (TPV) energy conversion is highlighted. A novel, monolithic. multibandgap, tandem device for solar PV (SPV) conversion involving LMM materials .is also presented along with promising preliminary performance results.

show abstract

Monolithic interconnected modules (MIMs) for thermophotovoltaic energy conversion

Wilt

Wehrer

Palmisiano

et al. 2003

Semicond. Sci. Technol.

View full text Add to dashboard Cite

Monolit hic Interconnected Modules (MIM) are under dev e lopment for thermophotovoltaic (TPV) energy conversion apphcations. MIM de vices are typifi ed by series-interconnected photovoltaic cells on a common , semi-insul ati ng su bstrate and generally include rear-surface infrared (lR) reflectors. The MIM arc hitecture is being implemented in InGaAsSb materials without semi-insulating substrates through the development of alternative isolation methodologies. Moti vations for developing the MIM structure include: reduced resistive losses , higher output power density than for systems utilizing fro nt surface spectral control, improved thermal coupling and ultimately higher system efficiency. Numerous design and material changes have been investigated since the introduction of the MIM concept in 1994. These developments as well as the current design strategies are addressed.

show abstract

Advanced Thermophotovoltaic Devices for Space Nuclear Power Systems

Wernsman¹,

Mahorter²,

Siergiej³

et al. 2005

View full text Add to dashboard Cite

Advanced thermophotovoltaic (TPV) modules capable of producing > 0.3 W/cm 2 at an efficiency > 22% while operating at a converter radiator and module temperature of 1228 K and 325 K, respectively, have been made. These advanced TPV modules are projected to produce > 0.9 W/cm 2 at an efficiency > 24% while operating at a converter radiator and module temperature of 1373 K and 325 K, respectively. Radioisotope and nuclear (fission) powered space systems utilizing these advanced TPV modules have been evaluated. For a 100 W e radioisotope TPV system, systems utilizing as low as 2 general purpose heat source (GPHS) units are feasible, where the specific power for the 2 and 3 GPHS unit systems operating in a 200 K environment is as large as ~ 16 W e /kg and ~ 14 W e /kg, respectively. For a 100 kW e nuclear powered (as was entertained for the thermoelectric SP-100 program) TPV system, the minimum system radiator area and mass is ~ 640 m 2 and ~ 1150 kg, respectively, for a converter radiator, system radiator and environment temperature of 1373 K, 435 K and 200 K, respectively. Also, for a converter radiator temperature of 1373 K, the converter volume and mass remains less than 0.36 m 3 and 640 kg, respectively. Thus, the minimum system radiator + converter (reactor and shield not included) specific mass is ~ 16 kg/kW e for a converter radiator, system radiator and environment temperature of 1373 K, 425 K and 200 K, respectively. Under this operating condition, the reactor thermal rating is ~ 1110 kW t . Due to the large radiator area, the added complexity and mission risk needs to be weighed against reducing the reactor thermal rating to determine the feasibility of using TPV for space nuclear (fission) power systems.

show abstract

0.74/0.55-eV Ga/sub x/In/sub 1-x/As/InAsP/sub 1-y/ monolithic, tandem, MIM TPV converters: design, growth, processing and performance

Wehrer

Wanlass²,

Werrisman³

et al.

View full text Add to dashboard Cite

Thermophotovoltaic (TPV) tandem converter technology is being explored in an effort to improve both the efficiency and power density of TPV systems. Inverted, tandem structures incorporate epitaxially grown 0.74-eV latticematched Gadn0.53As and 0.55-eV lattice-mismatched Gao.2alno.72As diodes. Adddionally, a strategy has been developed to allow voltage matching between these two subcells. Performance modeling calculations show that, under typical operating conditions, the 0.74/0.55eV tandem converter should outperform a 0.55-eV single junction converter by 15% on an efficiency basis and by 15% on a power density basis. This paper will present details regarding the design, growth, fabrication, and electrical, optical. and structural characterization of voltage-matched tandem TPV devices.

show abstract

scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.

Contact Info

customersupport@researchsolutions.com

10624 S. Eastern Ave., Ste. A-614

Henderson, NV 89052, USA

This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.

Blog Terms and Conditions API Terms Privacy Policy Contact Cookie Preferences Do Not Sell or Share My Personal Information

Made with 💙 for researchers

Part of the Research Solutions Family.

R.J. Wehrer

Greater Than 20% Radiant Heat Conversion Efficiency of a Thermophotovoltaic Radiator/Module System Using Reflective Spectral Control

Lattice-mismatched approaches for high-performance, III-V photovoltaic energy converters

Monolithic interconnected modules (MIMs) for thermophotovoltaic energy conversion

Advanced Thermophotovoltaic Devices for Space Nuclear Power Systems

0.74/0.55-eV Ga/sub x/In/sub 1-x/As/InAsP/sub 1-y/ monolithic, tandem, MIM TPV converters: design, growth, processing and performance

Contact Info

Product

Resources

About