R. R. Potter scite author profile

Transients in the current-voltage characteristics of (Cd,Zn)S/CuInSe2 solar cells after sudden changes in illumination are reported. The transients are found to vary with bias across the cell, intensity, temperature, illumination wavelength, and recent illumination history. Multiple trapping levels, primarily in the CuInSe2 near the interface, are seen as responsible for the observed dc voltage shift and are photoexcited in less than 1 ms. Relaxation in the dark takes tens of seconds and appears dominated by states in the (Cd,Zn)S which gives wavelength dependent effects on fill factor and transient decay.

show abstract

Current-voltage response of tandem junction solar cells

Potter

Sites

Wagner

1982

View full text Add to dashboard Cite

A flux analysis of the current-voltage characteristics of thin film frontwall illuminated and backwall illuminated liquid junction and metal junction solar cells A model tandem junction solar cell is compared with experimental results from the monolithic n-SilSn0 2 /n-CdSe/electrolyte tandem system and from its constituent cells, n-SilSn0 2 and n-CdSe/ electrolyte. Inclusion of the effects of series resistance and partial shunting of one or both active junctions produces a model that adequately describes the experimental cell. Both the voltage addition principle and the expected response to the tandem cell to different wavelengths are confirmed. The implications for tandem junction solar cell development are discussed.

show abstract

An n ‐ CdSe / SnO2 / n ‐ Si Tandem Electrochemical Solar Cell

Gobrecht

Potter

Nottenburg

et al. 1983

J. Electrochem. Soc.

View full text Add to dashboard Cite

We demonstrate a new type of monolithic tandem junction solar cell. The cell is made up of a bottom (low energy gap) Schottky barrier and a top (high energy gap) semiconductor-electrolyte junction. By using silicon as the low gap and cadmium selenide as the high gap semiconductor we chose a pair of semiconductors which produces equal photocurrents when stacked on top of each other. We have observed open-circuit voltages up to 1.21V which demonstrate addition of the output voltage of the two cells. Short-circuit currents are low, reflecting the poor quality of the CdSe film.The energy bandgap of the absorbing semiconductor chosen for a solar cell represents a compromise for high photocurrent (suggesting a small gap) and high photovoltage (suggesting a large gap) (1). Tandemand higher multiple-junction solar cells improve this compromise by employing in series two or more absorbing semiconductors that cover a range of energy gaps (2). To maximize efficiency and to provide a single output voltage such cells are arranged in electrical series. Tandem cell configurations comprise either two physically separate cells which receive separate portions of the solar spectrum from a dichroic mirror (a spectrum-splitting filter) (3), or a monolithic structure whose top cell absorbs the short wavelength portion of sunlight and transmits the long wavelength portion to the lower cell (4).Series connection of the two cells requires balancing of the photocurrents produced by each individual cell. This requirement makes the two energy gaps depend on each other. The use of semiconductor alloys (3) provides flexibility in the choice of energy gaps, but requires expensive fabrication technology which can be justified only for high performance concentrators.The theoretical principles of tandem solar cells have been analyzed by several authors (5, 6). However, few experimental tests of tandem cells have been reported. It is difficult to find and to combine semiconductors with acceptable photovoltaic properties and whose bandgaps are well matched.In this paper we demonstrate a tandem cell with CdSe (Eg : 1.73 eV) and Si (Eg ~_ 1.12 eV). At Air Mass 1 insolation, the photon flux with hv ~ 1.73 eV is 1.3 • 1017 cm-~ sec-1 and with h~ ~ 1.12 eV, 2.7 • 10 l~ em -2 sec -1. Thus the photon currents absorbed in the two partners of a monolithic CdSe/Si structure are nearly equal, Therefore, the CdSe/Si combination lies close to the point of maximum attainable efficiency for monolithic tandem cells. This semiconductor combination provides a near-ideal vehicle for a highly efficient tandem cell without the expense of alloy semiconductors. Since polycrystalline n-CdSe photoanodes have" been demonstrated with promising efficiency (7), the n-CdSe/n-Si tandem photoanode is an interesting candidate for use in an efficient regenerative photoelectrochemical cell. The observed high output voltage also suggests application in a photoelectrochemical storage cell (8); the voltages developed by most photoelectrochemical cells are insufficient to drive the desi...

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. R. Potter

Enhanced photocurrent ZnO/CdS/CuInSe2 solar cells

Light-induced junction modification in (Cd, Zn)S/CuInSe₂solar cells

Current-voltage transients in (Cd,Zn)S/CuInSe2 solar cells

Current-voltage response of tandem junction solar cells

An n ‐ CdSe / SnO2 / n ‐ Si Tandem Electrochemical Solar Cell

Contact Info

Product

Resources

About

R. R. Potter

Enhanced photocurrent ZnO/CdS/CuInSe2 solar cells

Light-induced junction modification in (Cd, Zn)S/CuInSe2solar cells

Current-voltage transients in (Cd,Zn)S/CuInSe2 solar cells

Current-voltage response of tandem junction solar cells

An n ‐ CdSe / SnO2 / n ‐ Si Tandem Electrochemical Solar Cell

Contact Info

Product

Resources

About

Light-induced junction modification in (Cd, Zn)S/CuInSe₂solar cells