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The University of New South Wales (UNSW) in Australia announced that a 4-layer solar module made by researchers at the university that converts sunlight after prism spectroscopy into electricity in two solar cells has achieved a conversion efficiency
of 34.
5%.
This is the world's record
for the conversion efficiency of non-concentrating solar modules.
The conversion efficiency of spectroscopic solar cells was previously about 24%, but this time it has suddenly increased to 1.
44 times
.
UNSW's spectroscopic solar cell is to make sunlight incident on the prism, separate the near-infrared rays with a wavelength of about 900~1050nm to irradiate the silicon solar cells, and irradiate other wavelengths of light and infrared rays to the 4-layer stacked compound solar cells, thereby improving the conversion efficiency
.
The effective area of the module is 28cm2
.
Mark Keevers, a senior researcher at UNSW who developed the module, achieved a conversion efficiency
of 40% in December 2014 by irradiating concentrated sunlight into the same spectroscopic solar module.
This time it set a new record
for non-concentrating type.
The University of New South Wales (UNSW) in Australia announced that a 4-layer solar module made by researchers at the university that converts sunlight after prism spectroscopy into electricity in two solar cells has achieved a conversion efficiency
of 34.
5%.
This is the world's record
for the conversion efficiency of non-concentrating solar modules.
The conversion efficiency of spectroscopic solar cells was previously about 24%, but this time it has suddenly increased to 1.
44 times
.
UNSW's spectroscopic solar cell is to make sunlight incident on the prism, separate the near-infrared rays with a wavelength of about 900~1050nm to irradiate the silicon solar cells, and irradiate other wavelengths of light and infrared rays to the 4-layer stacked compound solar cells, thereby improving the conversion efficiency
.
The effective area of the module is 28cm2
.
Mark Keevers, a senior researcher at UNSW who developed the module, achieved a conversion efficiency
of 40% in December 2014 by irradiating concentrated sunlight into the same spectroscopic solar module.
This time it set a new record
for non-concentrating type.
Mark Keevers, a senior researcher at UNSW who developed the module, achieved a conversion efficiency
of 40% in December 2014 by irradiating concentrated sunlight into the same spectroscopic solar module.
This time it set a new record
for non-concentrating type.
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Disclaimer: Some of the public information collected by this website comes from the Internet, and the purpose of reprinting is to convey more information and for network sharing, which does not mean that this site agrees with its views and is responsible for its authenticity, nor does it constitute any other suggestions, and the content of the article is for reference
only.
If you find a work on the website that infringes your intellectual property rights, please contact us and we will promptly modify or delete
it.
only.
If you find a work on the website that infringes your intellectual property rights, please contact us and we will promptly modify or delete
it.
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Responsible editor: Jiang Dan
Responsible editor: Jiang Dan
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