Info
Info
News Article

Researchers Advance CdTe Production

News

High purity CdTe crystals can be grown quickly under high-pressure using arsenic as a dopant

A Washington State University team has developed a more efficient, safer, and cost-effective way to produce CdTe material for solar cells or other applications.

The researchers showed they could rapidly grow a large amount of high-purity CdTe material - a more than kilogram-sized crystal in one day - which would be considered lightning fast in the industry. The technique, which uses a high-pressure furnace to produce large amounts of the needed crystal feedstock material, is 45 percent more cost effective than the industry standard and is scalable, which could make CdTe solar technology less expensive than natural gas. The crystal material produced also has better electrical properties than what is currently available.

Working in collaboration with the National Renewable Energy Laboratory (NREL) and industry partner Nious Technologies, the researchers report on their work in the Journal of Crystal Growth.

CdTe photovoltaics are a newer technology than popular silicon solar cells and are competitive in terms of efficiency. They also perform better in hot and humid weather. While CdTe solar cells could provide significant advantages in cost and efficiency over silicon, they currently make up less than 10 percent of the solar market, mostly at the utility scale. In particular, current production methods are slow, costly, cumbersome and lack the flexibility to customise.

"Right now there is a huge kink in raw material production," said Santosh Swain, research assistant professor with the Institute of Materials Research and a co-author on the paper. "The solar industry has steadily increased device efficiency and fabricating devices, but further efficiency gains and cost reduction require improvement in CdTe material properties."

The current manufacturing process involves cooking the CdTe material in a sealed glass tube to contain the reaction. It takes a long time, the tubes are not reusable, and the silica glass is limited in how much heat, mass, and pressure it can take. Because of concerns about the material exploding, the industry is limited in the size of crystals they can grow. To make solar cells, the crystals are then evaporated onto glass substrate to make very thin films.

The new technique uses a strong graphite crucible, and the material is cooked in a high-pressure Bridgman furnace. The high-pressure environment completely eliminates the possibility of explosions and also allows the researchers to easily add a high concentration of additional materials, called dopants, during the manufacturing process that improve the material's performance. In 2016, the WSU research team in collaboration with NREL and University of Tennessee dramatically improved CdTe technology by adding phosphorus as a dopant, overcoming a 1 Volt limit that had been pursued for six decades. For this project, the researchers added arsenic as a dopant.

Adding the highly volatile dopants during the feedstock manufacturing process also eliminates the need to dope after film deposition which can cause non uniformity issues, said Tawfeeq Al-Hamdi, a PhD student and lead author on the paper.

"Doping is a key strategy," said co-author Seth McPherson. "At 80 atmospheres of pressure, you can really shove the dopants into the material, and you don't have to worry about them evaporating out of the crystal or otherwise escaping the system."

The researchers created crystals that are 1.2 kilograms in size, but could potentially create crystals that are up to 20 kilograms.

The project was funded by the US Department of Energy.

'CdTe synthesis and crystal growth using the high-pressure Bridgman technique' by Tawfeeq Al-Hamdia et al; Journal of Crystal Growth Volume 534, 15 March 2020, 125466

BayWa R.e. Delivers The First Operational Solar Park Won In Malaysia’s LSS2 Auction
Fourth Fundraise Secured By Elgin Energy
ValkPro+ Mounting System Approved For Installation On Flat Roofs With ROCKWOOL Roof Insulation
Waxman Energy Appoint New Southern Sales Executive
Foresight Appoints Steven Hughes As Director And Head Of Portfolio
ABB To Deliver 90 Transformers To MHI Vestas’ Offshore Wind Farm In The UK
Cracks In Perovskite Films Easily Healed, Study Finds
SolarEdge Intensifying Activity In The Japanese Market With Receipt Of JET Certification
Solarif Insurance Available For Vikram Solar PV Modules
Gresham House Acquires 12MW Bumpers Battery-ready Solar Farm From Anesco
PV Modules With An Innovative Frame Design
Anesco’s O&M Team Secures 10 New Solar Farm Contracts
What Impact Could The Government’s New Building Regulations Have On Energy Targets?
ZSW To Delve Further Into Solar Cell Anatomy
DCS Launches Largest EV Charging Roaming Service In The UK
Solar Module Generates 326 W Per Square Metre
Cornwall Insight Ireland 'Lack Of Headroom In RESS Will See Projects Jostle For Limited Capacity'
Gresham House Energy Storage Boosts Portfolio By 39%
Flisom Chooses LayTec For CIGS Quality Control
SolarEdge To Supply Enfindus With Inverters For 1GW Of European Solar Projects
Researchers Advance CdTe Production
Ingeteam Launches Battery Inverter With Two Solar PV Inputs
Everoze Advises On +100MW Wind And Solar Portfolio Refinancing
JenaBatteries And BASF Cooperate In The Development Of Innovative Power Storage Technology

Info
×
Search the news archive

To close this popup you can press escape or click the close icon.
Logo
×
Logo
×
Register - Step 1

You may choose to subscribe to the Smart Solar Magazine, the Smart Solar Newsletter, or both. You may also request additional information if required, before submitting your application.


Please subscribe me to:

 

You chose the industry type of "Other"

Please enter the industry that you work in:
Please enter the industry that you work in:
 
X
Info
X
Info
{taasPodcastNotification}