UbiQD and First Solar Establish Long-Term Quantum Dot Supply Agreement

Los Alamos-based UbiQD And First Solar Establish Long-Term Quantum Dot Supply Agreement

Quantum dots glowing with various colors in vials. Courtesy/UbiQD® UbiQD® News: Additionally, the companies expanded their photovoltaic module R&D collaboration focused on optimizing performance of utility-scale solar  UbiQD®, a global leader in quantum dot (QD) nanotechnology, announced today that it has entered into an exclusive, multi-year agreement to supply its proprietary fluorescent QD technology to First Solar, Inc. (NASDAQ: FSLR). The …

UbiQD and First Solar Establish Long-Term Quantum Dot Supply Agreement

/PRNewswire/ -- UbiQD®, a global leader in quantum dot (QD) nanotechnology, announced today that it has entered into an exclusive, multi-year agreement to...

UbiQD and First Solar Establish Long-Term Quantum Dot Supply Agreement for Photovoltaic Panels - Quantum Computing Report

UbiQD, a company specializing in quantum dot (QD) nanotechnology, has entered into an exclusive, multi-year agreement to supply its proprietary fluorescent QD technology to First Solar, Inc. (NASDAQ: FSLR). This agreement facilitates the incorporation of QD technology into First Solar's thin film bifacial photovoltaic (PV) solar panels. This marks a high-volume QD supply agreement outside [...] The post UbiQD and First Solar Establish Long-Term …

Los Alamos-Based UbiQD And First Solar Establish Long-Term Quantum Dot Supply Agreement

Quantum dots glowing with various colors in vials. Photo Courtesy of UbiQD®UbiQD® NEWS RELEASE UbiQD®, a global leader in quantum dot (QD) nanotechnology, announced today that it has entered into an exclusive, multi-year agreement to supply its proprietary fluorescent QD technology to First Solar, Inc. (NASDAQ: FSLR). The agreement paves the way for the incorporation of QD technology into First Solar’s thin film bifacial photovoltaic (PV) solar …

Quantum Wells Boost Solar Cell Efficiency Beyond Theoretical Limits

Research into quantum well solar cells demonstrates that varying well thickness impacts hot carrier generation and quasi-Fermi level splitting, enhancing opto-electrical properties though photocurrent generation primarily occurs within the barrier layer rather than the quantum wells themselves, suggesting optimisation strategies must focus on barrier layer characteristics to improve device efficiency.