November 2024

Apple launched its latest laptops, the M4 MacBook Pro models, and according to DSSC the new displays adopt a red quantum dot film for the first time.

Up until now, Apple used red KSF phosphor films, but the QDs offer more accurate and vivid colors as the emission spectrum is narrower. In the past Apple opted for KSF because this technology does not use any Cadmium and it is lower in cost. Apple's new QD films are Cadmium-free.

Material developer Avantama announced that it is set to sell its entire perovskite QD IP portfolio. The company says that it has managed to bring the technology to market-readyness level, and is looking for a company that will bring it to market. 

Ocean Tomo Transactions (a part of J.S. Held) will be representing Avantama in the sale of its pQD IP portfolio. The company has developed over 220 IP assets, which includes patents on processes, compositions, formulations, films, and devices for the commercialization of semiconductor nanoparticle and quantum dot inks and films.

A couple of months ago we reported that Korean QD developer Hansol Chemical commissioned SGS and Intertek to test some of TCL's QLED TVs, finding that these do not in fact contain any Cadmium or Indium. Hansol  has now filed a complaint with the Fair Trade Commission (FTC) in the US against TCL, saying that it falsely advertised its TVs as QD-LED TVs.

In its FTC complaint, Hansol mentioned three TCL TV models: C755, C655 and C655 PRO. This will be interesting to watch.

Researchers from Sungkyunkwan University developed a source material for the inorganic hole transport layer of QD-EL devices. The researchers say that the new material significantly enhances the brightness and stability of emissive QD displays.

The researchers say that currently used organic HTL materials suffer from low conductivity and thermal instability. The new material is a standard HTL doped by defect-controlled nickel oxide-magnesium oxide alloy and treated with magnesium hydroxide. Using the new material, the EQE of the QD-EL device increased to 16.4%. The doping and treatment lowered the hole conductivity of the hole transport layer and suppressed the hole extraction process from within the quantum dots, thereby enhancing the device efficiency to a level comparable to existing technologies.