Search Results - photoluminescence

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Efficient One-Step Chemical Conversion of MXene Into Quantum Dots (Case No. 2025-246)

Summary: UCLA researchers in the Department of Chemistry and Biochemistry have developed a novel one-step method for producing MXene quantum dots with precise size control in an environmentally safe manner. Background: Quantum dots are widely used in bioimaging due to their tunable optical, electrical, and chemical properties. However, traditional...

Published: 5/6/2025 | Inventor(s): Paul Weiss, Haiyue Huang, Judy Cheng

Keywords(s): Biochemistry, bioimaging, Biomaterial, Catalysts, Chemical, Chemical Manufacturing & Industrial/Bulk Chemicals, energy conversion, energy conversion applications, Functional Materials, labeling, material science, Materials, Nanomaterials, photoluminescence, Quantum Dot

Category(s): Chemical, Chemical > Synthesis, Materials, Materials > Semiconducting Materials

HgTe Quantum Dots With Near Untiy Photoluminescent Quantum Yields in the Near and Short-Wave Infrared (Case No. 2024-256)

Summary: Researchers in UCLA’s Department of Chemistry and Biochemistry have developed an innovative synthesis technique to create ultrasmall Mercury Telluride (HgTe) quantum dots, offering tunable optoelectronic properties and high photoluminescent quantum yields across the infrared spectrum. Background: HgTe quantum dots are gaining popularity...

Published: 4/10/2025 | Inventor(s): Justin Caram, Belle Coffey

Keywords(s): Biochemistry, Chemical, Electronics & Semiconductors, Imaging, Infrared, infrared thermal imaging, Light-Emitting Diode, Materials, Microscale Chemistry, Nanomaterials, nanophotonics, near-infrared, Optoelectronic materials, Optoelectronics, photodetection, photoluminescence, photostability, Quantum Dot, Semiconductor, Semiconductors

Category(s): Electrical > Imaging, Chemical, Optics & Photonics, Materials > Nanotechnology, Chemical > Instrumentation & Analysis, Electrical > Sensors, Materials > Semiconducting Materials

A Chemical-Dedoping Strategy to Tailor Electron Density in Molecular-Intercalated Bulk Monolayer MOS2 (Case No. 2024-022)

Summary: UCLA researchers in the Department of Chemistry & Biochemistry have developed a novel strategy to decouple the interlayer interactions in bulk MoS2 to produce a bulk material with desirable monolayer properties. Background: Molybdenum disulfide (MoS2) is a popular and well-studied 2D semiconducting layered material. A single layer, or...

Published: 2/14/2025 | Inventor(s): Xiangfeng Duan, Yu Huang, Boxuan Zhou

Keywords(s): bulk material, bulk monolayer, chemical dedoping, direct bandgap, Doping (Semiconductor), Electronics & Semiconductors, exciton, indirect bandgap, intercalated materials, Microelectronics Semiconductor Device Fabrication, molybdenum disulfide (MOS2), monolayer, Optoelectronic materials, Organic Semiconductor, photoluminescence, photon absorption, Semiconductor, semiconductor chip foundries, Semiconductor Device, Semiconductor Device Fabrication, Semiconductor Ohmic Contact, Semiconductor Risk Assessment, Semiconductor Sapphire, Semiconductors, spin polarization, valley polarization, zzsemiconducting materials

Category(s): Materials, Materials > Functional Materials, Materials > Semiconducting Materials, Electrical, Electrical > Electronics & Semiconductors