Mechanical, interface adhesion, and encapsulation design strategies for wearable and implantable optoelectronic devices (left). Cardiac healthcare applications of wearable and implantable ...

Conducting polymers have emerged as a pivotal class of materials for advanced optoelectronic applications owing to their tunable molecular structure, ...

2D organic-inorganic heterojunctions for applications in the field of multifunctional optoelectronic devices, including electronic devices, molecular switches, photodetectors, memory devices, ...

Optoelectronics is founded on the principles of quantum mechanics and the interaction of photons with semiconductors. Semiconductor materials, such as silicon and gallium arsenide, play a central role ...

Quantum dots, tiny semiconductors with tunable properties, are redefining optoelectronics by advancing infrared sensing, bioimaging, solar energy, and more with greater efficiency and lower ...

Van der Waals heterostructures made of different two-dimensional (2D) layered materials serve as fundamental building blocks for optoelectronic devices with novel functionalities like photovoltaic ...

Optoelectronics, a sub-discipline of photonics, involves the study and application of devices that emit, detect, or control light. 1 Optoelectronic Materials (OEM) are a specific class of ...

Optoelectronics, the use of electronic devices for the detection and control of light, has become a preferred means for broadband and transoceanic communication networks. Below is a sneak peek at the ...

Optoelectronic materials, which exhibit properties of both electronics and optics, have revolutionized various technologies, including solar cells, light-emitting diodes (LEDs), and sensors. These ...