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 ...

This graphic shows how the Lewis acid treatment, p-type doping, and tin chloride concentrations and their effects on palladium diselenide, used in transistors for optoelectronic devices. Credit: Nano ...

The use of light signals to connect electronic components is a key element of today's data communication technologies, because of the speed and efficiency that only optical devices can guarantee.

Artificial intelligence (AI) is known for its high energy consumption, especially in data-intensive tasks like health monitoring. To address this, researchers have developed a flexible paper-based ...

However, a notable limitation of MoS2 is its poor absorbance in the infrared. The broadband optical detection ability, especially from ultraviolet to the near infrared range, is critical for ...

Organic-inorganic hybrid halide perovskites are regarded as the core material for next-generation optoelectronic devices due to their outstanding ...

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