Results 1 to 10 of about 2,672,637 (198)

Organic Electronics in Biosensing: A Promising Frontier for Medical and Environmental Applications. [PDF]

Biosensors (Basel), 2023
The promising field of organic electronics has ushered in a new era of biosensing technology, thus offering a promising frontier for applications in both medical diagnostics and environmental monitoring.
Kaushal JB, Raut P, Kumar S.
europepmc   +3 more sources

A comprehensive nano-interpenetrating semiconducting photoresist toward all-photolithography organic electronics. [PDF]

Sci Adv, 2021
A semiconducting photoresist contributes to precise and reliable manufacture of highly integrated organic electronics. Owing to high resolution, reliability, and industrial compatibility, all-photolithography is a promising strategy for industrial ...
Chen R, Wang X, Li X, Wang H, He M, Yang L, Guo Q, Zhang S, Zhao Y, Li Y, Liu Y, Wei D.   +11 more
europepmc   +2 more sources

Biodegradation of bio-sourced and synthetic organic electronic materials towards green organic electronics. [PDF]

Nat Commun, 2021
Ubiquitous use of electronic devices has led to an unprecedented increase in related waste as well as the worldwide depletion of reserves of key chemical elements required in their manufacturing.
Di Mauro E, Rho D, Santato C.
europepmc   +2 more sources

Interface Engineering in Organic Electronics: Energy-Level Alignment and Charge Transport. [PDF]

Small Sci, 2021
Organic light‐emitting diodes (OLEDs) and organic solar cells are new members of trillion‐dollar semiconductor industry. The structure of these devices generally consists of a stack of several organic layers sandwiched between two electrodes.
Li P, Lu ZH.
europepmc   +2 more sources

Breath figure-derived porous semiconducting films for organic electronics. [PDF]

Sci Adv, 2020
We show here that breath figure–derived semiconducting films are suitable and universal for porous organic electronics. Porous semiconductor film morphologies facilitate fluid diffusion and mass transport into the charge-carrying layers of diverse ...
Zhang X, Wang B, Huang L, Huang W, Wang Z, Zhu W, Chen Y, Mao Y, Facchetti A, Marks TJ.   +9 more
europepmc   +2 more sources

Organic Electronics [PDF]

International Journal of Photoenergy, 2013
K. N. Narayanan Unni, Himadri S. Majumdar, Manoj A. G. Nambuthiry   +2 more
doaj   +9 more sources

Nanoparticles for organic electronics applications

Materials Research Express, 2020
Recently, the research in solution-based, small-molecule organic semiconductors has achieved great progress, although their application in organic electronics devices is still restricted by a variety of issues, including crystal misorientation ...
Zhengran He, Ziyang Zhang, Sheng Bi
doaj   +2 more sources

Making silver a stronger n-dopant than cesium via in situ coordination reaction for organic electronics. [PDF]

Nat Commun, 2019
N-doping is an effective way to increase the electron conductivity of organic semiconductors and achieve ohmic cathode contacts in organic electronics.
Bin Z, Dong G, Wei P, Liu Z, Zhang D, Su R, Qiu Y, Duan L.   +7 more
europepmc   +2 more sources

Focus on organic electronics. [PDF]

Sci Technol Adv Mater, 2014
Electronically active materials, once largely the domain of inorganic metals and semiconductors, have become increasingly organic in character. Contemporary electronic materials such as light-emitting device (LED) displays, photovoltaic cells, and thin-film transistors (TFTs) all feature organic molecules with π-conjugated backbones, whose ...
Wei A, Zempo Y.
europepmc   +3 more sources

Emerging organic electronics

Materials Chemistry Frontiers, 2020
Zuo-Quan Jiang, Cyril Poriel and Nicolas Leclerc introduce the Materials Chemistry Frontiers themed collection on emerging organic electronics.
Jiang, Zuo-Quan, Poriel, Cyril, Leclerc, Nicolas   +2 more
openaire   +3 more sources