Organic Electrochemical Transistors (OECTs) Toward Flexible and Wearable Bioelectronics
Organic electronics have emerged as a fascinating area of research and technology in the past two decades and are anticipated to replace classic inorganic semiconductors in many applications.
Ariana Villarroel Marquez +2 more
exaly +8 more sources
Balanced Ambipolar OECTs through Tunability of Blend Microstructure [PDF]
Organic electrochemical transistors (OECTs) are promising building blocks for bioelectronics, bridging ionic biological signals and electronic circuits. Ambipolar OECTs, capable of both n- and p-type charge transport, are highly desirable for versatile bioelectronic applications, offering a simplified circuit design and enhanced sensing capabilities ...
Gitti L Frey
exaly +4 more sources
Charge-Based Compact Modeling of OECTs for Neuromorphic Applications
Organic electrochemical transistors (OECTs) are a class of promising neuromorphic devices due to their exceptional conductivity, ease of fabrication, and cost-effectiveness.
Ghader Darbandy +2 more
exaly +4 more sources
Logic Circuits Featuring Organic Electrochemical Transistors: What is the Logic Behind OECTs in Logic? [PDF]
For bioelectronic applications, the optimal electronic device is one capable of effectively interfacing with living systems by coupling electronic conduction and the ionic conduction which underlies signal transmission in physiological environments.
Damià Mawad
exaly +4 more sources
Investigation of Transport in OECTs with Electrochemical Strain Wave Microscopy. [PDF]
Abstract Understanding microscopic mixed ionic‐electronic conduction in organic electrochemical transistor (OECTs) is crucial to advance bioelectronic, neuromorphic, and sensing applications. In this work, electrochemical strain wave (ESW) microscopy is introduced as a novel approach to probe transport processes in the OECT channel at
Bonafè F +4 more
europepmc +5 more sources
Erratum to “Charge-Based Compact Modeling of OECTs for Neuromorphic Applications”
Presents corrections to the paper, (Erratum to “Charge-Based Compact Modeling of OECTs for Neuromorphic Applications”)
Ghader Darbandy +2 more
exaly +3 more sources
Device Physics, Modeling and Simulation of Organic Electrochemical Transistors
In this work, we investigate organic electrochemical transistors (OECTs) as a novel artificial electronic device for the realization of synaptic behavior, bioelectronics, and a variety of applications. A numerical method considering the Poisson-Boltzmann
Malte Koch +7 more
doaj +2 more sources
In Situ Electropolymerized Ambipolar Copolymers for Vertical OECTs
AbstractA novel approach is reported for obtaining ambipolar electroactive polymers via in situ electropolymerization for vertical organic electrochemical transistor (vOECT) applications. It is shown that electropolymerization is a practical and efficient method to obtain copolymers without contamination from chemical polymerization processes.
Roman Gańczarczyk +5 more
openaire +4 more sources
Ion Gel‐Gated Quasi‐Solid‐State Vertical Organic Electrochemical Transistor and Inverter
Parallel‐type organic electrochemical transistors (p‐OECTs) with aqueous electrolyte gate dielectrics have been widely studied for transducing biological signals into electrical signals.
Sang Young Jeong +6 more
doaj +2 more sources
Conductive Hydrogels for Exogenous Sensing and Cell Fate Control. [PDF]
We engineer electrically conductive hydrogels by combining sulfated glycosaminoglycans with semiconducting polymers. These hydrogels bind bioactive proteins, including growth factors, whose release or retention can be modulated by low‐voltage stimulation. The hydrogels are also integrated as 3D channels in organic electrochemical transistors as part of
Akbar TF +15 more
europepmc +2 more sources

