Building upon the milestone reached in June 2015, FlexEnable and CPT will exhibit its glass - free, full colour, flexible AMOLED display, showcasing the performance
of organic transistors, in combination with mainstream OLED manufacturing techniques.
They are the first to apply inhomogeneous deformations, that is strain, to the conducting channel
of an organic transistor and to understand the observed effects, says Reyes - Martinez, who conducted the series of experiments as part of his doctoral work.
They are the first to apply inhomogeneous deformations, that is strain, to the conducting channel
of an organic transistor and to understand the observed effects, saysReyes - Martinez, who conducted the series of experiments as part of his doctoral work.
Not exact matches
When I was at Bell Labs, I was surrounded by amazing
organic chemists who could cook up all kinds
of interesting polymers and
organic molecules that we could use to build
transistors.
To build their
transistor, Jan Hendrik Schn
of Bell Laboratories in New Jersey and colleagues, who describe their findings in the current issue
of the journal Nature, allowed many thousands
of organic molecules to assemble themselves onto a gold film like bristles on a brush.
Henning Sirringhaus
of Cambridge and his colleagues describe in Science how they fashioned this polymer into an
organic transistor and used it to drive a conventional polymer - based LED built directly on top.
The device used a new process to make this world record - setting
organic transistor, paving the way for a new generation
of cheap, transparent electronic devices.
«Engineers make world's fastest
organic transistor, herald new generation
of see - through electronics.»
The process remains experimental, and the engineers can not yet precisely control the alignment
of organic materials in their
transistors or achieve uniform carrier mobility.
Even at this stage, off - center spin coating produced
transistors with a range
of speeds much faster than those
of previous
organic semiconductors and comparable to the performance
of the polysilicon materials used in today's high - end electronics.
In the Jan. 8 edition
of Nature Communications, engineers from the University
of Nebraska - Lincoln (UNL) and Stanford University show how they created thin - film
organic transistors that could operate more than five times faster than previous examples
of this experimental technology.
«Single - walled carbon nanotube field - effect
transistors (FETs) have characteristics similar to polycrystalline silicon FETs, a thin film silicon
transistor currently used to drive the pixels in
organic light - emitting (OLED) displays,» said Mark Hersam, Dodabalapur's coworker and a professor in the McCormick School
of Engineering and Applied Science at Northwestern University.
On page 314
of this issue, Tee et al. (3) report a Digital Tactile System («DiTact») based on a low - power flexible
organic transistor circuit that transduces pressure stimuli into oscillating signals like those generated by skin mechanoreceptors.
The structural investigations
of model
organic systems like pentacene in the monolayer regime is very important for fundamental understanding
of the initial nucleation process together with the electronic performance
of transistor devices.
His research led to the discovery
of a liquid crystalline thiophene polymer which has served for over a decade as a benchmark semiconductor, employed in fundamental studies
of the properties
of organic field effect
transistors, demonstrating the feasibility
of solution processed
organic polymers, and provided the impetus for advances in the field.
Instead
of using traditional silicon
transistors, our active - matrix backplane consists
of organic thin film
transistors (OTFTs) on PET; that's exactly the same plastic used to make cola bottles.
Durable, flexible displays have been made possible by our leadership in plastic electronics technology and our development and industrialisation
of the
organic thin film
transistor (OTFT).
They are more flexible than many other companies offerings because instead
of using traditional silicon
transistors, their active - matrix backplane consists
of organic thin film
transistors (OTFTs) on PET; that's exactly the same plastic used to make cola bottles.
This paper summarizes work that demonstrates many
of these characteristics in a realistic system:
organic active matrix backplane circuits (256
transistors) for large (≈ 5 × 5 - inch) mechanically flexible sheets
of electronic paper, an emerging type
of display.
The collaboration is based on the deposition
of organic printed photodetectors (OPD), pioneered by ISORG, onto a plastic
organic thin - film
transistor (OTFT) backplane, developed by Plastic Logic, to create a flexible sensor array.
The success
of this effort relies on new or improved processing techniques and materials for plastic electronics, including methods for (i) rubber stamping (microcontact printing) high - resolution (≈ 1 μm) circuits with low levels
of defects and good registration over large areas, (ii) achieving low leakage with thin dielectrics deposited onto surfaces with relief, (iii) constructing high - performance
organic transistors with bottom contact geometries, (iv) encapsulating these
transistors, (v) depositing, in a repeatable way,
organic semiconductors with uniform electrical characteristics over large areas, and (vi) low - temperature (≈ 100 °C) annealing to increase the on / off ratios
of the
transistors and to improve the uniformity
of their characteristics.
(PhysOrg.com)-- A clever but simple new way
of making
transistors out
of high - performance
organic microwires presents a potential path for products such as smart merchandise tags, light and cheap solar panels, and flexible...
Providing insight into a frustrating inconsistency in the performance
of electronics made with
organic materials, Stanford researchers have shown that the way boundaries between individual crystals in a film are aligned can make a 70-fold difference in how easily current, or electrical charges, can move through
transistors.
Instead
of using traditional silicon
transistors, our active - matrix backplane consists
of organic thin film
transistors (OTFTs) made from the same plastic used to for cola bottles (PET).