Printed, Flexible and Organic Electronics
Printed, Flexible and Organic Electronics
Printed Electronics, being thin film silicon or inorganic or organic semiconductors, can be used to form Thin Film Transistor Circuits (TFTCs), such as replacing the functionality of simple silicon chips. TFTCs also employ thin film conductors and dielectrics and the ultimate objective is to make many different components at the same time - such as displays, batteries, sensors, microphones etc using the same materials or at least the same deposition techniques thus saving cost and improving reliability. Some TFTCs will be capable of covering large areas to affordably form electronic billboards, smart shelves and so on. They will be lightweight, rugged and mechanically flexible. Often they will be made by rapid, high-volume reel-to-reel processing even forming a part of regular printing processes for graphics. These circuits will be cheap enough to permit electronics where envisaged silicon chips are always or almost always too expensive, where multiple components and needed, and where silicon is impracticle (e.g. not flexible, brittle, thick etc).
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2018
4 Jan 2018
LG Display unveils world's first 88-inch 8K OLED display
LG Display has developed the world's first 88-inch 8K OLED display.
4 Jan 2018
Tweaking quantum dots powers-up double-pane solar windows
Using two types of "designer" quantum dots, researchers are creating double-pane solar windows that generate electricity with greater efficiency and create shading and insulation for good measure.
4 Jan 2018
TactoTek collaborates with Dassault Systèmes
TactoTek® announced that it is collaborating with Dassault Systèmes to enable users of the 3DEXPERIENCE platform to digitally experiment with TactoTek IMSE parts.
3 Jan 2018
Atomically thin perovskites boost for future electronics
WPI-MANA has developed the world's highest performance dielectric nanofilms using atomically thin perovskites. This technology may revolutionize the next-generation of electronics.
2 Jan 2018
Sensors for Smart Garments
StretchSense is a global supplier of soft, stretchy sensors.
Included are:
1 Jan 2018
Flexible system-on-chip for internet-of-things
As the ecosystem of everyday objects embedded with technology to connect, communicate and transfer information continues to expand, scientists are challenged to find ways to enable even more physical objects to become 'smarter' and connected.
2017
29 Dec 2017
LG Display's massive surge in OLED light panel production
LG Display announced that the company started mass production at its new Gen 5 OLED light panel production line in Gumi, Korea and launched its new OLED light brand, Luflex.
27 Dec 2017
Low-cost way to make flexible, stretchable electronics
Researchers have developed a new technique for directly printing metal circuits, creating flexible, stretchable electronics. The technique can use multiple metals and substrates and is compatible with existing manufacturing systems that employ direct printing technologies.
26 Dec 2017
World record thin-film solar cell efficiency of 22.9%
Solar Frontier KK claims it has set a new world record for thin-film solar cell efficiency.
25 Dec 2017
It's all GO for cleaner, more efficient batteries
Battery power better than lithium or even solar is under development as researchers work to efficiently capture the energy of graphene oxide (GO).
22 Dec 2017
Chemists go 'back to the future' to untangle quantum dot mystery
For more than 30 years, researchers have been creating quantum dots—tiny, crystalline, nanoscale semiconductors with remarkable optical and electronic properties.
21 Dec 2017
Fully integrated circuits successfully printed directly onto fabric
If wearable electronics are to become commonplace, a breakthrough is required which allows them to be washable, stretchable and breathable. Using conventional inkjet techniques which are cheap, safe and environmentally friendly, researchers recently reported the successful printing of 2D material, creating integrated electronic circuits, directly onto fabrics.
20 Dec 2017
New theory to describe widely used material
A researcher has put forward a theoretical model that explains the coupling between ions and electrons in the widely used conducting polymer PEDOT:PSS. The model has profound implications for applications in printed electronics, energy storage in paper, and bioelectronics.
20 Dec 2017
IKEA Open Innovation Challenge in Printed Electronics
IKEA has invited a selection of companies to propose innovative ideas and technologies aiming at E-labels and/or Digital Communication Carriers.
19 Dec 2017
Industry-first optical-based fingerprint sensors for smartphones
Synaptics Incorporated announced an industry-first family of Natural ID™ biometric authentication solutions that leverage high-performance, highly secure optical-based fingerprint sensors for smartphones and tablets.
19 Dec 2017
Sensor & Actuator Research - New Technology
New research at BSAC will have even greater impacts on consumer, industrial, and medical products.
Included are:
18 Dec 2017
Engineers create artificial graphene
Researchers are the first to observe the electronic structure of graphene in an engineered semiconductor; finding could lead to progress in advanced optoelectronics and data processing.
15 Dec 2017
Chemists synthesize narrow ribbons of graphene using light and heat
Silicon — the shiny, brittle metal commonly used to make semiconductors — is an essential ingredient of modern-day electronics. But as electronic devices have become smaller and smaller, creating tiny silicon components that fit inside them has become more challenging and more expensive.
15 Dec 2017
'Origami' lattices with nano-scale surface ornaments
Inspired by the Japanese art of paper folding (origami), researchers are developing an alternative to 3D printing that allows the final products to have many more functionalities than what is possible with 3D printing.
14 Dec 2017
Revolutionizing electronics using Kirigami
A research team has developed an ultrastretchable bioprobe using Kirigami designs. The Kirigami-based bioprobe enables one to follow the shape of spherical and large deformable biological samples such as heart and brain tissues.
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