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Stretchable Electronics Market | Projected to Register a CAGR of 33.3% During 2023-2030

July 25, 2023 Audrey

Stretchable Electronics Market is projected to register a CAGR of 33.3% during 2023-2030, Says Reports Insights. The popularity of wearable devices such as smartwatches, fitness trackers, electronic textiles, etc. has soared, and enable the development of more comfortable and seamless wearable technology.

New York, July 13, 2023 (GLOBE NEWSWIRE) — The global Stretchable Electronics Market is witnessing robust growth with a significant CAGR of 33.3%, which encompass electronic devices and circuits capable of withstanding mechanical deformation while maintaining their functionality, are gaining traction across various industries.

Stretchable Electronics Market Size was valued at US$ 8,465.01 Million in 2022, and is projected to reach US$ 83,096.97 Million by 2030, growing at a CAGR of 33.3% from 2023 to 2030.

The market is being driven by factors such as the increasing demand for wearable electronics, expanding healthcare applications, growing demand for flexible displays, the rise of the Internet of Things (IoT), ongoing research and development efforts, and the integration of stretchable electronics in consumer electronics and automotive sectors. The stretchable electronics market is poised for substantial growth and holds immense potential for innovation and technological advancements.

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Key market highlights of the Stretchable Electronics Market:

1. Growing Demand for Wearable Electronics: The increasing popularity of wearable devices such as smartwatches, fitness trackers, and electronic textiles is driving the demand for stretchable electronics. These devices require flexible and stretchable components to provide a comfortable and seamless user experience, leading to the growth of the stretchable electronics market.

2. Healthcare Applications: Stretchable electronics have found extensive applications in the healthcare sector. They enable real-time health monitoring, diagnostics, and integration with biomedical implants. The healthcare industry is leveraging the flexibility and conformability of stretchable electronics to revolutionize patient care and enhance medical device functionality.

3. Rise of Flexible Displays: The demand for flexible and bendable displays is on the rise in consumer electronics, automotive, and signage applications. Stretchable display technologies offer advantages such as lightweight construction, durability, and the ability to conform to curved surfaces. This has led to increased adoption of stretchable electronics in the display industry.

4. Integration with the Internet of Things (IoT): The proliferation of IoT devices has created opportunities for stretchable electronics. IoT devices often require flexible and stretchable components to accommodate different form factors and enable seamless integration into various objects and environments. Stretchable electronics provide the necessary flexibility and durability for IoT applications.

5. Ongoing Research and Development: The stretchable electronics market is characterized by continuous research and development activities. Advancements in material science, manufacturing processes, and device integration techniques are driving innovation in the field. This ongoing R&D effort is contributing to the development of new stretchable electronic products and expanding the market opportunities.

6. Consumer Electronics and Automotive Applications: The integration of stretchable electronics in consumer electronics and automotive sectors is gaining traction. Stretchable touch panels, sensors, and interconnects offer improved functionality and design flexibility in these industries. The ability to conform to irregular

BIND connector keeps the “stretch” in stretchable electronic devices

March 2, 2023 Audrey

Whilst the field of stretchable electronics does hold a ton of guarantee, becoming a member of the factors of these kinds of equipment together can be tough. A new connector is intended to aid, as it stretches concerning the elements, additionally it links them to a single an additional in a make any difference of seconds.

As points at this time stand, the numerous pieces of stretchable electronic devices (these types of as tender-bodied robots or wearable sensors) are often glued instantly together. However, electrical indicators are unable to travel by way of the glue. Furthermore, the glue’s bond will before long crack when those people pieces are pulled in opposite instructions.

Searching for a better-operating option, an worldwide crew of experts led by Prof. Chen Xiaodong from Singapore’s Nanyang Technological College developed a ribbon-like connector known as the BIND (BIphasic, Nano-dispersed Interface).

It can be composed mostly of a tender thermoplastic that is previously extensively made use of in stretchable electronics, recognized as styrene-ethylene-butylene-styrene. Embedded within the thermoplastic matrix are electrically conductive nanoparticles of gold or silver.

When customers are assembling stretchable digital equipment, they merely press just about every conclusion of a single BIND connector to the circuitboard, and many others in each individual of two parts – the finishes securely adhere them selves to these things in just 10 seconds. The connector can then be stretched up to seven situations its comfortable length with no breaking. It also continues to carry a sturdy electrical signal amongst the parts though being stretched by up to 2.8 occasions its standard condition.

Also, a standard Peel Adhesion Take a look at confirmed that the two finishes of the connector (which are bonded to the linked parts) have 60 times the adhesion toughness of regular connective glues.

The know-how has by now been efficiently analyzed on checking devices which were hooked up to rats and human skin, in the latter scenario measuring the electrical exercise of arm muscle groups even when underwater.

“These amazing benefits confirm that our interface can be applied to build hugely functional and reputable wearable units or tender robots,” stated Nanyang’s Dr. Jiang Ying. “For example, it can be employed in large-quality wearable health and fitness trackers in which end users can extend, gesture, and move in whichever way they are most comfy with, without impacting the device’s capacity to seize and watch their physiological indicators.”

A paper on the analysis – which also involved researchers from Stanford College Shenzhen Institute of Superior Technologies Company for Science, Know-how and Exploration (A*STAR) and the Countrywide University of Singapore – was not long ago revealed in the journal Character.

Supply: Nanyang Technological College

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A new elastic polymer dielectric to build wafer-scale stretchable electronics

February 23, 2023 Audrey

A new elastic polymer dielectric to create wafer-scale stretchable electronics — Photograph of wafer-scale fabrication of intrinsically stretchable transistor arrays using a vacuum-deposited polymer dielectric. Credit rating: Prof. Donghee Son and Dr. Ja Hoon Koo.

Around the previous several yrs, content scientists and electronics engineers have been hoping to fabricate new adaptable inorganic products to create stretchable and highly performing electronic products. These products can be based mostly on distinct styles, this sort of as rigid-island energetic cells with serpentine-condition/fractal interconnections, neutral mechanical planes or bunked structures.

In spite of the major progress in the fabrication of stretchable materials, some issues have proved hard to overcome. For instance, materials with wavy or serpentine interconnect styles typically have a restricted area density and fabricating proposed stretchable components is usually equally tough and highly-priced. In addition, the stiffness of many existing stretchable materials does not match that of human skin tissue, producing them uncomfortable on the skin and as a result not excellent for making wearable technologies.

Scientists at Sungkyunkwan University (SKKU), Institute for Primary Science (IBS), Seoul Countrywide University (SNU), and Korea State-of-the-art Institute of Science and Technology (KAIST) have not long ago fabricated a vacuum-deposited elastic polymer for building stretchable electronics. This materials, released in Nature Electronics, could be applied to create stretchy discipline-outcome transistors (FETs), which are primary elements of most digital units on the market place these days.

“Just lately, a variety of techniques for adopting smooth supplies have been proposed for creating intrinsically stretchable electronics which does not require any particular structural layouts owing to their intrinsic deformability,” Donghee Son, one of the scientists who carried out the review, told Tech Xplore. “Nonetheless, this sort of gadgets utilized option-processed dielectric products and therefore face significant issues in accomplishing superior electrical performances.”

Remedy-processed organic and natural gate dielectric supplies, materials that can transmit electric power without the need of conducting it (i.e., insulating it), are not particularly suited for the generation of versatile electronics. Most notably, they have thicknesses in the micrometer-scale, very poor insulating performances, chemical instability and a small uniformity. In addition, they are normally incompatible with conventional microfabrication processes, building them tricky to develop on a large scale.

As a outcome of these restrictions, electronic factors dependent on these option-processed components are plagued by weak gate controllability and significant procedure voltages, as perfectly as a limited scalability. Son and his colleagues, together with other research groups throughout the world, have so been striving to make ultrathin, stretchable, scalable, and remarkably accomplishing dielectrics with option fabrication strategies.

“In our examine, we existing a new method to the design and style of dielectric products to take care of the aforementioned difficulties in intrinsically stretchable digital devices,” Son discussed. “Our significant-scale vacuum-deposited stretchable dielectric allows the scalable fabrication of intrinsically stretchable devices with electrical performances equivalent to all those fabricated applying the non-stretchable inorganic and stretchable organic dielectric elements (e.g., Al₂O₃ deposited by means of atomic layer deposition & spin-coated viscoelastic layer).”