Tag Archives: textiles

Textiles that clean pollution from air and water

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I once read that you could tell what colour would be in style by looking at the river in Milan (Italy). It may or may not still be true in Milan but it seems that the practice of using the river for dumping the fashion industry’s wastewater is still current in at least some parts of the world according to a Nov. 10, 2016 news item on Nanowerk featuring Juan Hinestroza’s work on textiles that clear pollution,

A stark and troubling reality helped spur Juan Hinestroza to what he hopes is an important discovery and a step toward cleaner manufacturing.

Hinestroza, associate professor of fiber science and director of undergraduate studies in the College of Human Ecology [Cornell University], has been to several manufacturing facilities around the globe, and he says that there are some areas of the planet in which he could identify what color is in fashion in New York or Paris by simply looking at the color of a nearby river.

“I saw it with my own eyes; it’s very sad,” he said.

Some of these overseas facilities are dumping waste products from textile dying and other processes directly into the air and waterways, making no attempt to mitigate their product’s effect on the environment.

“There are companies that make a great effort to make things in a clean and responsible manner,” he said, “but there are others that don’t.”

Hinestroza is hopeful that a technique developed at Cornell in conjunction with former Cornell chemistry professor Will Dichtel will help industry clean up its act. The group has shown the ability to infuse cotton with a beta-cyclodextrin (BCD) polymer, which acts as a filtration device that works in both water and air.

A Nov. 10, 2016 Cornell University news release by Tom Fleischman provides more detail about the research,

Cotton fabric was functionalized by making it a participant in the polymerization process. The addition of the fiber to the reaction resulted in a unique polymer grafted to the cotton surface.

“One of the limitations of some super-absorbents is that you need to be able to put them into a substrate that can be easily manufactured,” Hinestroza said. “Fibers are perfect for that – fibers are everywhere.”

Scanning electron microscopy showed that the cotton fibers appeared unchanged after the polymerization reaction. And when tested for uptake of pollutants in water (bisphenol A) and air (styrene), the polymerized fibers showed orders of magnitude greater uptakes than that of untreated cotton fabric or commercial absorbents.

Hinestroza pointed to several positives that should make this functionalized fabric technology attractive to industry.

“We’re compatible with existing textile machinery – you wouldn’t have to do a lot of retooling,” he said. “It works on both air and water, and we proved that we can remove the compounds and reuse the fiber over and over again.”

Hinestroza said the adsorption potential of this patent-pending technique could extend to other materials, and be used for respirator masks and filtration media, explosive detection and even food packaging that would detect when the product has gone bad.

And, of course, he hopes it can play a role in a cleaner, more environmentally responsible industrial practices.

“There’s a lot of pollution generation in the manufacture of textiles,” he said. “It’s just fair that we should maybe use the same textiles to clean the mess that we make.”

Here’s a link to and a citation for the paper,

Cotton Fabric Functionalized with a β-Cyclodextrin Polymer Captures Organic Pollutants from Contaminated Air and Water by Diego M. Alzate-Sánchez†, Brian J. Smith, Alaaeddin Alsbaiee, Juan P. Hinestroza, and William R. Dichtel. Chem. Mater., Article ASAP DOI: 10.1021/acs.chemmater.6b03624 Publication Date (Web): October 24, 2016

Copyright © 2016 American Chemical Society

This paper is open access.

One comment, I’m not sure how this solution will benefit the rivers unless they’re thinking that textile manufacturers will filter their waste water through this new fabric.

There is another researcher working on creating textiles that remove air pollution, Tony Ryan at the University of Sheffield (UK). My latest piece about his (and Helen Storey’s) work is a July 28, 2014 posting featuring a detergent that deposits onto the fabric nanoparticles that will clear air pollution. At the time, China was showing serious interest in the product.

Self-healing lithium-ion batteries for textiles

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It’s easy to forget how hard we are on our textiles. We rip them, step on them, agitate them in water, splatter them with mud, and more. So, what happens when we integrate batteries and electronics into them? An Oct. 20, 2016 news item on phys.org describes one of the latest ‘textile batter technologies’,

Electronics that can be embedded in clothing are a growing trend. However, power sources remain a problem. In the journal Angewandte Chemie, scientists have now introduced thin, flexible, lithium ion batteries with self-healing properties that can be safely worn on the body. Even after completely breaking apart, the battery can grow back together without significant impact on its electrochemical properties.

wiley_selfhealinglithiumionbattery

© Wiley-VCH

An Oct. 20, 2016 Wiley Angewandte Chemie International Edition press release (also on EurekAlert), which originated the news item, describes some of the problems associated with lithium-ion batteries and this new technology designed to address them,

Existing lithium ion batteries for wearable electronics can be bent and rolled up without any problems, but can break when they are twisted too far or accidentally stepped on—which can happen often when being worn. This damage not only causes the battery to fail, it can also cause a safety problem: Flammable, toxic, or corrosive gases or liquids may leak out.

A team led by Yonggang Wang and Huisheng Peng has now developed a new family of lithium ion batteries that can overcome such accidents thanks to their amazing self-healing powers. In order for a complicated object like a battery to be made self-healing, all of its individual components must also be self-healing. The scientists from Fudan University (Shanghai, China), the Samsung Advanced Institute of Technology (South Korea), and the Samsung R&D Institute China, have now been able to accomplish this.

The electrodes in these batteries consist of layers of parallel carbon nanotubes. Between the layers, the scientists embedded the necessary lithium compounds in nanoparticle form (LiMn2O4 for one electrode, LiTi2(PO4)3 for the other). In contrast to conventional lithium ion batteries, the lithium compounds cannot leak out of the electrodes, either while in use or after a break. The thin layer electrodes are each fixed on a substrate of self-healing polymer. Between the electrodes is a novel, solvent-free electrolyte made from a cellulose-based gel with an aqueous lithium sulfate solution embedded in it. This gel electrolyte also serves as a separation layer between the electrodes.

After a break, it is only necessary to press the broken ends together for a few seconds for them to grow back together. Both the self-healing polymer and the carbon nanotubes “stick” back together perfectly. The parallel arrangement of the nanotubes allows them to come together much better than layers of disordered carbon nanotubes. The electrolyte also poses no problems. Whereas conventional electrolytes decompose immediately upon exposure to air, the new gel is stable. Free of organic solvents, it is neither flammable nor toxic, making it safe for this application.

The capacity and charging/discharging properties of a battery “armband” placed around a doll’s elbow were maintained, even after repeated break/self-healing cycles.

Here’s a link to and a citation for the paper,

A Self-Healing Aqueous Lithium-Ion Battery by Yang Zhao, Ye Zhang, Hao Sun, Xiaoli Dong, Jingyu Cao, Lie Wang, Yifan Xu, Jing Ren, Yunil Hwang, Dr. In Hyuk Son, Dr. Xianliang Huang, Prof. Yonggang Wang, and Prof. Huisheng Peng. Angewandte Chemie International Edition DOI: 10.1002/anie.201607951 Version of Record online: 12 OCT 2016

© 2016 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim

This paper is behind a paywall.

Cientifica’s latest smart textiles and wearable electronics report

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After publishing a report on wearable technology in May 2016 (see my June 2, 2016 posting), Cientifica has published another wearable technology report, this one is titled, Smart Textiles and Wearables: Markets, Applications and Technologies. Here’s more about the latest report from the report order page,

“Smart Textiles and Wearables: Markets, Applications and Technologies” examines the markets for textile based wearable technologies, the companies producing them and the enabling technologies. This is creating a 4th industrial revolution for the textiles and fashion industry worth over $130 billion by 2025.

Advances in fields such as nanotechnology, organic electronics (also known as plastic electronics) and conducting polymers are creating a range of textile–based technologies with the ability to sense and react to the world around them.  This includes monitoring biometric data such as heart rate, the environmental factors such as temperature and The presence of toxic gases producing real time feedback in the form of electrical stimuli, haptic feedback or changes in color.

The report identifies three distinct generations of textile wearable technologies.

First generation is where a sensor is attached to apparel and is the approach currently taken by major sportswear brands such as Adidas, Nike and Under Armour
Second generation products embed the sensor in the garment as demonstrated by products from Samsung, Alphabet, Ralph Lauren and Flex.
In third generation wearables the garment is the sensor and a growing number of companies including AdvanPro, Tamicare and BeBop sensors are making rapid progress in creating pressure, strain and temperature sensors.

Third generation wearables represent a significant opportunity for new and established textile companies to add significant value without having to directly compete with Apple, Samsung and Intel.

The report predicts that the key growth areas will be initially sports and wellbeing

followed by medical applications for patient monitoring. Technical textiles, fashion and entertainment will also be significant applications with the total market expected to rise to over $130 billion by 2025 with triple digit compound annual growth rates across many applications.

The rise of textile wearables also represents a significant opportunity for manufacturers of the advanced materials used in their manufacture. Toray, Panasonic, Covestro, DuPont and Toyobo are already suppling the necessary materials, while researchers are creating sensing and energy storage technologies, from flexible batteries to graphene supercapacitors which will power tomorrows wearables. The report details the latest advances and their applications.

This report is based on an extensive research study of the wearables and smart textile markets backed with over a decade of experience in identifying, predicting and sizing markets for nanotechnologies and smart textiles. Detailed market figures are given from 2016-2025, along with an analysis of the key opportunities, and illustrated with 139 figures and 6 tables.

The September 2016 report is organized differently and has a somewhat different focus from the report published in May 2016. Not having read either report, I’m guessing that while there might be a little repetition, you might better consider them to be companion volumes.

Here’s more from the September 2016 report’s table of contents which you can download from the order page (Note: The formatting has been changed),

SMART TEXTILES AND WEARABLES:
MARKETS, APPLICATIONS AND
TECHNOLOGIES

Contents  1
List of Tables  4
List of Figures  4
Introduction  8
How to Use This Report  8
Wearable Technologies and the 4Th Industrial Revolution  9
The Evolution of Wearable Technologies  10
Defining Smart Textiles  15
Factors Affecting The Adoption of Smart Textiles for Wearables  18
Cost  18
Accuracy  18
On Shoring  19
Power management  19
Security and Privacy  20
Markets  21
Total Market Growth and CAGR  21
Market Growth By Application  21
Adding Value To Textiles Through Technology  27
How Nanomaterials Add Functionality and Value  31
Business Models  33
Applications  35
Sports and Wellbeing  35
1st Generation Technologies  35
Under Armour Healthbox Wearables  35
Adidas MiCoach  36
Sensoria  36
EMPA’s Long Term Research  39
2nd Generation Technologies  39
Google’s Project Jacquard  39
Samsung Creative Lab  43
Microsoft Collaborations  44
Intel Systems on a Chip  44
Flex (Formerly Flextronics) and MAS Holdings  45
Jiobit  46
Asensei Personal Trainer  47
OmSignal Smart Clothing  48
Ralph Lauren PoloTech  49
Hexoskin Performance Management  50
Jabil Circuit Textile Heart Monitoring  51
Stretch Sense Sensors  52
NTT Data and Toray  54
Goldwin Inc. and DoCoMo  55
SupaSpot Inc Smart Sensors  55
Wearable Experiments and Brand Marketing  56
Wearable Life Sciences Antelope  57
Textronics NuMetrex  59
3rd Generation Technologies  60
AdvanPro Pressure Sensing Shoes  60
Tamicare 3D printed Wearables with Integrated Sensors  62
AiQ Smart Clothing Stainless Steel Yarns  64
Flex Printed Inks And Conductive Yarns  66
Sensing Tech Conductive Inks  67
EHO Textiles Body Motion Monitoring  68
Bebop Sensors Washable E-Ink Sensors  70
Fraunhofer Institute for Silicate Research Piezolectric Polymer
Sensors  71
CLIM8 GEAR Heated Textiles  74
VTT Smart Clothing Human Thermal Model  74
ATTACH (Adaptive Textiles Technology with Active Cooling and Heating) 76
Energy Storage and Generation  78
Intelligent Textiles Military Uniforms  78
BAE Systems Broadsword Spine  79
Stretchable Batteries  80
LG Chem Cable Batteries  81
Supercapacitors  83
Swinburne Graphene Supercapacitors  83
MIT Niobium Nanowire Supercapacitors  83
Energy Harvesting  86
Kinetic  86
StretchSense Energy Harvesting Kit  86
NASA Environmental Sensing Fibers  86
Solar  87
Powertextiles  88
Sphelar Power Corp Solar Textiles  88
Ohmatex and Powerweave  89
Fashion  89
1st Generation Technologies  92
Cute Circuit LED Couture  92
MAKEFASHION LED Couture  94
2nd Generation Technologies  94
Covestro Luminous Clothing  94
3rd Generation Technologies  96
The Unseen Temperature Sensitive Dyes  96
Entertainment  98
Wearable Experiments Marketing  98
Key Technologies 100
Circuitry  100
Conductive Inks for Fabrics  100
Conductive Ink For Printing On Stretchable Fabrics  100
Creative Materials Conductive Inks And Adhesives  100
Dupont Stretchable Electronic Inks  101
Aluminium Inks From Alink Co  101
Conductive Fibres  102
Circuitex Silver Coated Nylon  102
Textronics Yarns and Fibres  102
Novonic Elastic Conductive Yarn  103
Copper Coated Polyacrylonitrile (PAN) Fibres  103
Printed electronics  105
Covestro TPU Films for Flexible Circuits  105
Sensors  107
Electrical  107
Hitoe  107
Cocomi  108
Panasonic Polymer Resin  109
Cardiac Monitoring  110
Mechanical  113
Strain  113
Textile-Based Weft Knitted Strain Sensors  113
Chain Mail Fabric for Smart Textiles  113
Nano-Treatment for Conductive Fiber/Sensors 115
Piezoceramic materials  116
Graphene-Based Woven Fabric  117
Pressure Sensing  117
LG Innotek Flexible Textile Pressure Sensors  117
Hong Kong Polytechnic University Pressure Sensing Fibers  119
Conductive Polymer Composite Coatings  122
Printed Textile Sensors To Track Movement  125
Environment  127
Photochromic Textiles  127
Temperature  127
Sefar PowerSens  127
Gasses & Chemicals  127
Textile Gas Sensors  127
Energy  130
Storage  130
Graphene Supercapacitors  130
Niobium Nanowire Supercapacitors  130
Stretchy supercapacitors  132
Energy Generation  133
StretchSense Energy Harvesting Kit  133
Piezoelectric Or Thermoelectric Coated Fibres  134
Optical  137
Light Emitting  137
University of Manchester Electroluminescent Inks and Yarns 137
Polyera Wove  138
Companies Mentioned  141
List of Tables
Table 1 CAGR by application  22
Table 2 Value of market by application 2016-25 (millions USD)  24
Table 3 % market share by application  26
Table 4 CAGR 2016-25 by application  26
Table 5 Technology-Enabled Market Growth in Textile by Sector (2016-22) 28
Table 6 Value of nanomaterials by sector 2016-22 ($ Millions)  33
List of Figures
Figure 1 The 4th Industrial Revolution (World Economic Forum)  9
Figure 2 Block Diagram of typical MEMS digital output motion sensor: ultra
low-power high performance 3-axis “femto” accelerometer used in
fitness tracking devices.  11
Figure 3 Interior of Fitbit Flex device (from iFixit)  11
Figure 4 Internal layout of Fitbit Flex. Red is the main CPU, orange is the
BTLE chip, blue is a charger, yellow is the accelerometer (from iFixit)  11
Figure 5 Intel’s Curie processor stretches the definition of ‘wearable’  12
Figure 6 Typical Textile Based Wearable System Components  13
Figure 7 The Chromat Aeros Sports Bra “powered by Intel, inspired by wind, air and flight.”  14
Figure 8 The Evolution of Smart textiles  15
Figure 9 Goldwin’s C2fit IN-pulse sportswear using Toray’s Hitoe  16
Figure 10 Sensoglove reads grip pressure for golfers  16
Figure 11 Textile Based Wearables Growth 2016-25(USD Millions)  21
Figure 12 Total market for textile based wearables 2016-25 (USD Millions)  22
Figure 13 Health and Sports Market Size 2016-20 (USD Millions)  23
Figure 14 Health and Sports Market Size 2016-25 (USD Millions)  23
Figure 15 Critical steps for obtaining FDA medical device approval  25
Figure 16 Market split between wellbeing and medical 2016-25  26
Figure 17 Current World Textile Market by Sector (2016)  27
Figure 18 The Global Textile Market By Sector ($ Millions)  27
Figure 19 Compound Annual Growth Rates (CAGR) by Sector (2016-25)  28
Figure 20 The Global Textile Market in 2022  29
Figure 21 The Global Textile Market in 2025  30
Figure 22 Textile Market Evolution (2012-2025)  30
Figure 23 Total Value of Nanomaterials in Textiles 2012-2022 ($ Millions)  31
Figure 24 Value of Nanomaterials in Textiles by Sector 2016-2025 ($ Millions) 32
Figure 25 Adidas miCoach Connect Heart Rate Monitor  36
Figure 26 Sensoria’s Hear[t] Rate Monitoring Garments . 37
Figure 27 Flexible components used in Google’s Project Jacquard  40
Figure 28 Google and Levi’s Smart Jacket  41
Figure 29 Embedded electronics Google’s Project Jacquard  42
Figure 30 Samsung’s WELT ‘smart’ belt  43
Figure 31 Samsung Body Compass at CES16  44
Figure 32 Lumo Run washable motion sensor  45
Figure 33 OMSignal’s Smart Bra  49
Figure 34 PoloTech Shirt from Ralph Lauren  50
Figure 35 Hexoskin Data Acquisition and Processing  51
Figure 36 Peak+™ Hear[t] Rate Monitoring Garment  52
Figure 37 StretchSense CEO Ben O’Brien, with a fabric stretch sensor  53
Figure 38 C3fit Pulse from Goldwin Inc  55
Figure 39 The Antelope Tank-Top  58
Figure 40 Sportswear with integrated sensors from Textronix  60
Figure 41 AdvanPro’s pressure sensing insoles  61
Figure 42 AdvanPro’s pressure sensing textile  62
Figure 43 Tamicare 3D Printing Sensors and Apparel  63
Figure 44 Smart clothing using stainless steel yarns and textile sensors from AiQ  65
Figure 45 EHO Smart Sock  69
Figure 46 BeBop Smart Car Seat Sensor  71
Figure 47 Non-transparent printed sensors from Fraunhofer ISC  73
Figure 48 Clim8 Intelligent Heat Regulating Shirt  74
Figure 49 Temperature regulating smart fabric printed at UC San Diego  76
Figure 50 Intelligent Textiles Ltd smart uniform  79
Figure 51 BAE Systems Broadsword Spine  80
Figure 52 LG Chem cable-shaped lithium-ion battery powers an LED display even when twisted and strained  81
Figure 53 Supercapacitor yarn made of niobium nanowires  84
Figure 54 Sphelar Textile  89
Figure 55 Sphelar Textile Solar Cells  89
Figure 56 Katy Perry wears Cute Circuit in 2010  91
Figure 57 Cute Circuit K Dress  93
Figure 58 MAKEFASHION runway at the Brother’s “Back to Business” conference, Nashville 2016  94
Figure 59 Covestro material with LEDs are positioned on formable films made from thermoplastic polyurethane (TPU).  95
Figure 60 Unseen headpiece, made of 4000 conductive Swarovski stones, changes color to correspond with localized brain activity  96
Figure 61 Eighthsense a coded couture piece.  97
Figure 62 Durex Fundawear  98
Figure 63 Printed fabric sensors from the University of Tokyo  100
Figure 64 Tony Kanaan’s shirt with electrically conductive nano-fibers  107
Figure 65 Panasonic stretchable resin technology  109
Figure 66 Nanoflex moniroring system  111
Figure 67 Knitted strain sensors  113
Figure 68 Chain Mail Fabric for Smart Textiles  114
Figure 69 Electroplated Fabric  115
Figure 70 LG Innotek flexible textile pressure sensors  118
Figure 71 Smart Footwear installed with fabric sensors. (Credit: Image courtesy of The Hong Kong Polytechnic University)  120
Figure 72 SOFTCEPTOR™ textile strain sensors  122
Figure 73 conductive polymer composite coating for pressure sensing  123
Figure 74 Fraunhofer ISC_ printed sensor  125
Figure 75 The graphene-coated yarn sensor. (Image: ETRI)  128
Figure 76 Supercapacitor yarn made of niobium nanowires  131
Figure 77 StretchSense Energy Harvesting Kit  134
Figure 78 Energy harvesting textiles at the University of Southampton  135
Figure 79 Polyera Wove Flexible Screen  139

If you compare that with the table of contents for the May 2016 report in my June 2, 2016 posting, you can see the difference.

Here’s one last tidbit, a Sept. 15, 2016 news item on phys.org highlights another wearable technology report,

Wearable tech, which was seeing sizzling sales growth a year ago [2015], is cooling this year amid consumer hesitation over new devices, a survey showed Thursday [Sept. 15, 2016].

The research firm IDC said it expects global sales of wearables to grow some 29.4 percent to some 103 million units in 2016.

That follows 171 percent growth in 2015, fueled by the launch of the Apple Watch and a variety of fitness bands.

“It is increasingly becoming more obvious that consumers are not willing to deal with technical pain points that have to date been associated with many wearable devices,” said IDC analyst Ryan Reith.

So-called basic wearables—including fitness bands and other devices that do not run third party applications—will make up the lion’s share of the market with some 80.7 million units shipped this year, according to IDC.

According to IDC, it seems that the short term does not promise the explosive growth of the previous year but that new generations of wearable technology, according to both IDC and Cientifica, offer considerable promise for the market.

Cooling the skin with plastic clothing

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Rather that cooling or heating an entire room, why not cool or heat the person? Engineers at Stanford University (California, US) have developed a material that helps with half of that premise: cooling. From a Sept. 1, 2016 news item on ScienceDaily,

Stanford engineers have developed a low-cost, plastic-based textile that, if woven into clothing, could cool your body far more efficiently than is possible with the natural or synthetic fabrics in clothes we wear today.

Describing their work in Science, the researchers suggest that this new family of fabrics could become the basis for garments that keep people cool in hot climates without air conditioning.

“If you can cool the person rather than the building where they work or live, that will save energy,” said Yi Cui, an associate professor of materials science and engineering and of photon science at Stanford.

A Sept. 1, 2016 Stanford University news release (also on EurekAlert) by Tom Abate, which originated the news item, further explains the information in the video,

This new material works by allowing the body to discharge heat in two ways that would make the wearer feel nearly 4 degrees Fahrenheit cooler than if they wore cotton clothing.

The material cools by letting perspiration evaporate through the material, something ordinary fabrics already do. But the Stanford material provides a second, revolutionary cooling mechanism: allowing heat that the body emits as infrared radiation to pass through the plastic textile.

All objects, including our bodies, throw off heat in the form of infrared radiation, an invisible and benign wavelength of light. Blankets warm us by trapping infrared heat emissions close to the body. This thermal radiation escaping from our bodies is what makes us visible in the dark through night-vision goggles.

“Forty to 60 percent of our body heat is dissipated as infrared radiation when we are sitting in an office,” said Shanhui Fan, a professor of electrical engineering who specializes in photonics, which is the study of visible and invisible light. “But until now there has been little or no research on designing the thermal radiation characteristics of textiles.”

Super-powered kitchen wrap

To develop their cooling textile, the Stanford researchers blended nanotechnology, photonics and chemistry to give polyethylene – the clear, clingy plastic we use as kitchen wrap – a number of characteristics desirable in clothing material: It allows thermal radiation, air and water vapor to pass right through, and it is opaque to visible light.

The easiest attribute was allowing infrared radiation to pass through the material, because this is a characteristic of ordinary polyethylene food wrap. Of course, kitchen plastic is impervious to water and is see-through as well, rendering it useless as clothing.

The Stanford researchers tackled these deficiencies one at a time.

First, they found a variant of polyethylene commonly used in battery making that has a specific nanostructure that is opaque to visible light yet is transparent to infrared radiation, which could let body heat escape. This provided a base material that was opaque to visible light for the sake of modesty but thermally transparent for purposes of energy efficiency.

They then modified the industrial polyethylene by treating it with benign chemicals to enable water vapor molecules to evaporate through nanopores in the plastic, said postdoctoral scholar and team member Po-Chun Hsu, allowing the plastic to breathe like a natural fiber.

Making clothes

That success gave the researchers a single-sheet material that met their three basic criteria for a cooling fabric. To make this thin material more fabric-like, they created a three-ply version: two sheets of treated polyethylene separated by a cotton mesh for strength and thickness.

To test the cooling potential of their three-ply construct versus a cotton fabric of comparable thickness, they placed a small swatch of each material on a surface that was as warm as bare skin and measured how much heat each material trapped.

“Wearing anything traps some heat and makes the skin warmer,” Fan said. “If dissipating thermal radiation were our only concern, then it would be best to wear nothing.”

The comparison showed that the cotton fabric made the skin surface 3.6 F warmer than their cooling textile. The researchers said this difference means that a person dressed in their new material might feel less inclined to turn on a fan or air conditioner.

The researchers are continuing their work on several fronts, including adding more colors, textures and cloth-like characteristics to their material. Adapting a material already mass produced for the battery industry could make it easier to create products.

“If you want to make a textile, you have to be able to make huge volumes inexpensively,” Cui said.

Fan believes that this research opens up new avenues of inquiry to cool or heat things, passively, without the use of outside energy, by tuning materials to dissipate or trap infrared radiation.

“In hindsight, some of what we’ve done looks very simple, but it’s because few have really been looking at engineering the radiation characteristics of textiles,” he said.

Dexter Johnson (Nanoclast blog on the IEEE [Institute of Electrical and Electronics Engineers] website) has written a Sept. 2, 2016 posting where he provides more technical detail about this work,

The nanoPE [nanoporous polyethylene] material is able to achieve this release of the IR heat because of the size of the interconnected pores. The pores can range in size from 50 to 1000 nanometers. They’re therefore comparable in size to wavelengths of visible light, which allows the material to scatter that light. However, because the pores are much smaller than the wavelength of infrared light, the nanoPE is transparent to the IR.

It is this combination of blocking visible light and allowing IR to pass through that distinguishes the nanoPE material from regular polyethylene, which allows similar amounts of IR to pass through, but can only block 20 percent of the visible light compared to nanoPE’s 99 percent opacity.

The Stanford researchers were also able to improve on the water wicking capability of the nanoPE material by using a microneedle punching technique and coating the material with a water-repelling agent. The result is that perspiration can evaporate through the material unlike with regular polyethylene.

For those who wish to further pursue their interest, Dexter has a lively writing style and he provides more detail and insight in his posting.

Here’s a link to and a citation for the paper,

Radiative human body cooling by nanoporous polyethylene textile by Po-Chun Hsu, Alex Y. Song, Peter B. Catrysse, Chong Liu, Yucan Peng, Jin Xie, Shanhui Fan, Yi Cui. Science  02 Sep 2016: Vol. 353, Issue 6303, pp. 1019-1023 DOI: 10.1126/science.aaf5471

This paper is open access.

Cientifica’s “Wearables, Smart Textiles and Nanotechnology Applications Technologies and Markets” report

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It’s been a long time since I’ve received notice of a report from Cientifica Research and I’m glad to see another one. This is titled, Wearables, Smart Textiles and Nanotechnologies and Markets, and has just been published according to the May 26,  2016 Cientifica announcement received by email.

Here’s more from the report’s order page on the Cientifica site,

Wearables, Smart Textiles and Nanotechnology: Applications, Technologies and Markets

Price GBP 1995 / USD 2995

The past few years have seen the introduction of a number of wearable technologies, from fitness trackers to “smart watches” but with the increasing use of smart textiles wearables are set to become ‘disappearables’ as the devices merge with textiles.

The textile industry will experience a growing demand for high-tech materials driven largely by both technical textiles and the increasing integration of smart textiles to create wearable devices based on sensors.  This will enable the transition of the wearable market away from one dominated by discrete hardware based on MEMS accelerometers and smartphones. Unlike today’s ‘wearables’ tomorrow’s devices will be fully integrated into the the garment through the use of conductive fibres, multilayer 3D printed structures and two dimensional materials such as graphene.

Largely driven by the use of nanotechnologies, this sector will be one of the largest end users of nano- and two dimensional materials such as graphene, with wearable devices accounting for over half the demand by 2022. Products utilizing two dimensional materials such as graphene inks will be integral to the growth of wearables, representing a multi-billion dollar opportunity by 2022.

This represents significant opportunities for both existing smart textiles companies and new entrants to create and grow niche markets in sectors currently dominated by hardware manufacturers such Apple and Samsung.

The market for wearables using smart textiles is forecast to grow at a CAGR [compound annual growth rate] of 132% between 2016 and 2022 representing a $70 billion market. Largely driven by the use of nanotechnologies, this sector has the potential to be one of the largest end users of nano and two dimensional materials such as graphene, with wearable devices accounting for over half the demand by 2022.

“Wearables, Smart Textiles and Nanotechnologies: Applications, Technologies and Markets” looks at the technologies involved from antibacterial silver nanoparticles to electrospun graphene fibers, the companies applying them, and the impact on sectors including wearables, apparel, home, military, technical, and medical textiles.

This report is based on an extensive research study of the smart textile market backed with over a decade of experience in identifying, predicting and sizing markets for nanotechnologies and smart textiles. Detailed market figures are given from 2016-2022, along with an analysis of the key opportunities, and illustrated with 120 figures and 15 tables.

I always love to view the table of contents (from the report’s order page),

Table of Contents      

Executive Summary  

Why Wearable Technologies Need More than Silicon + Software

The Solution Is in Your Closet

The Shift To Higher Value Textiles

Nanomaterials Add Functionality and Value

Introduction   

Objectives of the Report

World Textiles and Clothing

Overview of Nanotechnology Applications in the EU Textile Industry

Overview of Nanotechnology Applications in the US Textile Industry

Overview of Nanotechnology Applications in the Chinese Textile Industry

Overview of Nanotechnology Applications in the Indian Textile Industry

Overview of Nanotechnology Applications in the Japanese Textile Industry

Overview of Nanotechnology Applications in the Korean Textile Industry

Textiles in the Rest of the World

Macro and Micro Value Chain of Textiles Industry

Common Textiles Industry Classifications

End Markets and Value Chain Actors

Why Textiles Adopt Nanotechnologies        

Nanotechnology in Textiles

Examples of Nanotechnology in Textiles

Nanotechnology in Some Textile-related Categories

Technical & Smart Textiles

Multifunctional Textiles

High Performance Textiles

Smart/Intelligent Textiles

Nanotechnology Hype

Current Applications of Nanotechnology in Textile Production       

Nanotechnology in Fibers and Yarns

Nano-Structured Composite Fibers

Nanotechnology in Textile Finishing, Dyeing and Coating

Nanotechnology In Textile Printing

Green Technology—Nanotechnology In Textile Production Energy Saving

Electronic Textiles and Wearables   

Nanotechnology in Electronic Textiles

Concept

Markets and Impacts

Conductive Materials

Carbon Nanotube Composite Conductive Fibers

Carbon Nanotube Yarns

Nano-Treatment for Conductive Fiber/Sensors

Textile-Based Wearable Electronics

Conductive Coatings On Fibers For Electronic Textiles

Stretchable  Electronics

Memory-Storing Fiber

Transistor Cotton for Smart Clothing

Embedding Transparent, Flexible Graphene Electrodes Into Fibers

Organic Electronic Fibers

‘Temperature Regulating Smart Fabric’

Digital System Built Directly on a Fiber

Sensors    

Shirt Button Sensors

An integrated textile heart monitoring solution

OmSignal’s  Smart Bra

Printed sensors to track movement

Textile Gas Sensors

Smart Seats To Curtail Fatigued Driving.

Wireless Brain and Heart Monitors

Chain Mail Fabric for Smart Textiles

Graphene-Based Woven Fabric

Anti-Counterfeiting and Drug Delivery Nanofiber

Batteries and Energy Storage

Flexible Batteries

Cable Batteries

Flexible Supercapacitors

Energy Harvesting Textiles

Light Emitting Textiles  

Data Transmission 

Future and Challenges of Electronic Textiles and Wearables

Market Forecast

Smart Textiles, Nanotechnology and Apparel          

Nano-Antibacterial Clothing Textiles

Nanosilver Safety Concerns

UV/Sun/Radiation Protective

Hassle-free Clothing: Stain/Oil/Water Repellence, Anti-Static, Anti-Wrinkle

Anti-Fade

Comfort Issues: Perspiration Control, Moisture Management

Creative Appearance and Scent for High Street Fashions

Nanobarcodes for Clothing Combats Counterfeiting

High Strength, Abrasion-Resistant Fabric Using Carbon Nanotube

Nanotechnology For Home Laundry

Current Adopters of Nanotechnology in Clothing/Apparel Textiles

Products and Markets

Market Forecast

Nanotechnology in Home Textiles   

Summary of Nanotechnology Applications in Home Textiles

Current Applications of Nanotechnology in Home Textiles

Current Adopters of Nanotechnology in Home Textiles

Products and Markets

Costs and Benefits

Market Forecast

Nanotechnology Applications in Military/Defence Textiles

Summary of Nanotechnology Applications in Military/Defence Textiles

Military Textiles

Current Applications of Nanotechnology in Military/Defence Textiles

Current Adopters of Nanotechnology in Military/Defence Textiles

Light Weight, Multifunctional Nanostructured Fibers and Materials

Costs and Benefits

Market Forecast

Nanotechnology Applications in Medical Textiles   

Summary of Nanotechnology Applications in Medical Textiles

Current Applications of Nanotechnology in Medical Textiles

Current Adopters of Nanotechnology in Medical Textiles

Products and Markets

Costs and Benefits

Market Forecast

Nanotechnology Applications in Sports/Outdoor Textiles   

Summary of Nanotechnology Applications in Sports/Outdoor Textiles

Current Applications of Nanotechnology in Sports/Outdoor Textiles

Current Adopters of Nanotechnology in Sports/Outdoor Textiles

Products and Markets

Costs and Benefits

Market Forecast

Nanotechnology Applications in Technical Textiles 

Summary of Nanotechnology Applications in Technical and smart textiles

Current Applications of Nanotechnology in Technical Textiles

Current Adopters of Nanotechnology in Technical and smart textiles

Products and Markets

Costs and Benefits

Market Forecast

APPENDIX I: Companies/Research Institutes Applying Nanotechnologies to the Textile Industry

Companies Working on Nanofiber Applications

Companies Working on Nanofabric Applications

Companies Working on Nano Finishing, Coating, Dyeing and Printing Applications

Companies Working on Green Nanotechnology In Textile Production Energy Saving Applications

Companies Working on E-textile Applications

Companies Working on Nano Applications in Clothing/Apparel Textiles

Companies Working on Nano Applications in Home Textiles

Companies Working on Nano Applications in Sports/Outdoor Textile

Companies Working on Nano Applications in Military/Defence Textiles

Companies Working on Nano Applications in Technical Textiles

APPENDIX II: Selected Company Profiles     

APPENDIX III: Companies Mentioned in This Report 

The report’s order page has a form you can fill out to get more information but, as far as I can tell, there is no purchase button or link to a shopping cart for purchase.

Afterthought

Recently, there was an email in my inbox touting a Canadian-based company’s underclothing made with the founder’s Sweat-Secret fabric technology (I have not been able to find any details about the technology). As this has some of the qualities being claimed for the nanotechnology-enabled textiles described in the report and the name for the company amuses me, Noody Patooty, I’m including it in this posting (from the homepage),

Organic Bamboo Fabric
The soft, breathable and thermoregulation benefits of organic bamboo fabric keep you comfortable throughout all your busy days.

Sweat-Secret™ Technology
The high performance fabric in the underarm wicks day-to-day sweat and moisture from the body preventing sweat and odour stains.

Made in Canada
From fabric to finished garment our entire collection is made in Canada using sustainable and ethical manufacturing processes.

This is not an endorsement of the Noody Patooty undershirts. I’ve never tried one.

As for the report, Tim Harper who founded Cientifica Research has in my experience always been knowledgeable and well-informed (although I don’t always agree with him). Presumably, he’s still with the company but I’m not entirely certain.

Teijin and its fibres at Nano Tech 2016

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Teijin is a Japanese chemical and pharmaceutical company known to me due to its production of nanotechnology-enabled fibres. As a consequence, a Jan. 21, 2016 news item on Nanotechnology Now piqued by interest,

Teijin Limited announced today that it will exhibit a wide range of nanotech materials and products incorporating advanced Teijin technologies during the International Nanotechnology Exhibition and Conference (nano tech 2016), the world’s largest nanotechnology show, at Tokyo Big Sight in Tokyo, Japan from January 27 to 29 [2016].

A Jan. 21, 2016 Teijin news release, which originated the news item, offers further detail,

Teijin’s booth (Stand 4E-09) will present nanotech materials and products for sustainable transportation, information and electronics, safety and protection, environment and energy, and healthcare, including the following:

– Nanofront, an ultra-fine polyester fiber with an unprecedented diameter of just 700 nanometers, features slip-resistance, heat shielding, wiping and filtering properties. It is used for diverse applications, including sportswear, cosmetics and industrial applications such as filters and heat-shielding sheets.

– Carbon nanotube yarn (CNTy) is 100%-CNT continuous yarn offering high electrical and thermal conductivity, easy handling and flexibility. Uses including space, aerospace, medical and wearable devices are envisioned. A motor using CNTy as its coil, developed by Finnish Lappeenranta University of Technology Opening a new window, will be exhibited first time in Japan.

– NanoGram Si paste is a printed electronics material containing 20nm-diameter silicon nanoparticles for photovoltaic cells capable of high conversion efficiency.

– Teijin Tetoron multilayer film is a structurally colored multilayer polyester film that utilizes the interference of each multilayer’s optical path difference rather than dyes or pigments. Decorative films for automotive and other applications will be exhibited.

– High-performance membranes, including a high-precision porous thin polyethylene membrane and multilayer membrane composites for micro filters, are moisture-permeable waterproof sheets.

– Carbon Alloy Catalyst (CAC) (under development) is platinum free catalyst made from polyacrylonitrile (precursor of carbon fiber) in combination with iron species, which is less expensive and more readily available than platinum, enabling production for reduced cost and in higher volumes. Fuel cells in which the cathode consists of the CAC without the platinum catalyst can generate exceptionally high electric power.

– Carbon nanofiber (under development) is a highly conductive carbon nanofiber with an elliptical cross section consisting of well-developed graphite layers ordered in a single direction. Envisioned applications include additives for  lithiumion secondary batteries (LIBs) , thermal conducting materials and plastic-reinforcing materials, among others.

Teijin first came to my attention in 2010 with their Morphotex product, a fabric based on the nanostructures found on the Blue Morpho butterfly’s wing. I updated the story in an April 12, 2012 posting sadly noting that Morphotex was no longer available.

For anyone interested in the exhibition, here’s the nano tech 2016 website.

Pomegranates, silver nanoparticles, and Persian carpets

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One of the issues with adding silver nanoparticles to textiles is that they wash off and eventually enter our water supply. According to a Dec. 14. 2015 news item on Nanotechnology Now, Iranian scientists has devised a technique for affixing silver nanoparticles,

Iranian researchers produced laboratorial samples of antibacterial woolen fabrics by using nanoparticles which are able to preserve their properties even after five times of washing.

A Dec. 12, 2015 Iran Nanotechnology Initiative Council (INIC) press release, which originated the news item, provides more detail,

Nanoparticles used in the production of fabrics have been produced through a cost-effective method and by using environmentally-friendly materials.

The aim of the research was to obtain an eco-friendly method for the production and application of silver nanoparticles in carpet weaving industry to create antibacterial properties in the final product. The interesting point in this research is the application of pomegranate skin as the reducer in the process to produce nanoparticles.

Results showed that pigment extracted from pomegranate skin is able to be used in the production of silver nanoparticles. Therefore, this method decreases the application of chemical reducers in the synthesis of these nanoparticles, and it also decreases the environmental pollution. In addition, the synthesized nanoparticles preserve their antibacterial properties after being loaded on woolen fiber samples. Therefore, carpets woven by these fibers have antibacterial properties and no bacteria will grow on them.

After carrying out complementary tests and producing the fabrics and fibers at a large scale, the products can be used in carpet weaving industries and also in production of medical devices.

Based on the results, fabrics completed with silver nanoparticles synthesized at low ratio of pigment have antibacterial properties and they do not affect the color of samples. Fabric samples also conserve their antibacterial properties even after five times of washing. The decrease in pH value and increase in temperature improves exhaustion of silver nanoparticles on the wool.

Here’s a link to and a citation for the paper,

Novel method for synthesis of silver nanoparticles and their application on wool by Majid Nasiri Boroumand, Majid Montazer, Frank Simon, Jolanta Liesiene, Zoran Šaponjic, Victoria Dutschk. Applied Surface Science Volume 346, 15 August 2015, Pages 477–483 doi:10.1016/j.apsusc.2015.04.047

This paper is behind a paywall.

Slaughterhouse yarn (scientists looking for business investment)

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Not everyone is going to feel comfortable with the idea of using gelatine to create fibres for yarn. Nonetheless, here’s a July 29, 2015 ETH Zurich (Swiss Federal Institute of Technology in Zurich, [Eidgenössische Technische Hochschule Zürich]) press release (also on EurekAlert) describes the research (a plea for business investment follows),

Some 70 million tonnes of fibres are traded worldwide every year. Man-made fibres manufactured from products of petroleum or natural gas account for almost two-thirds of this total. The most commonly used natural fibres are wool and cotton, but they have lost ground against synthetic fibres.

Despite their environmental friendliness, fibres made of biopolymers from plant or animal origin remain very much a niche product. At the end of the 19th century, there were already attempts to refine proteins into textiles. For example, a patent for textiles made of gelatine was filed in 1894. After the Second World War, however, the emerging synthetic fibres drove biological protein fibres swiftly and thoroughly from the market.

Over the past few years, there has been increased demand for natural fibres produced from renewable resources using environmentally friendly methods. Wool fibre in particular has experienced a renaissance in performance sportswear made of merino wool. And a few years ago, a young entrepreneur in Germany started making high-quality textiles from the milk protein casein.

New use for waste product

Now Philipp Stössel, a 28-year-old PhD student in Professor Wendelin Stark’s Functional Materials Laboratory (FML), is presenting a new method for obtaining high-quality fibres from gelatine. The method was developed in cooperation with the Advanced Fibers Laboratory at Empa St. Gallen. Stössel was able to spin the fibres into a yarn from which textiles can be manufactured.

Gelatine consists chiefly of collagen, a main component of skin, bone and tendons. Large quantities of collagen are found in slaughterhouse waste and can be easily made into gelatine. For these reasons, Stark and Stössel decided to use this biomaterial for their experiments.

Coincidence helps provide a solution

In his experiments, Stössel noticed that when he added an organic solvent (isopropyl) to a heated, aqueous gelatine solution, the protein precipitated at the bottom of the vessel. He removed the formless mass using a pipette and was able to effortlessly press an elastic, endless thread from it. This was the starting point for his unusual research work.

As part of his dissertation, Stössel developed and refined the method, which he has just recently presented in an article for the journal Biomacromolecules.

The refined method replaces the pipette with several syringe drivers in a parallel arrangement. Using an even application of pressure, the syringes push out fine endless filaments, which are guided over two Teflon-coated rolls. The rolls are kept constantly moist in an ethanol bath; this prevents the filaments from sticking together and allows them to harden quickly before they are rolled onto a conveyor belt. Using the spinning machine he developed, Stössel was able to produce 200 metres of filaments a minute. He then twisted around 1,000 individual filaments into a yarn with a hand spindle and had a glove knitted from the yarn as a showpiece.

Attractive luster

Extremely fine, the individual fibres have a diameter of only 25 micrometres, roughly half the thickness of a human hair. With his first laboratory spinning machines, the fibre thickness was 100 micrometres, Stössel recalls. That was too thick for yarn production.

Whereas natural wool fibres have tiny scales, the surface of the gelatine fibres is smooth. “As a result, they have an attractive luster,” Stössel says. Moreover, the interior of the fibres is filled with cavities, as shown by the researchers’ electron microscope images. This might also be the reason for the gelatine yarn’s good insulation, which Stössel was able to measure in comparison with a glove made of merino wool.

Water-resistant fibres

Gelatine’s major drawback is that it its water-solubility. Stössel had to greatly improve the water resistance of the gelatine yarn through various chemical processing stages. First he treated the glove with an epoxy in order to bond the gelatine components more firmly together. Next, he treated the material with formaldehyde so that it would harden better. Finally, he impregnated the yarn with lanolin, a natural wool grease, to make it supple.

As he completes his dissertation over the coming months, Stössel will research how to make the gelatine fibres even more water-resistant. Sheep’s wool is still superior to the gelatine yarn in this respect. However, Stössel is convinced that he is very close to his ultimate goal: making a biopolymer fibre from a waste product.

It’s been a few months since I’ve seen one of these pleas for commercial interest/partnership (from the press release),

Three years ago, the researchers applied for a patent on their invention. Stössel explains that they have reached the point where their capacity in the laboratory is at its limit, but commercial production will only be possible if they can find partners and funding.

Here’s a link to and a citation for the researchers’ latest published paper (there are also two previous paper listed in the press release),

Porous, Water-Resistant Multifilament Yarn Spun from Gelatin by Philipp R. Stoessel, Urs Krebs, Rudolf Hufenus, Marcel Halbeisen, Martin Zeltner, Robert N. Grass, and Wendelin J. Stark. Biomacromolecules, 2015, 16 (7), pp 1997–2005 DOI: 10.1021/acs.biomac.5b00424 Publication Date (Web): June 2, 2015

Copyright © 2015 American Chemical Society

This paper is behind a paywall.

Fully textile-embedded transparent and flexible technology?

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There are a lot of research teams jockeying for position in the transparent, flexible electrodes stakes (for anyone unfamiliar with the slang, I’m comparing the competition between various research teams to a horse race). A May 11, 2015 news item on Nanowerk describes work from an international collaboration at the University of Exeter (UK), Note: A link has been removed,

An international team of scientists, including Professor Monica Craciun from the University of Exeter, have pioneered a new technique to embed transparent, flexible graphene electrodes into fibres commonly associated with the textile industry.

The discovery could revolutionise the creation of wearable electronic devices, such as clothing containing computers, phones and MP3 players, which are lightweight, durable and easily transportable.

The international collaborative research, which includes experts from the Centre for Graphene Science at the University of Exeter, the Institute for Systems Engineering and Computers, Microsystems and Nanotechnology (INESC-MN) in Lisbon, the Universities of Lisbon and Aveiro in Portugal and the Belgian Textile Research Centre (CenTexBel), is published in the leading scientific journal Scientific Reports (“Transparent conductive graphene textile fibers”).

A May 11, 2015 University of Exeter press release (also on EurekAlert*), which originated the news item,  describes the current situation regarding transparent and flexible electrodes in textiles and how the research at Exeter improves the situation,

Professor Craciun, co-author of the research said: “This is a pivotal point in the future of wearable electronic devices. The potential has been there for a number of years, and transparent and flexible electrodes are already widely used in plastics and glass, for example. But this is the first example of a textile electrode being truly embedded in a yarn. The possibilities for its use are endless, including textile GPS systems, to biomedical monitoring, personal security or even communication tools for those who are sensory impaired.  The only limits are really within our own imagination.”

At just one atom thick, graphene is the thinnest substance capable of conducting electricity. It is very flexible and is one of the strongest known materials. The race has been on for scientists and engineers to adapt graphene for the use in wearable electronic devices in recent years.

This new research has identified that ‘monolayer graphene’, which has exceptional electrical, mechanical and optical properties, make it a highly attractive proposition as a transparent electrode for applications in wearable electronics. In this work graphene was created by a growth method called chemical vapour deposition (CVD) onto copper foil, using a state-of-the-art nanoCVD system recently developed by Moorfield.

The collaborative team established a technique to transfer graphene from the copper foils to a polypropylene fibre already commonly used in the textile industry.

Dr Helena Alves who led the research team from INESC-MN and the University of Aveiro said: “The concept of wearable technology is emerging, but so far having fully textile-embedded transparent and flexible technology is currently non-existing. Therefore, the development of processes and engineering for the integration of graphene in textiles would give rise to a new universe of commercial applications. “

Dr Ana Neves, Associate Research Fellow in Prof Craciun’s team from Exeter’s Engineering Department and former postdoctoral researcher at INESC added: “We are surrounded by fabrics, the carpet floors in our homes or offices, the seats in our cars, and obviously all our garments and clothing accessories. The incorporation of electronic devices on fabrics would certainly be a game-changer in modern technology.

“All electronic devices need wiring, so the first issue to be address in this strategy is the development of conducting textile fibres while keeping the same aspect, comfort and lightness. The methodology that we have developed to prepare transparent and conductive textile fibres by coating them with graphene will now open way to the integration of electronic devices on these textile fibres.”

Dr Isabel De Schrijver,an expert of smart textiles from CenTexBel said: “Successful manufacturing of wearable electronics has the potential for a disruptive technology with a wide array of potential new applications. We are very excited about the potential of this breakthrough and look forward to seeing where it can take the electronics industry in the future.”

Professor Saverio Russo, co-author and also from the University of Exeter, added: “This breakthrough will also nurture the birth of novel and transformative research directions benefitting a wide range of sectors ranging from defence to health care. “

In 2012 Professor Craciun and Professor Russo, from the University of Exeter’s Centre for Graphene Science, discovered GraphExeter – sandwiched molecules of ferric chloride between two graphene layers which makes a whole new system that is the best known transparent material able to conduct electricity.  The same team recently discovered that GraphExeter is also more stable than many transparent conductors commonly used by, for example, the display industry.

Here’s a link to and a citation for the paper,

Electron transport of WS2 transistors in a hexagonal boron nitride dielectric environment by Freddie Withers, Thomas Hardisty Bointon, David Christopher Hudson, Monica Felicia Craciun, & Saverio Russo. Scientific Reports 4, Article number: 4967 doi:10.1038/srep04967 Published 15 May 2014

Did they wait a year to announce the research or is this a second-go-round? In any event, it is an open access paper.

* Added EurekAlert link 1120 hours PDT on May 12, 2015.

A new approach to heating: warm the clothing not the room

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A Jan. 7, 2015 news item on ScienceDaily describes a new type of textile which could change the way we use heat (energy),

To stay warm when temperatures drop outside, we heat our indoor spaces — even when no one is in them. But scientists have now developed a novel nanowire coating for clothes that can both generate heat and trap the heat from our bodies better than regular clothes. They report on their technology, which could help us reduce our reliance on conventional energy sources, in the ACS journal Nano Letters.

A Jan. 7, 2015 American Chemical Society (ACS) news release (also on EurekAlert), which originated the news item, provides more information about energy consumption and the researchers’ proposed solution,

Yi Cui [Stanford University] and colleagues note that nearly half of global energy consumption goes toward heating buildings and homes. But this comfort comes with a considerable environmental cost – it’s responsible for up to a third of the world’s total greenhouse gas emissions. Scientists and policymakers have tried to reduce the impact of indoor heating by improving insulation and construction materials to keep fuel-generated warmth inside. Cui’s team wanted to take a different approach and focus on people rather than spaces.

The researchers developed lightweight, breathable mesh materials that are flexible enough to coat normal clothes. When compared to regular clothing material, the special nanowire cloth trapped body heat far more effectively. Because the coatings are made out of conductive materials, they can also be actively warmed with an electricity source to further crank up the heat. The researchers calculated that their thermal textiles could save about 1,000 kilowatt hours per person every year — that’s about how much electricity an average U.S. home consumes in one month.

Here’s a link to and a citation for the paper,

Personal Thermal Management by Metallic Nanowire-Coated Textile by Po-Chun Hsu, Xiaoge Liu, Chong Liu, Xing Xie, Hye Ryoung Lee, Alex J. Welch, Tom Zhao, and Yi Cui. Nano Lett., Article ASAP DOI: 10.1021/nl5036572 Publication Date (Web): November 30, 2014
Copyright © 2014 American Chemical Society

This paper is behind a paywall.