Transparent & flexible electronics
I know perfectly that many people could think: Hey guy, this stuff is only a dream, good for some sci-fi movies.
This general opinion is normal because so far we have seen electronics always opaque but, before show these project, I wanted to be sure they were feasible.
Well, if you read the ebook " A foldable world" - http://www.biodomotica.com/foldable-nanotech.htm - you will find that all this is true.
Most important universities, companies and research centers around the world are working on nanotechnology and on projects that I like: transparent electronics.
You don't need a Ph.D. in Physics to understand articles inside the ebook. At the end of reading you will begin to ask for a new foldable & transparent laptop ;-)
These devices are not yet available but are NOT sci-fi.
Printed electronics and nanotechnology will rules and changes the world before than you think.
Forget what have seen so far about electronic gadgets: printed electronics is coming with new unbelievable features.
This products will be thin, light, without wires, flexible, water-proof, shock resistant, low energy, solar recharge and recyclable.
This technology will be out of laboratory and completely available by a few years, so it’s not too early to think how the nanotechnology will change our life and how interact with invisible electronics.
Transparent and foldable electronic is a part of the coming printed electronics and these forecasts are my personal point of view:
Electronics should be user-friendly and eco-friendly, cheap and standard.
Some products will have only 2 dimensions. If you want 3rd dimension is possible use packaging technology (boxes) or glued printed electronics sheets or print directly on surfaces of 3d objects.
Philosophy of product designer is going to be more near to fashion designers or graphic designers:
products thought as dress, using ribbons and sheets.
Transparent and thin means not only invisible electronics but you can also customize it with your creativity.
Help and tutorial “how use it” are visible on the products’ surface.
With “artificial muscles” inside is possible move, vibrate or open printed sheets.
Using surface’s treatment like gecko's paws is possible shape or attach devices everywhere.
Solar nanocells recharge devices by sun or infrared rays.
Without wires for electric energy is possible use it everywhere.
Neither fall or water can damage our precious electronic friend.
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- http://en.wikipedia.org/wiki/Nano-
Nano- (symbol n) is a prefix in the metric system denoting a factor of 10−9 or 0.000000001. It is frequently
encountered in science and electronics for prefixing units of time and length, such as 30 nanoseconds
(symbol ns), 100 nanometres (nm) or in the case of electrical capacitance, 100 nanofarads (nF).
The prefix is derived from the Greek νάνος, meaning "dwarf", and was officially confirmed as standard in
1960.
In the United States, the use of the nano prefix for the farad unit of electrical capacitance is uncommon;
capacitors of that size are more often expressed in terms of a small fraction of a microfarad or a large
number of picofarads.
When used as a prefix for something other than a unit of measure, as in "nanoscience", nano means relating
to nanotechnology, or on a scale of nanometres. See nanoscopic scale.
SI prefixes
Prefix Symbol 10n Decimal Short scale Long scale
yotta Y 1024 1000000000000000000000000 Septillion Quadrillion
zetta Z 1021 1000000000000000000000 Sextillion Trilliard
exa E 1018 1000000000000000000 Quintillion Trillion
peta P 1015 1000000000000000 Quadrillion Billiard
tera T 1012 1000000000000 Trillion Billion
giga G 109 1000000000 Billion Milliard
mega M 106 1000000 Million
kilo k 103 1000 Thousand
hecto h 102 100 Hundred
deca da 101 10 Ten
10
0
1 One
deci d 10-1 0.1 Tenth
centi c 10-2 0.01 Hundredth
milli m 10-3 0.001 Thousandth
micro ì 10-6 0.000001 Millionth
nano n 10-9 0.000000001 Billionth Milliardth
pico p 10-12 0.000000000001 Trillionth Billionth
femto f 10-15 0.000000000000001 Quadrillionth Billiardth
atto a 10-18 0.000000000000000001 Quintillionth Trillionth
zepto z 10-21 0.000000000000000000001 Sextillionth Trilliardth
yocto y 10-24 0.000000000000000000000001 Septillionth Quadrillionth
The International System of Units (SI) specifies a set of unit prefixes known as SI prefixes or metric prefixes.
An SI prefix is a name that precedes a basic unit of measure to indicate a decadic multiple or fraction of the
unit. Each prefix has a unique symbol that is prepended to the unit symbol.
Name Abbrev. Decimal Representative objects with this size scale
metre m 100 Height of a 7-year-old child.
deci- dm 10-1 Size of our palm.
centi- cm 10-2 Length of a bee.
milli- mm 10-3 Thickness of ordinary paperclip.
micro- ìm 10-6 Size of typical dust particles.
nano- nm 10-9 The diametre of a C60 molecule is about 1 nm.
pico- pm 10-12 Radius of a Hydrogen Atom is about 23 pm.
femto- fm 10-15 Size of a typical nucleus of an atom is 10 fm.
atto- am 10-18 Estimated size of an electron
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GGGGGGGGrrrrrrrraaaaaaaapppppppphhhhhhhheeeeeeeennnnnnnneeeeeeee
- http://en.wikipedia.org/wiki/Graphene
Graphene is a one-atom-thick planar sheet of sp2-bonded carbon atoms that are densely packed
in a honeycomb crystal lattice. It can be viewed as an atomic-scale chicken wire made of carbon
atoms and their bonds. The name comes from GRAPHITE + ENE; graphite itself consists of many
graphene sheets stacked together.
Graphene is an atomic-scale chicken wire
made of carbon atoms.
Integrated circuits
Graphene has the ideal properties to be an excellent component of integrated circuits. Graphene has a high
carrier mobility, as well as low noise allowing it to be utilized as the channel in a FET. The issue is that single
sheets of graphene are hard to produce, and even harder to make on top of an appropriate substrate.
Researchers are looking into methods of transferring single graphene sheets from their source of origin
(mechanical exfoliation on SiO2 / Si or thermal graphitization of a SiC surface) onto a target substrate of
interest. In 2008, the smallest transistor so far, one atom thick, 10 atoms wide was made of graphene.
Transparent conducting electrodes
Graphene's high electrical conductivity and high optical transparency make it a candidate for transparent
conducting electrodes, required for such applications as touchscreens, liquid crystal displays, organic
photovoltaic cells, and OLEDs. In particular, graphene's mechanical strength and flexibility are advantageous
compared to indium tin oxide, which is brittle, and graphene films may be deposited from solution over large
areas.
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NNNNNNNNaaaaaaaannnnnnnnoooooooottttttttuuuuuuuubbbbbbbbeeeeeeeessssssss
- http://en.wikipedia.org/wiki/Carbon_nanotube
3D model of three types of single-walled carbon nanotubes.
Carbon nanotubes (CNTs) are allotropes of carbon with a nanostructure that can have a length-to-diameter
ratio greater than 1,000,000. These cylindrical carbon molecules have novel properties that make them
potentially useful in many applications in nanotechnology, electronics, optics and other fields of materials
science. They exhibit extraordinary strength and unique electrical properties, and are efficient conductors of
heat. Inorganic nanotubes have also been synthesized.
Their name is derived from their size, since the diameter of a nanotube is in the order of a few nanometers
(approximately 1/50,000th of the width of a human hair), while they can be up to several millimeters in length
(as of 2008). Nanotubes are categorized as single-walled nanotubes (SWNTs) and multi-walled nanotubes
(MWNTs).
- http://www.unidym.com/technology/about_carbon.html
What are Carbon Nanotubes?
Carbon nanotubes (CNTs) are tubular cylinders of carbon atoms that have extraordinary electrical,
mechanical, optical, thermal, and chemical properties.
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Individual carbon nanotubes can conduct electricity better than copper, possess higher tensile strength than
steel, and conduct heat better than diamond. In electronic applications, carbon nanotubes can possess higher
mobilities than single crystal silicon. All this in a material that is over 10,000 times thinner than a human hair.
There are multiple forms of carbon nanotubes, varying in diameter, length, and in the tendency of the
nanotubes to form ropes and bundles of tubes. Some forms of carbon nanotubes are metallic and highly
conducting; other forms are semiconducting, and can form the basis of electronic switches.
- http://www.unidym.com/technology/about_carbon_more.html
CARBON NANOTUBES
Carbon nanotubes (fullerene nanotubes) are part of the fullerene family of carbon materials discovered by Dr.
Richard E. Smalley and colleagues in 1985. They include single-wall carbon nanotubes (SWNTs), and nested
(endohedral or endotopic) SWNTs, i.e., one, two or more tubular fullerenes nested inside another tubular
fullerene. Each tubular fullerene is a huge carbon molecule, often having millions of carbon atoms bonded
together to form a tiny tube. Carbon nanotube diameters range from about 0.5 to about 10 nanometers (one
nanometer = 10-9 meter) and their lengths are typically between a few nanometers and tens of microns (one
micron = 10-6 meter).
Carbon is a truly remarkable atom. It readily bonds with itself into extended sheets of atoms comprising linked
hexagonal rings shown below. Each carbon atom is covalently bonded to its three nearest neighbors.
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This unique sheet structure is called graphene. Solid graphite is made up of layers of graphene stacked as
shown above. No other element in the periodic table bonds to itself in an extended network with the strength of
the carbon-carbon bond, which is among the strongest of chemical bonds. Some of the electrons in the
carbon-carbon bonds are free to move about the entire graphene sheet, rather than stay home with their donor
atoms, giving the structure good electrical conductivity. The tight coupling between atoms in the carbon-
carbon bond provides an intrinsic thermal conductivity that exceeds almost all other materials. As suggested
by the carbon nanotube figure above, the structure of a fullerene nanotube is that of a sheet of graphene,
wrapped into a tube and bonded seamlessly to itself. This is a true molecule with every atom in its place and
very few defects: an example of molecular perfection on a relatively large scale.
The special nature of the bonded carbon sheet, the molecular perfection of carbon nanotubes, and their long
tubular shape endow them with physical and chemical properties that are unlike those of any other material.
These properties include high surface area, excellent electrical and thermal conductivity, and tremendous
tensile strength, stiffness, and toughness.
In a single tube, every atom is on two surfaces - the inside and the outside, and a single gram of nanotubes
has over 2400 m2 of surface area! The nature of the carbon bonding gives the tubes their great tensile
strength and electrical and thermal conductivity. The carbon nanotubes' stiffness and toughness derives from
their molecular perfection. In most materials the actual observed stiffness and toughness are degraded very
substantially by the occurrence of defects in their structure. For example, high strength steel typically fails at
about 1% of its theoretical breaking strength. Carbon nanotubes, however, achieve values very close to their
theoretical limits because of their perfection of structure - there are no structural defects where mechanical
failures can begin! It is, however, the tubular geometry of carbon nanotubes that gives them their most exotic
properties. Depending on the orientation of the graphene sheet forming the tube's wall, the tube can be either
metallic or semiconducting. The metallic tubes conduct electricity just as metals do and the semiconducting
ones have great promise as the basic elements of a new paradigm for electronic circuitry at the molecular
level.
Basic Structure
There are literally hundreds of different carbon nanotube structures. One can identify these structures by
thinking of the carbon nanotube as a sheet of graphene wrapped into a seamless cylinder. As one might
imagine, there are many ways to wrap a graphene cylinder, and the cylinder can have a wide range of
dimensions. Soon after fullerene nanotubes were discovered, a classification scheme was devised to describe
the different conformations of graphene cylinders. This classification scheme uses an ordered pair of numbers,
(n,m), and is based upon the diagram of graphene shown below. Each carbon atom in the graphene sheet is
bonded to three other carbon atoms, forming a Y-shaped vertex of carbon-carbon bonds. In order to make a
seamless graphene tube of a uniform diameter, one must wrap the graphene sheet in a way that permits every
carbon atom in the cylinder to be bonded to three other carbon atoms where the sheet joins to itself. The
number of ways this wrapping can be achieved is countable according to the numbering scheme given in the
figure below. The unit vectors of the 2-dimensional graphene lattice are shown as a1 and a2 below. Each
vertex that could possibly join to the origin during a wrapping operation is labeled with an ordered pair wherein
the first number of the pair is the distance (in lattice repeat units) of the vertex from the origin along a1, and
the second number is the distance of the vertex from the origin along a2.
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- http://www.unidym.com/technology/cnt_application_electronics.html
Transparent Conductive Films
One of the more amazing attributes of carbon nanotubes is that they can form films that are highly electrically
conductive, but almost completely transparent. The film is only about 50 nanometers thick, and very porous.
Under an electron microscope, the film is seen to be a just a few layers of endless carbon nanotube ropes.
The films have an ideal conductivity for multiple types of touch screens which have applications including
point-of-sale terminals, games, portable computers, cell phones, personal digital assistants and many others.
The transparent films used initially for touch screens also reach any application that requires a large-area
transparent conductor, including LCD displays, plastic solar cells, and organic LED lighting, and transparent
carbon nanotube films have been demonstrated in the laboratory to be effective in all these areas.
Printable Transistors
The semiconducting properties of carbon nanotubes can be exploited to create printable transistors with
extremely high performance. Specifically, researchers have shown CNT-based transistors employing a sparse
nanotube network to achieve mobilities of 1 cm2/V-s (Schindler et al., Physica E (2006), while those using an
aligned array of single-walled nanotubes can reach as high as 480 cm2/V-s [Kang et al., Nature Nanotech. 2,
230 (2007)]. Nanotubes also prove to be useful additives to polymer-based TFTs and help to overcome some
of the shortcomings of those devices. Beyond their performance, such devices are compatible with solution-
based printing techniques, which enable dramatic cost savings in such devices as LCDs and OLED-based
displays.
Field Emission
Carbon nanotubes are the best field emitters of any known material. This is understandable, given their high
electrical conductivity, and the unbeatable sharpness of their tip. If the tip is placed close to another electrode
and a voltage is applied between the tube and electrode, a large electric field builds up near the tip of the tube.
The magnitude of the electric field is inversely proportional to the radius of curvature of the tip. Thus the
sharper the tip is, the larger the electric field. Even with only a few volts applied to an electrode a few microns
away from the nanotube tip, electric fields in the range of a millions of Volts per centimeter will build up near
the tip. These fields are large enough to pull a substantial number of electrons out of the tip. As "cold cathode"
electron emitters, carbon nanotube films have been shown to be capable of emitting over 4 Amperes per
square centimeter. Furthermore, the current is extremely stable [B.Q. Wei, et al. Appl. Phys. Lett. 79 1172
(2001)]. An immediate application of this behavior receiving considerable interest is in field-emission flat-panel
displays. Instead of a single electron gun, as in a traditional cathode ray tube display, there is a separate
electron gun for each pixel in the display. The high current density, low turn-on and operating voltage, and
steady, long-lived behavior make carbon nanotubes ideal field emitters for this application. Other applications
utilizing the field-emission characteristics of carbon nanotubes include: high-resolution x-ray sources, general
cold-cathode lighting sources, high-performance microwave tubes, lightning arrestors, and electron
microscope cathodes.
Integrated Circuits
Nanotubes might also represent a solution to thermal management problems plaguing the semiconductor
industry. As more and more transistors are packed on chips, microprocessors are getting hotter and noisier.
The industry is searching for new types of heat sinks to control temperatures on chips. Nanotubes have
tremendous thermal conductivity, and a number of firms are developing nanotube-based heat sinks. Due to
the unique conducting and semiconducting properties of nanotubes, devices based on individual carbon
nanotubes may eventually replace existing silicon devices. For example, several prototypes for future memory
devices based on nanotubes have been demonstrated. In light of their high carrying capacity, nanotubes might
replace copper interconnects in integrated circuits. Additionally, individual nanotubes have been shown to be
superior to existing silicon transistors and diodes.
- http://thefutureofthings.com/news/1106/high-speed-carbon-nanotube-based-chips.html
High Speed Carbon Nanotube Based Chips
A team of electrical engineers from Stanford University and Toshiba have developed nanotube wires that can
withstand data transfer speeds comparable to those of commercially available chips. In a paper published in
the _Nano Letters" Journal, the researchers reported they had successfully used nanotubes to wire a silicon
chip operating at the same speeds as today's processors.
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PPPPPPPPrrrrrrrriiiiiiiinnnnnnnntttttttteeeeeeeedddddddd eeeeeeeelllllllleeeeeeeeccccccccttttttttrrrrrrrroooooooonnnnnnnniiiiiiiiccccccccssssssss
- http://en.wikipedia.org/wiki/Printed_electronics
Printed electronics is a set of printing methods used to create electrical devices. Paper's rough surface and
high water absorption rate has focused attention on materials such as plastic, ceramics and silicon. Printing
typically uses common printing equipment, such as screen printing, flexography, gravure, offset lithography
and inkjet. Electrically functional electronic or optical inks are deposited on the substrate, creating active or
passive devices, such as thin film transistors or resistors. Printed electronics is expected to facilitate
widespread, very low-cost, low-performance electronics for applications such as flexible displays, smart labels,
decorative and animated posters, and active clothing that do not require high performance.
The term printed electronics is related to organic electronics or plastic electronics, in which one or more inks
are composed of carbon-based compounds. These other terms refer to the ink material, which can be
deposited by solution-based, vacuum-based or some other method. Printed electronics, in contrast, specifies
the process, and can utilize any solution-based material, including organic semiconductors, inorganic
semiconductors, metallic conductors, nanoparticles, nanotubes, etc.
- http://alislab.com/research/sub01.html
Printed electronics (also called electronic printing) is the term for a relatively new technology that defines the
printing of electronics on common media such as paper, plastic using standard printing processes. This
printing preferably utilizes common press equipment in the graphics arts industry, such as screen printing,
flexography, gravure, contact printing and offset lithography. Instead of printing graphic arts inks, families of
electrically functional electronic inks (conducting polymer, SWNT, insulator solution, etc) are used to print
active devices, such as thin film transistors, electronic paper, and flexible displays. Printed electronics is
expected to facilitate widespread and very low-cost electronics useful for applications not typically associated
with conventional silicon based electronics, such as flexible displays, RF-ID tags, printing displays, and
functional clothing.
- http://en.wikipedia.org/wiki/Conductive_polymer
Conductive polymers or more precisely intrinsically conducting polymers (ICPs) are organic polymers
that conduct electricity. Such compounds may have metallic conductivity or be semiconductors. The biggest
advantage of conductive polymers is their processability. Conductive polymers are also plastics, which are
organic polymers. Therefore, they can combine the mechanical properties (flexibility, toughness, malleability,
elasticity, etc.) of plastics with high electrical conductivity.
- http://www.nanowerk.com/spotlight/spotid=1814.php
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The fabrication of electronic devices on plastic substrates has attracted considerable recent attention owing to
the proliferation of handheld, portable consumer electronics. Plastic substrates possess many attractive
properties including biocompatibility, flexibility, light weight, shock resistance, softness and transparency.
Achieving high performance electronics or sensors on plastic substrates is difficult, because plastics melt at
temperatures above 120 degrees C. Central to continued advances in high-performance plastic electronics is
the development of robust methods for overcoming this temperature restriction. Unfortunately, high quality
semiconductors (such as silicon) require high growth temperatures, so their application to flexible plastics is
prohibited. A group of researchers at the California Institute of Technology now showed that highly ordered
films of silicon nanowires can be literally glued onto pieces of plastic to make flexible sensors with state-of-the-
art sensitivity to a range of toxic chemicals. These nanowires are crystalline wires made out of doped silicon –
the mainstay of the computer industry. By etching nanowires into a wafer of silicon, and then peeling them off
and transferring them to plastic, they developed a general, parallel, and scalable strategy for achieving high
performance electronics on low cost plastic substrates.
Photograph of the flexible sensor chip (Image: Heath Group, Caltech)
By Michael Berger, Copyright 2008 Nanowerk LLC
- http://www.gizmag.com/go/4749/picture/16223/
By Mike Hanlon September 15, 2005
First polymer electronic transistor produced completely by means of continuous mass printing technology. The
finger structure of the source/drain electrodes can be seen, behind them lies the reddish semiconsuctor layer.
The gate electrode lies invisibly behind the white insulator layer.
Source: [pmTUC] Institute for Print- und Media Technology
http://www.tu-chemnitz.de/mb/PrintMedienTech/pminstitut_en/download_en.php
- http://printedelectronics.idtechex.com/printedelectronicsworld/en/aboutus.asp
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Bending with a folded piece of paper
Last year, by stamping GaAs-based components onto a plastic film, Prof. John Rogers and his team were able
to create the array's underlying circuit. Recently, they added coiled interconnecting metal wires and electronic
components, to create a mesh-like grid of LEDs and photodetectors. That array was added to a pre-stretched
sheet of rubber, which was then itself encapsulated inside another piece of rubber, this one being bio-
compatible and transparent.
The resulting device can be twisted or stretched in any direction, with the electronics remaining unaffected
after being repeatedly stretched by up to 75 percent. The coiled wires, which spring back and forth like a
telephone cord, are the secret to its flexibility. The research was recently published in the journal Nature
Materials.
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- http://blog.targethealth.com/?p=14473
Roll-to-roll Plastic Displays
Oct 22 2010
A new company puts silicon transistors on plastic for flexible displays
This plastic material is used as the backing for Phicot’s amorphous silicon electronics. Credit: Phicot
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Organic electronics (see also Printed electronic)
- http://en.wikipedia.org/wiki/Organic_electronics
Organic electronics, or plastic electronics, is a branch of electronics that deals with conductive polymers,
plastics, or small molecules. It is called 'organic' electronics because the polymers and small molecules are
carbon-based, like the molecules of living things. This is as opposed to traditional electronics which relies on
inorganic conductors such as copper or silicon.
Conductive polymers are lighter, more flexible, and less expensive than inorganic conductors. This makes
them a desirable alternative in many applications. It also creates the possibility of new applications that would
be impossible using copper or silicon.
Organic electronics not only includes organic semiconductors, but also organic dielectrics, conductors and
light emitters.
New applications include smart windows and electronic paper. Conductive polymers are expected to play an
important role in the emerging science of molecular computers.
In general organic conductive polymers have a higher resistance and therefore conduct electricity poorly and
inefficiently, as compared to inorganic conductors. Researchers currently are exploring ways of "doping"
organic semiconductors, like melanin, with relatively small amounts of conductive metals to boost conductivity.
However, for many applications, inorganic conductors will remain the only viable option.
Organic electronics can be printed.
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IIIIIIIInnnnnnnnkkkkkkkk ffffffffoooooooorrrrrrrr ““““““““pppppppprrrrrrrriiiiiiiinnnnnnnntttttttteeeeeeeedddddddd eeeeeeeelllllllleeeeeeeeccccccccttttttttrrrrrrrroooooooonnnnnnnniiiiiiiiccccccccssssssss””””””””
- http://www.printelectronicnews.com/2820/epoxy-ink-for-printed-electronics/
Fine-Line Epoxy Ink Recommended for Printed Electronics Applications
December 2nd, 2010
Creative Materials, Inc., introduces 125-26, an exceptional conductive ink for screen- printing circuits with fine-
line widths and spaces. Creative Materials is expanding its line of products for the printed electronics market.
Our newest product, 125-26A/B119-44 is a flexible two-part epoxy ink that features superior adhesion to ITO-
coated surfaces and other low surface-energy substrates. This product has been used successfully in printed
electronics applications and is recommended where high-performance on coated substrates is necessary.
- http://www.printelectronicnews.com/2732/new-film-technologies/
New film technologies for printed polymer electronics developed
October 22nd, 2010
Conductive nano inks for flexible circuits
Bayer MaterialScience develops conductive and formable nano inks for use in areas such as printed polymer
electronics under the BayInk® name. These can be applied digitally using Depending on the process, it is
possible to apply line widths with a resolution of less than 30 micrometers that are no longer visible to the
human eye. This enables conductor tracks, contacts and electrodes to be applied much more easily and
effectively than with conventional methods, which are mostly more complicated and more energy- and
material-intensive.
The inks ad here to a very wide range of plastic films such as Makrofol® and Bayfol® and other flexible
materials, as well as to rigid substrates. The range of applications is wide – for example, as invisible conductor
tracks they can be used to simplify the complex design of touchscreens.
Customized service along the entire process chain.
- http://www.nanotech-now.com/news.cgi?story_id=36811
Conductive nano inks for printed electronics
Leverkusen | February 17th, 2010
The two conductive inks BayInk® TP S and BayInk® TP CNT from Bayer MaterialScience have been
developed primarily for use in the growing “printed electronics” market. These new inks boast excellent
adhesion to plastic films, other flexible substrates, glass, silicon and indium tin oxide.
- http://www.nanowerk.com/news/newsid=16884.php
Methode's Inkjet Printable Conductive Ink Allows Printing of Circuits on Polyester with No Secondary Curing
June 24, 2010
(Nanowerk News) Methode Development Company, a business unit of Methode Electronics, Inc., announces
that its conductive inkjet printable ink can now print circuits directly onto treated polyesters. The ink,
formulated for thermal and piezo inkjet systems, makes it possible for engineers to print working electrical
circuits, right from their desktops – facilitating product development, prototyping, and manufacturing
processes. With this technology, scale-up for high volume manufacturing can be easily achieved.
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PPPPPPPPrrrrrrrriiiiiiiinnnnnnnntttttttteeeeeeeerrrrrrrr ffffffffoooooooorrrrrrrr ““““““““pppppppprrrrrrrriiiiiiiinnnnnnnntttttttteeeeeeeedddddddd eeeeeeeelllllllleeeeeeeeccccccccttttttttrrrrrrrroooooooonnnnnnnniiiiiiiiccccccccssssssss””””””””
- http://www.ntera.com/technology/printing_processes.php
Web-Fed (Roll-to-Roll) Printed NCD Displays on Flexible Substrate
Printing Processes
NanoChromics Ink Systems are compatible with existing printing equipment and processes.
Sheet or Web-fed Screen Printing
Flexographic Printing
Inkjet Printing
Leveraging additive print processes, NanoChromics Ink Systems can be combined with other printed
electronic technologies (and traditional graphics inks) on the same substrate. Compatibility with existing,
widely available printing equipment minimizes capital investment for traditional graphics printers looking to
expand into printed electronics and functional media.
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TTTTTTTTrrrrrrrraaaaaaaannnnnnnnssssssssppppppppaaaaaaaarrrrrrrreeeeeeeennnnnnnntttttttt EEEEEEEElllllllleeeeeeeeccccccccttttttttrrrrrrrroooooooonnnnnnnniiiiiiiiccccccccssssssss
- http://www.indiastudychannel.com/resources/98936-Transparent-Electronics-or-Invisible-Electronics.aspx
Transparent Electronics -- or Invisible Electronics
Dec 2009 By Pratima
Transparent electronics is a emerging technology, which is satisfying the requirements of everything invisible
or multi-purpose objects.
What is Transparent Electronics?
Its just Technology for next generation of optoelectronic devices and employs wide band-gap semiconductors
for the realization of invisible circuits. Oxide semiconductors are very interesting materials because they
combine simultaneously high/low conductivity with high visual transparency.
How it works?
Transparent oxide semiconductor based transistors have recently been proposed using as active channel
intrinsic zinc oxide (ZnO). The main advantage of using ZnO deals with the fact that it is possible to growth
at/near room temperature high quality polycrystalline ZnO, which is a particular advantage for electronic
drivers, where the response speed is of major importance. Besides that, since ZnO is a wide band gap
material (3.4 eV), it is transparent in the visible region of the spectra and therefore, also less light sensitive.
Applications:
They have been widely used in a variety of applications like:
1.antistatic coatings
2.touch display panels
3.solar cells,
4.flat panel displays
5.heaters
6.defrosters
7.optical coatings etc
- http://kn.theiet.org/magazine/issues/1009/transparent-electronics-1009.cfm
Transparent electronics look to use in smart objects
June 2010 By Chris Edwards
Transparent electronic materials will make it possible to build a new generation of smart objects.
After crash-landing on Mars in the 2000 movie 'Red Planet', Val Kilmer tries to work out where he and his
team have wound up on the surface. So, he unrolls a see-through computer that tries to match the local
landscape with the images collected by scores of unmanned Mars probes over the years.
It was a bomb at the box office. Ten years on, 'Red Planet' is not showing much sign of becoming a cult
classic and ultimately profitable like 'Blade Runner'. But it's still inspiring engineers to work out how to make a
roll-up, see-through map.
Tolis Voutsas, director of the materials and devices applications lab at Sharp Laboratories of America, says:
''Red Planet' was shown in 2000. And we still don't have technology to do this. But thanks to Hollywood we still
have the vision.'
Director Antony Hoffman reckoned it might take a while to realise the transparent map. 'Red Planet' was set in
2056. Engineers such as Chris Bower, principal scientist at Nokia's research centre in Cambridge, are hoping
that they can develop something similar much more quickly.
Working on morph
A couple of years ago, Nokia unveiled what it called the Morph concept. A set of videos showed what the
portable computer and phone of the future might look like. Bower explained the idea at the Printed
Electronics conference in Dresden in April: 'You can take a standard candy-bar phone and transform it.
You can wrap it around your wrist so that it becomes a wearable device.
'We are working hard to enable the Morph concept. We are trying to build a library of functional surface
materials that provide the ability to change colour or haptic feedback. We also need compliancy to reshape
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26 Massimo Marrazzo - biodomotica.com
the device, with flexible and even stretchable displays. And transparency is something we require,' says
Bower, showing a Photoshop-assisted mockup of Nokia's take on the transparent navigator.
The roll-up map is not the only applications for see-through electronics. Douglas Keszler of Oregon State
University, a leading researcher into transparent metal oxides, reckons these materials will find uses in car
dashboards and windows to provide extra real estate for computer circuits.
Carbon nanotubes and plastics are vying with metal oxides for a role in transparent electronics, but the metals
have a solid lead historically.
'We believe metal oxides can enable transparent electronics and they have been around for some time,' says
Flora Li, research associate at the University of Cambridge.
In the Second World War, aircraft makers used transparent conductive oxides to deliver heat to windshields to
keep them free of ice. Indium tin oxide (ITO) has become the one material that appears almost everywhere
as a conductive coating for flat-screens and touchscreens. Unfortunately, the key component, indium, is a
very rare and expensive metal, giving researchers a strong incentive to find other options.
Peter Harrop, chairman of analyst firm IDTechEx, says: 'It's a defeat that indium tin oxide is still used for
transparent electronics. There are replacements but they need to gain traction. That is a big opportunity for
a lot of people.'
Li says ITO represents the first generation of transparent electronics, forming just passive conductors on the
surface of screens. 'The phase we are in now, we consider the second generation, allowing us to fabricate
discrete transparent components,' she claims. The coming third generation will put active transparent
components into many more devices.
Thin-film transistors made out of metal oxides date back to the the 1960s but it's only since the late 1990s that
research has shown that it is possible to create a library of standard components that you can see through.
Keszler points to a paper on the creation of a p-type transistor by Hiroshi Kawazoe and colleagues at the
Tokyo Institute of Technology in 1997 as the birth of modern transparent electronics. Up to that point, all
the conductors were n-type. With the two types available, it became feasible to build thin-film diodes and
transistors.
There is a reason why transparent metal oxides are not more widely used in electronics. As with the organic
polymers used in printed electronics, electrons do not move easily through most of them. According to
Keszler, the best materials have a conductivity more than ten times worse than the contact metals used
today in silicon chips.
Li says even with this lower performance, there is still a useful role for these devices. She compares metal
oxides to lower-grade forms of silicon used in flat-panel displays, such as polycrystalline and amorphous,
non-crystalline silicon, often called alpha-silicon.
'Polysilicon gives you great mobility. But you need to use really high temperatures to get this. Alpha-silicon you
can make at much lower temperatures but at the expense of lower mobility. This is where we believe
transparent metal oxides fit in: filling a gap between organic materials and alpha-silicon in terms of cost and
performance,' says Li.
Whereas alpha-silicon generally has a mobility of around 1cm/Vs, researchers have managed to achieve
around 30cm'/Vs for the widely available material zinc oxide, which is still five times lower than the
polysilicon used in high-end displays but is usable.
Mobility is only one of the concerns that researchers have with metal oxides. Sharp worked with startup Inpria,
which Keszler co-founded, on indium gallium zinc oxide transistors. 'However, the current doesn't saturate,'
says Voutsas, in the way that it should for a workable transistor. 'And the threshold voltage is high. That is
why you don't see a product that uses amorphous-oxide TFTs.'
As with the the transistor, researchers are working with a range of metals in the hope of finding combinations
that work. Li says many of these materials are binary oxides that are difficult to produce reliably using
sputtering - the balance between the two metals in the oxide varies, disrupting its ability to conduct
electricity.
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32 Massimo Marrazzo - biodomotica.com
EEEEEEEElllllllleeeeeeeeccccccccttttttttrrrrrrrroooooooonnnnnnnniiiiiiiicccccccc ppppppppaaaaaaaappppppppeeeeeeeerrrrrrrr //////// EEEEEEEE--------ppppppppaaaaaaaappppppppeeeeeeeerrrrrrrr //////// EEEEEEEE--------iiiiiiiinnnnnnnnkkkkkkkk®®®®®®®®
For more info about this please see:
Nanotechnology vol.2 Technology for E-books Readers (B/W & colors display)
www.biodomotica.com/public/e-paper_e-book.pdf
by Emily Cooper - http://www.cooperhawk.com/contact.htm
33. Transparent & Flexible Electronics
Massimo Marrazzo - biodomotica.com 33
PPPPPPPPrrrrrrrriiiiiiiinnnnnnnntttttttteeeeeeeedddddddd bbbbbbbbaaaaaaaatttttttttttttttteeeeeeeerrrrrrrryyyyyyyy
- http://www.gizmag.com/worlds-smallest-battery-created/17237/
World’s smallest battery created
By Darren Quick December 2010
Nano Battery A tin oxide anode contorts in response to ions flowing in as the battery charges. Sandia Labs
http://www.popsci.com/science/article/2010-12/lithium-ion-batteries-swell-and-contort-while-charging-new-study-shows
Because battery technology hasn’t developed as quickly as the electronic devices they power, a greater and
greater percentage of the volume of these devices is taken up by the batteries needed to keep them running.
Now a team of researchers working at the Center for Integrated Nanotechnologies (CINT) is claiming to have
created the world’s smallest battery, and although the tiny battery won’t be powering next year’s mobile
phones, it has already provided insights into how batteries work and should enable the development of smaller
and more efficient batteries in the future.
The tiny rechargeable, lithium-based battery was created by a team led by Sandia National Laboratories
researcher Jianyu Huang. It consists of a bulk lithium cobalt cathode three millimeters long, an ionic liquid
electrolyte, and has as its anode a single tin oxide (Sn02) nanowire 10 nanometers long and 100 nanometers
in diameter – that’s one seven-thousandth the thickness of a human hair.
Because nanowire-based materials in lithium-ion batteries offer the potential for significant improvements in
power and energy density over bulk electrodes the researchers wanted to gain an understanding of the
fundamental mechanisms by which batteries work. They therefore formed the battery inside a transmission
electron microscope (TEM) so they could study the charging and discharging of the battery in real time and at
atomic scale resolution.
By following the progression of the lithium ions as they travel along the nanowire, the researchers found that
during charging the tin oxide nanowire rod nearly doubles in length. This is far more than its diameter
increases and could help avoid short circuits that may shorten battery life. This unexpected finding goes
against the common belief of workers in the field that batteries swell across their diameter, not longitudinally.
“Manufacturers should take account of this elongation in their battery design,” Huang said. “These
observations prove that nanowires can sustain large stress (>10 GPa) induced by lithiation without breaking,
indicating that nanowires are very good candidates for battery electrodes,” he added.
Atomic-scale examination of the charging and discharging process of a single nanowire had not been possible
before because the high vacuum in a TEM made it difficult to use a liquid electrolyte. Huang’s group overcame
this problem by demonstrating that a low-vapor-pressure ionic liquid – essentially molten salt – could function
in the vacuum environment.
This means that although the work was carried out using tin oxide nanowires, Huang says the experiments
could be extended to other materials systems, either for cathode or anode studies.
“The methodology that we developed should stimulate extensive real-time studies of the microscopic
processes in batteries and lead to a more complete understanding of the mechanisms governing battery
performance and reliability,” he said. “Our experiments also lay a foundation for in-situ studies of
electrochemical reactions, and will have broad impact in energy storage, corrosion, electrodeposition and
general chemical synthesis research field.”
The research team’s work is reported in the December 10 issue of the journal Science.
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- http://www.energyharvestingjournal.com/articles/printed-lithium-reshaping-battery-00002104.asp
Energy Scavenging, Power Scavenging - Making small electronic and electric devices self-sufficient
Mar 2010 | Japan
Printed lithium reshaping battery
In February 2010, ITSUBO Advanced Materials Innovation Center and Hatanaka Electric in Japan announced
a large area printed lithium polymer battery that can be reshaped as shown in the pictures. This is the
statement from Mie Prefecture Industrial Support Center for the Promotion of Education and Science, Ministry
of Industry-Academia Collaboration Urban Areas (a development in the Mie Ise Bay area).
"This development of advanced materials and innovation creates a new generation all-solid polymer lithium
secondary battery. It is a world first because the all-solid polymer lithium secondary battery employs a printing
process.
This battery, involving new electrode material and electrode interface control technology and a new polymer
electrolyte, plus a separator, avoids the safety and reliability challenges of manufacturing polymer electrolyte
lithium ion secondary batteries. A safe, thin, bendable, large area battery has resulted, which offers ease of
stacking. Such batteries are welcome as the printed electronics sector is expected to grow rapidly.
Development of this cell is continuing at the Principal Research and Development Center for Next Generation Batteries, Mie University,
Mie Prefecture Industrial Research Institute (Kinseimatekku Co., Ltd., Kurehaerasutoma Co., Ltd., Shin-Co., Ltd., Toppan Printing Co.,
Ltd., Myeongseong Chemical Co., Ltd.). It has been jointly conducted by the government and academia."
Photos prototype polymer lithium secondary batteries
Prototype battery performance
"Cell size A6 (external dimension), cell thickness 450µm (external dimension)
Initial charge and discharge efficiency of 99%
Initial capacity of 45mAh (electrode material utilization efficiency of 80%)
Operating voltage 1.8 V (voltage at 50% depth of discharge)
Discharge rate of 0.02C ~ 1.0C of more than 100 cycle times (the current ongoing evaluation)
Operating Temperature 0 ~ 25 C°
In future, we will dramatically improve the performance of the battery cell structure design and optimization of
polymer electrolyte interface control electrode materials."
Second generation lithium batteries that are safer and have better performance are incorporated in the
Lightning Car Company's Lightning sports car, the KleenSpeed Technologies 200mph Formula One car, the
Hawkes Ocean Technologies Deepflight submarines, the PC-Aero pure electric aircraft etc. but even more
powerful batteries will be welcome.
For more read : Energy Harvesting and Storage for Electronic Devices 2009-2019
- http://newenergyandfuel.com/http:/newenergyandfuel/com/2010/01/08/printing-lithium-ion-batteries/
Printing Lithium Ion Batteries
January 2010
The Advanced Materials Innovation Center (AMIC) of MIE Industry and Enterprise Support Center, a Japan-
based foundation, has developed a lithium polymer battery that can be manufactured by printing technology.
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Massimo Marrazzo - biodomotica.com 35
Printed Lithium Ion Sheet Battery.
The research group used a normal sheet-shaped flexible substrate but employed a printing technology that
can be applied to roll-to-roll production. When a roll-to-roll production method is used, the thickness of the
flexible substrate can be reduced, enabling the manufacturing of thin batteries.
Printed Lithium Ion Sheet Battery Side View. Quite thin.
There are two battery prototypes. One has an output voltage of about 4V at room temperature while the other
has an output voltage of about 2V. The thickness of the battery is about 500µm, or 500 microns – that’s a half-
millimeter. Its negative and positive electrodes were formed on a flexible substrate by using printing
technology. The AMIC isn’t disclosing the battery capacity. That could be disappointing, but the point is to get
something small and light for something small and light. Such things at this point in time aren’t going to have
huge power demands, yet.
The AMIC says it did not use a printing technology to package the polymer electrolyte for the prototypes. Nor
did they disclose the details of the polymer electrolyte or the negative or positive electrode materials.
But the design and production by using printing technology offers reduced thickness, increased surface areas
and laminated construction. Using a roll-to-roll production, costs can be reduced, and reducing costs for
lithium technology is going to be a paramount concern.
The sheet-shaped battery is being researched to be used with a flexible solar cell and be attached to a curved
surface. If the battery is integrated with a solar cell formed on a flexible substrate, it is possible to build a sheet
that can be used both as a power generator and as power storage.
The effort is a three-year project that will end in March 2011. During the coming year, the research group
plans to improve manufacturing technologies for commercial production, determine potential applications for
the battery and set out the targets such as battery capacity.
Having the construction technology for simply sheets of batteries might open far larger fields of uses. The
capacity issue is of some concern, but 4 volts, using simple printing to construct the battery internal parts has
to have a serious impact over time as the various anode and cathode materials are adapted to the assorted
construction methods.
The lithium polymer battery is being developed in a research project of MIE Industry and Enterprise Support
Center with the partners of Toppan Printing Co Ltd., Shin-Kobe Electric Machinery Co. Ltd, Kureha Elastomer
Co. Ltd., Kinsei Matec Co. Ltd., Meisei Chemical Works Ltd., MIE University, Suzuka National College of
Technology and MIE Prefecture Industrial Research Institute.
36. Transparent & Flexible Electronics
36 Massimo Marrazzo - biodomotica.com
One has to think now that seeing something much lower in cost and simpler to manufacture will push research
for thinner and lighter substrates, innovations in the anode and cathode materials and some clever electrolyte
application processes.
This research bodes well for the future of lithium batteries. Still quite expensive, lithium needs to get the
manufacturing costs down. Perhaps printing is the path, and at 4 volts per cell, a compelling one indeed.
- http://news.cnet.com/8301-11128_3-20004170-54.html
by Martin LaMonica May 2010
CAMBRIDGE, Mass.--Scientists at the Massachusetts Institute of Technology have successfully coated paper
with a solar cell, part of a suite of research projects aimed at energy breakthroughs.
Susan Hockfield, MIT's president, and Paolo Scaroni, CEO of Italian oil company Eni, on Tuesday officially
dedicated the Eni-MIT Solar Frontiers Research Center. Eni invested $5 million into the center, which is also
receiving a $2 million National Science Foundation grant, said Vladimir Bulovic, the center's director.
The printed solar cells, which Bulovic showed at a press conference Tuesday, are still in the research phase
and are years from being commercialized.
However, the technique, in which paper is coated with organic semiconductor material using a process similar
to an inkjet printer, is a promising way to lower the weight of solar panels. "If you could use a staple gun to
install a solar panel, there could be a lot of value," Bulovic said.
Vladimir Bulovic, director of the Eni-MIT Solar Frontiers Research Center, holds a solar cell printed onto
a piece of paper to spell MIT. This is the first paper solar cell, according to MIT and Eni.
(Credit: Martin LaMonica/CNET)
The materials MIT researchers used are carbon-based dyes and the cells are about 1.5 percent to 2 percent
efficient at converting sunlight to electricity. But any material could be used if it can be deposited at room
temperature, Bulovic said. "Absolutely, the trick was coming up with ways to use paper," he said.
MIT professor Karen Gleason headed the research and has submitted a paper for scientific review but it has
not yet been published. MIT and Eni said this is the first time a solar cell has been printed on paper.
During the press conference, Scaroni said that Eni is funding the center because the company understands
that hydrocarbons will eventually run out and believes that solar can be a replacement. At the same time, he
said, current technologies are not sufficient.
"We are not very active (in alternative energy) today because we don't believe today's technologies are the
answer of our problems," he said.
Quantum dots
The paper solar cells are one of many avenues being pursued around nanoscale materials at the Eni-MIT
Solar Frontiers Center. Layers of these materials could essentially be sprayed using different manufacturing
techniques to make a thin-film solar cell on a plastic, paper, or metal foils.
37. Transparent & Flexible Electronics
Massimo Marrazzo - biodomotica.com 37
Silicon, the predominant material for solar cells, is durable and is made from abundant materials. Many
companies sell or are developing thin-film solar cells, which are less efficient but are cheaper to manufacture.
During a tour, Bulovic showed one of the center's labs, where researchers use a laser to blast light at
nanomaterials for picoseconds. A picosecond is one trillionth of a second. The laser provides data on how the
light excites electrons in the material, which will provide clues as to whether it will make a good solar cell
material, he explained.
MIT is focusing much of its effort on quantum dots, or tiny crystals that are only a few nanometers in size. A
human hair is about 50,000 to 100,000 nanometers thick.
By using different materials and sizes, researchers can fine-tune the colors of light that quantum dots can
absorb, a way of isolating good candidates for quantum dot solar cells.
Researchers at the center are also looking at different molecules or biological elements which can act as solar
cell material. These cheap thin-film materials can be used on their own or added to silicon-based solar panels
to enhance the efficiency, Bulovic said.
If 0.3 percent of the U.S. were covered with photovoltaics with 10 percent efficiency, solar power could
produce three times the country's needs, including a transition to electric vehicles, Bulovic said. For example,
the easement strip on highways could be coated with material that could capture energy from the sun.
But don't expect a revolution in solar power tomorrow.
"I'm giving you a whole bunch of hype," Bulovic said while explaining solar's potential during the tour. "It
usually takes 10 years from the time between when you invent something and you commercialize it." He
estimated that many of the technologies in the labs were in the first three years of a five-to-seven-year
development cycle
- http://laptopreviewshop.com/flexible-li-ion-battery.html
Flexible Li-Ion battery
Mircea / September 2010
Stanford scientists created a new flexible Li-Ion battery that’s as slim as a piece of paper and can easily bend.
Researchers from Stanford invented a very slim rechargeable Lithium-Ion battery (it’s only 300 µm thick) that
can easily bend.
Scientists Liangbing Hu, Hui Wu and Yi Cui managed to transform a simple piece of paper into a functional
flexible battery. The piece of paper was covered on both sides with a layer of nano-tubes and a lithium
compound. The lithium compound works as electrodes, while the nano-tubes collect and store electrical
energy. The piece of paper separates the electrodes and keeps the whole thing together.
Following tests, these batteries endured 300 charges flawlessly. This technology can easily be applied in
paper-based electronics, an area that’s constantly evolving. Also, this technology can be used to store
electrical energy, as Rice University professor Pulickel M. Ajayan states: “Such simple fabrication techniques
could prove useful for integrating other nanomaterials for building the next generation of energy-storage
devices.”
40. Transparent & Flexible Electronics
40 Massimo Marrazzo - biodomotica.com
- http://ozlab1.blogspot.com/2010_01_01_archive.html
Power cells produced T-shirt fashion
By James Sherwood July 2009
Power boffins have developed a prototype battery that’s not only lighter and thinner than existing power cells,
but is produced using a printing process.
Printed Batteries Provide Paper-Thin Power
August 2009
A team of German scientists has invented the world's first printable batteries. Thin, flexible and
environmentally friendly, the batteries can be produced in large quantities for a fraction of what it takes to
produce conventional batteries. The new battery is also different in other ways from conventional batteries.
The printable version weighs less than one gram on the scales, is not even one millimeter thick and can
therefore be integrated into bank cash cards, for example.The battery contains no mercury and is in this
respect environmentally friendly. Its voltage is 1.5 V, which lies within the normal range.
- http://www.elektor.com/news/a-printed-battery.860844.lynkx
A printed battery
March 2009
41. Transparent & Flexible Electronics
Massimo Marrazzo - biodomotica.com 41
The printed battery is an innovation developed by the department Printed Functionalities of the Fraunhofer
ENAS in Germany. Series connections of printed batteries are possible for the first time, thus integer multiples
of the nominal voltage of 1.5 V are realized (3 V, 4.5 V, 6 V).
The battery system is zinc manganese which might be regarded as environmentally friendly. Parts of the
batteries’ components may even be composed. By using high efficient printing technologies and the
adaptation of the used materials, the production yield reaches almost 100 %.
The printed batteries are especially suited for thin and flexible products. These might be e.g. intelligent chip
and sensor cards, medical patches and plasters for transdermal medication and vital signs monitoring, as well
as lab on chip analyses. The combination with other flexible or thin modules, at least, has to be accentuated.
Hereby flexible displays and solar cells may be manufactured in the same manner of preparation and
combined where required.
More info Fraunhofer website
- http://gigaom.com/cleantech/mit-researchers-print-tiny-battery-using-viruses/
MIT Researchers Print Tiny Battery Using Viruses
By Craig Rubens August 2008
Using nanorobots to build circuits is so last year’s fantasy. The latest technology of tomorrow uses viruses to
construct everything from transistors to tiny batteries to solar cells. Researchers at MIT published a paper in
the Proceedings of the National Academy of Sciences this week describing how they’ve successfully created
tiny batteries, just four- to eight-millionths of a meter in diameter, using specially designed viruses. The hope is
that these tiny batteries — which could be used in embedded medical sensors — and eventually other
electronics, could be printed easily and cheaply onto surfaces and woven into fabrics.
Viruses are very orderly little critters and in high concentrations organize themselves into patterns, without
high heat, toxic solvents or expensive equipment. By tweaking their DNA, the viruses, called M13, can be
programmed to bind to inorganic materials, like metals and semiconductors. So far, the researchers have
been able to use viruses to assemble the anode and electrolyte, two of the three main components of a
battery. Eventually the work could also be used to make tiny electronics made up of silicon-covered viruses.
Gross and cool.
“It’s not really analogous to anything that’s done now,” lead researcher Angela Belcher told MIT Technology
Review late last year when describing her work. “It’s about giving totally new kinds of functionalities to fibers.”
The idea of thread-like electronics has gotten the interest of the Army, which has been funding Belcher’s
research through the Army Research Office Institute of Collaborative Biotechnologies and the Army Research
Office Institute of Soldier Nanotechnologies. Theoretically, these fibers could be woven into soldiers’ uniforms
allowing clothing to sense biological or chemical agents as well as collect and store energy from the sun to
power any number of devices.
The team still has to create a cathode for the battery, but so far, so good; the researchers note that when a
platinum cathode is attached, “the resulting electrode arrays exhibit full electrochemical functionality.” Belcher
has also successfully created fibers that glow under UV light, tiny cobalt oxide wires and has even developed
viruses that bind to gold. We’re still waiting to see some viral bling.
42. Transparent & Flexible Electronics
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- http://www.gizmag.com/go/7018/picture/32741/
Flexible see-through battery power
By Mike Hanlon February 2007
Flexible see-through battery power
All is no longer as it seems — the clear flexible plastic in the image is a battery — it is a polymer based
rechargeable battery made by Japanese scientists. Drs Hiroyuki Nishide, Hiroaki Konishi and Takeo Suga at
Waseda University have designed the battery — which consists of a redox-active organic polymer film around
200 nanometres thick. Nitroxide radical groups are attached, which act as charge carriers. Because of its high
radical density, the battery has a high charge/discharge capacity. This is just one of many advantages the
'organic radical' battery has over other organic based materials according to the researchers. The power rate
performance is strikingly high — it only takes one minute to fully charge the battery and it has a long cycle life,
often exceeding 1,000 cycles.
The team made the thin polymer film by a solution-processable method — a soluble polymer with the radical
groups attached is _spin-coated" onto a surface. After UV irradiation, the polymer then becomes crosslinked
with the help of a bisazide crosslinking agent.
A drawback of some organic radical polymers is the fact they are soluble in the electrolyte solution which
results in self-discharging of the battery — but the polymer must be soluble so it can be spin-coated.
However, the photocrosslinking method used by the Japanese team overcomes the problem and makes the
polymer mechanically tough.
Dr Nishide said: This has been a challenging step, since most crosslinking reactions are sensitive to the
nitroxide radical."
Professor Peter Skabara, an expert in electroactive materials at the University of Strathclyde , praised the high
stability and fabrication strategy of the polymer-based battery. The plastic battery plays a part in ensuring that
organic device technologies can function in thin film and flexible form as a complete package." The news is
reported in the edition of The Royal Society of Chemistry journal Chemical Communications.
- http://www.ee-yorkshire.com/yf/services/enquire.asp?id=10%20ES%2027F3%203ISQ&EnquiryType=BBS
Transparent lithium ion secondary battery
An Andalusian University has developed a novel transparent lithium ion secondary battery comprising a first
transparent support, a first transparent electronic conductor and transparent positive and negative electrodes,
a solid lithium ion electrolyte between the negative and positive electrodes, a second transparent conductor
and a second transparent support. Its transparency to sunlight enables the integration of this battery into glass
surfaces of buildings making it suitable for an energy saving and self-sustainable system, including lighting if
combined with solar cells The invention also includes a method of manufacturing the battery.
- http://www.eu-service-
bb.de/data/newsletter/1314/transparent_lithium_ion_secondary_battery.pdf?PHPSESSID=d0c174598bdecb3c53c795480705a8c4
Enterprise Europe Pdf document: transparent_lithium_ion_secondary_battery.pdf