Transparent Electronic PPT
Transparent electronics is an emerging science and technology field focused on producing ‘invisible’ electronic circuitry and opto-electronic devices. Applications include consumer electronics, new energy sources, and transportation; for example, automobile windshields could transmit visual information to the driver. Glass in almost any setting could also double as an electronic device, possibly improving security systems or offering transparent displays. In a similar vein, windows could be used to produce electrical power. Other civilian and military applications in this research field include realtime wearable displays. As for conventional Si/III–V-based electronics, the basic device structure is based on semiconductor junctions and transistors. However, the device building block materials, the semiconductor, the electric contacts, and the dielectric/passivation layers, must now be transparent in the visible –a true challenge! Therefore, the first scientific goal of this technology must be to discover, understand, and implement transparent high-performance electronic materials. The second goal is their implementation and evaluation in transistor and circuit structures. The third goal relates to achieving application-specific properties since transistor performance and materials property requirements vary, depending on the final product device specifications. Consequently, to enable this revolutionary technology requires bringing together expertise from various pure and applied sciences, including materials science, chemistry, physics, electrical/electronic/circuit engineering, and display science.
3. Introduction
Transparent electronics (also called as invisible
electronics) is an emerging technology.
It employs wide band-gap semiconductors for
the realization of invisible circuits and opto-
electronic devices.
In transparent electronics , the usual opaque
semiconductor materials forming the basis for
electronic device fabrication is replaced with
transparent materials.
3
5. The first scientific goal of this technology must be to
discover, understand, and implement transparent high-
performance electronic materials.
The second goal is their implementation and evaluation
in transistor and circuit structures.
The third goal relates to achieving application-specific
properties since transistor performance and materials
property requirements vary, depending on the final
product device specifications.
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6. 6
There are two technologies
which preceded and underlie
transparent electronics:
1. Transparent Conducting
Oxides (TCOs)
2. Thin Film Transistors (TFTs)
7. TCOs constitute an unusual
class of materials possessing two
contradictory physical properties:
• High optical transparency
• High electrical conductivity
The three most common TCOs
are indium oxide In2O3, tin
oxide SnO2 and zinc oxide
ZnO2.
Mate
rial
Band
gap
(eV)
Conducti
vity
(Scm-1)
Electron
Concentr
ation (cm-
3)
Mobil
ity
(cm2V-
1s-1)
In2O3 3.75 10,000 >1021 35
ZnO2 3.35 8,000 >1021 20
SnO2 3.6 5,000 >1020 15
Electrical properties of
common TCOs
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8. 8
The thin-film transistor (TFTs) is
another technology underlying
transparent electronics, since it is a
bridge between passive electrical and
active electronic applications. But it
does not evolve a fully transparent
transistor.
Two possible configurations are:
• Bottom gate
• Top gate
9. 9
The challenge for producing "invisible" electronic circuitry and
opto-electronic devices is that the transistor materials must be
transparent to visible light yet have good carrier mobilities which
requires a special class of materials having "contra-indicated
properties".
Oxide semiconductors are very interesting materials because
they combine simultaneously high/low conductivity with high
visual transparency.
Transparent oxide semiconductor based transistors have recently
been proposed using as active channel intrinsic zinc oxide (ZnO).
10. The main advantages of using ZnO are:
1. 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.
2. 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.
The second is amorphous oxides with heavy
metal content, such as amorphous InGaZnO4 (a-
IGZO) also used in this application.
A comparison of ZnO and a-IGZO shows that
ZnO has the lead when it comes to carrier
mobility. At present, though, a-IGZO is the
material of choice for large-area displays,
electronic paper utilizing low-temperature
processing, etc.
Oxides play key role:
Oxides
ZnO InGaZnO4
11. There are 2 types of technique for fabrication of
epitaxial films of semiconductors. They are
1.Vapor Phase Epitaxy
2. Reactive Solid-Phase Epitaxy
12. Researchers at Oregon State University and Hewlett Packard have reported
their first example of an entirely new class of materials which could be used to
make transparent transistors that are inexpensive, stable, and environmentally
benign.
ADVANCEMENTS MADE IN
TRANSPARENT ELECTRONICS
Significant advances in the emerging
science of transparent electronics, creating
transparent "p-type" semiconductors that
have more than 200 times the conductivity
of the best materials available for that
purpose a few years ago.
This basic research is opening the door to
new types of electronic circuits that, when
deposited onto glass, are literally invisible.
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13. 13
Characteristics other than Transparency.
Transparent semiconductors, in addition to being transparent, have a
number of useful characteristics, including a wide band gap, relatively
high carrier mobility, low-temperature manufacturability, and low
manufacturing costs thanks to the low-temperature process and
inexpensive materials. As a result, R&D into properties other than
transparency is also active.
Lets consider the properties of materials
other than transparency and their
applications…
14. Strengths Weaknesses
Visible transparency High resistance of TCO’s
Large area Lack of complementary devices
Low cost (solution based deposition
and printing)
Low temperature processing Technological immaturity
Free real estate
Passive availability (R & C)
Robust stable inorganic materials
Safe, nontoxic materials
15. 15
APPLICATIONS OF TRANSPARENT
ELECTRONICS
Transparent circuits will have
unprecedented applications in flat panel
displays and other electronic devices, such
as see through display or novel display
structures.
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.
and many more….
16. 16
Future Scope
In the field of solar cells, although
much progress has been made in
developing new materials and
devices for high performance
transparent solar cells, there is still
plenty of opportunity to study and
improve device performance and
fabrication techniques compared with
the nontransparent solar cell devices.
It is likely that new scientific
discoveries and technological
advances will continue to cross
fertilize each other for the foreseeable
future.
17. 17
Oxides represent a relatively new class
of semiconductor materials applied to
active devices, such as TFTs, SWNT
transistors.
The combination of high field effect
mobility and low processing temperature
for oxide semiconductors makes them
attractive for high performance electronics
on flexible plastic substrates.
Let us hope that we are soon going to
see transparent technology being
implemented in our lives…!!!
18. REFERENCES
‘Transparent Electronics ’, Springer
publications, J.F.Wager, D. A. Keszler, R. E.
Presley.
‘Transparent electronics: from synthesis to
applications’, Wiley publications: Antonio
Facchetti, Tobin J. Marks.
www.wikipedia.org
www.ieee.org
www.alternative-energy-news.info/transparent-
a-solar-energy-breakthrough/
www.nanomarkets.net
www.nikkeibp.co.jp