Abstract
“The total spend on inorganic materials will be approximately $22 Billion in 2021”
Description
There is increasing work on printed inorganics as people struggle with the
performance of organics in some aspects. For conductors with vastly better
conductance and cost, for the best printed batteries, for quantum dot devices
and for transistor semiconductors with ten times the mobility, look to the new
inorganics. That is the emerging world of new nanoparticle metal and alloy
inks that are magnitudes superior in cost, conductivity and stability, such as
the flexible zinc oxide based transistor semiconductors working at ten times
the frequency and with best stability and life, along with many other
inorganic materials. Read the world's only report that pulls all this together
in readable form.
This report critically compares the options, the trends and the emerging
applications. It is the first in the world to comprehensively cover this
exciting growth area. The emphasis is on technology basics, commercialisation
and the key players.
This report is suitable for all companies developing or interested in the
opportunity of printed or thin film electronics materials, manufacturing
technologies or complete device fabrication and integration.
Market Forecasts
IDTechEx forecasts a market of $45 Billion for printed electronics by 2021 and
that market is expected to be more or less evenly divided between organic and
inorganic materials.
This report reveals the rapidly increasing opportunities for inorganic and
composite chemicals in the new printed electronics, given that so much of the
limelight is on organics. Inorganics encompass various metals, metal oxides as
transparent conductors (such as fluorine tin oxide or indium tin oxide,
extensively used in displays and photovoltaic technologies) or transistor
materials as well as nano-silicon or copper and silver inks, whether in
particle or flake form. Then there are inorganic quantum dots, carbon
structures such as graphene, nanotubes and the various buckyballs etc.
However, there is much more, from light emitting materials to battery elements
and the amazing new meta-materials that render things invisible and lead to
previously impossible forms of electronics.
Over the next ten years, improvements in inorganic conductors such as the use
of nanotechnology and the lack of improvement of the very poorly conductive
and expensive organic alternatives means that inorganics will be preferred for
most conductors whether for electrodes, antennas, touch buttons, interconnects
or for other purposes. By contrast, organic substrates for flexible
electronics such as low cost polyester film and paper will be preferred in
most cases because they are light weight, low cost and have a wide range of
mechanical flexibility. The use of inorganic substrates such as glass
represents a fall-back particularly required where there is failure to reduce
processing temperatures. Here stainless steel foil printed reel to reel is an
improvement, where possible.
Technologies covered
The report considers inorganic printed and thin film electronics for displays,
lighting, semiconductors, sensors, conductors, photovoltaics, batteries and
memory giving detailed company profiles not available elsewhere. The coverage
is global - with companies from East Asia to Europe to America all included.
The application of the technology in relation to other types such as organic
electronics and silicon chips is given, with detailed information clearly
summarised in over 160 tables and figures.
Elements being targeted
In order to meet the widening variety of needs for printed and potentially
printed electronics, not least in flexible, low cost form, a rapidly
increasing number of elements are being brought to bear. Oxides, amorphous
mixtures and alloys are particularly in evidence. Even the so-called organic
devices such as OLEDs variously employ such materials as B, Al and Ti oxides
and nitrides as barrier layers against water and oxygen, Al, Cu, Ag and indium
tin oxide as conductors, Ca or Mg cathodes and CoFe nanodots, Ir and Eu in
light emitting layers, for example.
This report is essential for all those wishing to understand this technology,
the players, opportunities and applications, to ensure they are not surpassed.
Report Statistics
- Last update: Feb 2012
- Forecasts to: 2022
- Total Number of Pages: 298
- Total Number of Tables: 46
- Total Number of Figures: 111
- Total Number of Companies: 15
Table of Contents
1. INTRODUCTION
- 1.1. Printed electronics - reasons why
- 1.2. Impact of printed electronics on conventional electronics
- 1.3. Progress so far
- 1.3.1. The age of silicon
- 1.3.2. The dream of organic electronics
- 1.3.3. The example of smart clothing
- 1.3.4. Slow progress with organic conductors
- 1.3.5. Boron nitride - tailoring carbon composites
- 1.4. The new inorganic printed and thin film devices
- 1.4.1. Rapidly widening choice of elements - deja vu
- 1.4.2. Example - printed lighting
- 1.4.3. Example - printed photodetectors
- 1.4.4. Inorganic barrier layers - alumina, silicon nitride, boron
nitride etc
2. INORGANIC TRANSISTORS
- 2.1. Inorganic compound semiconductors for transistors
- 2.1.1. Learning how to print inorganic compound transistors
- 2.1.2. Zinc oxide based transistor semiconductors and Samsung
breakthrough
- 2.1.3. More work on inorganic transistors: Progress at Evonik
- 2.1.4. Amorphous InGaZnO
- 2.1.5. Gallium-indium hydroxide nanoclusters
- 2.1.6. Gallium arsenide semiconductors for transistors
- 2.1.7. Transfer printing silicon and gallium arsenide on film
- 2.1.8. Silicon nanoparticle ink
- 2.1.9. Molybdenite transistors at EPFL Lausanne
- 2.1.10. Carbon nanotube TFTs at SWeNT
- 2.2. Inorganic dielectrics for transistors
- 2.2.1. Solution processed barium titanate nanocomposite
- 2.2.2. Alternative inorganic dielectrics HafSOx etc
- 2.2.3. Hybrid inorganic dielectrics - zirconia
- 2.2.4. Hafnium oxide - latest work
- 2.2.5. Aluminium, lanthanum and other oxides
- 2.3. Hewlett Packard prints aSi backplanes reel to reel
- 2.4. Inorganic transistors on paper
- 2.5. Progress Towards p-type Metal Oxide Semiconductors
- 2.6. High-Mobility Ambipolar Organic-Inorganic Hybrid Transistors
- 2.7. Hybrid inorganic/organic transistors and memory
- 2.7.1. Resistive switching
- 2.7.2. Oxides as anodes
- 2.8. Do organic transistors have a future?
3. INORGANIC PHOTOVOLTAICS AND THERMOELECTRIC
- 3.1. Performance criteria and limitations of silicon photovoltaics
- 3.2. Comparison of photovoltaic technologies
- 3.3. Non-silicon inorganic options
- 3.3.1. Lowest cost solar cells - CuSnZnSSe?
- 3.3.2. Copper Indium Gallium diSelenide (CIGS)
- 3.3.3. Gallium arsenide
- 3.3.4. Gallium arsenide - germanium
- 3.3.5. Gallium indium phosphide and gallium indium arsenide
- 3.3.6. Cadmium telluride and cadmium selenide
- 3.3.7. Bismuth ferrite - new principle of operation
- 3.3.8. Porous zinc oxide
- 3.3.9. Polymer-quantum dot devices CdSe, CdSe/ZnS, PbS, PbSe
- 3.3.10. Cuprous oxide PV
- 3.3.11. Other inorganic semiconductors for PV
- 3.4. Inorganic-organic and carbon-organic formulations
- 3.4.1. Titanium dioxide Dye Sensitised Solar Cells (DSSC)
- 3.4.2. Zinc oxide DSCC photovoltaics
- 3.4.3. Development of high-performance organic-dye sensitized solar cells
- 3.4.4. Fullerene enhanced polymers
- 3.5. Other recent advances
- 3.6. Cobalt, phosphate and ITO to store the energy
- 3.7. Major US funding for thin Si, CIGS/ZnMnO, DSSC photovoltaics
4. BATTERIES AND SUPERCAPACITORS
- 4.1. Applications of laminar batteries
- 4.2. Technology and developers
- 4.2.1. All-inorganic printed lithium electric vehicle battery: Planar
Energy
- 4.2.2. Zirconium disulphide
- 4.2.3. Battery overview
- 4.2.4. The Paper Battery Co
- 4.2.5. Nanotecture
- 4.2.6. CEA Liten
- 4.2.7. Rocket Electric, Bexel, Samsung, LG Chemicals and micro SKC
batteries for Ubiquitous Sensor Networks
- 4.2.8. Power Paper
- 4.2.9. Solicore, USA
- 4.2.10. SCI, USA
- 4.2.11. Infinite Power Solutions, USA
- 4.2.12. Blue Spark Technologies, USA
- 4.2.13. Enfucell
- 4.2.14. Printed battery research
- 4.3. Smart skin patches
- 4.4. Nano metal oxides with carbon create new supercapacitor
5. CONDUCTORS, SENSORS, METAMATERIALS AND MEMRISTORS
- 5.1. Silver, indium tin oxide and general comparisons.
- 5.2. Conductor deposition technologies
- 5.3. 2009/2010 breakthroughs in printing copper
- 5.3.1. Challenges with copper
- 5.3.2. University of Helsinki
- 5.3.3. NanoDynamics
- 5.3.4. Applied Nanotech Holdings
- 5.3.5. Samsung Electro-Mechanics
- 5.3.6. Intrinsiq announces nano copper for printing
- 5.3.7. NovaCentrix
- 5.3.8. Hitachi Chemical
- 5.4. Conductive Inks
- 5.5. Progress with new conductive ink chemistries and cure processes
- 5.5.1. Novacentrix PulseForge
- 5.6. Pre-Deposit Images in Metal PDIM
- 5.7. Transparent electrodes by metal patterning
- 5.8. Printed conductors for RFID tag antennas
- 5.8.1. Print resolutions required for high performance RFID tag antennas
- 5.8.2. Process cost comparison
- 5.8.3. RFID tag manufacture consolidation and leaders in 2009
- 5.9. Printing wide area sensors and their memory: Polyscene, Polyapply,
3Plast, PriMeBits, Motorola
- 5.10. Phase Change Memory
- 5.11. Printing metamaterials
- 5.12. Flexible memristors
- 5.13. Company profiles
- 5.13.1. ASK
- 5.13.2. Poly-Flex
- 5.13.3. Avery Dennison
- 5.13.4. Sun Chemical (Coates Circuit Products)
- 5.13.5. Mark Andy
- 5.13.6. InTune (formerly UPM Raflatac)
- 5.13.7. Stork Prints
- 5.14. Aerosol jet printing by Optomec
- 5.15. Electroless plating and electroplating technologies
- 5.15.1. Conductive Inkjet Technology
- 5.15.1. Hanita Coatings
- 5.15.2. Omron
- 5.15.3. Meco
- 5.15.4. Additive Process Technologies Ltd
- 5.15.5. Ertek
- 5.15.6. Leonhard Kurz
- 5.16. Polymer - metal suspensions
- 5.17. Comparison of options
- 5.18. Dry Phase Patterning (DPP)
- 5.19. Inorganic biomedical sensors
- 5.19.1. Disposable blocked artery sensors
- 5.19.2. Disposable asthma analysis
6. NANOTUBES AND NANOWIRES
- 6.1. Nanotubes
- 6.2. At Stanford, nanotubes + ink + paper = instant battery
- 6.3. Carbon Nanotubes and printed electronics
- 6.4. Developers of Carbon Nanotubes for Printed Electronics
- 6.5. Nanorods in photovoltaics
- 6.6. Zinc oxide nanorod semiconductors
- 6.7. Zinc oxide nano-lasers
- 6.8. Indium oxide nanowires
- 6.9. Zinc oxide nanorod piezo power
7. INORGANIC AND HYBRID DISPLAYS AND LIGHTING
- 7.1. AC Electroluminescent
- 7.1.1. Fully flexible electroluminescent displays
- 7.1.2. Watch displays
- 7.1.3. MorphTouch™ from MFLEX
- 7.1.4. Electroluminescent and other printed displays
- 7.2. Thermochromic
- 7.2.1. Heat generation and sensitivity
- 7.2.2. CASE STUDY: Duracell battery testers
- 7.3. Electrophoretic
- 7.3.1. Background
- 7.3.2. Applications of E-paper displays
- 7.3.3. Electrochromic E-Paper using ZnO Nanowire Array
- 7.3.4. The Killer Application
- 7.4. Colour electrophoretics
- 7.5. Inorganic LED lighting and hybrid OLED
- 7.6. Affordable electronic window shutters
- 7.7. Quantum dot lighting and displays
8. COMPANY PROFILES
- 8.1. Hewlett Packard
- 8.2. Unidym
- 8.3. NanoMas Technologies
- 8.4. Miasole
- 8.5. Konarka
- 8.6. Spectrolab
- 8.7. G24i
- 8.8. Soligie
- 8.9. BASF
- 8.10. DaiNippon Printing
- 8.11. Evonik
- 8.12. InkTec
- 8.13. Samsung
- 8.14. Toppan Printing
- 8.15. Nanogram
9. TIMELINES, SIZING OF OPPORTUNITIES AND MARKET FORECASTS
- 9.1. Market forecasts 2011-2021
- 9.2. Materials
- 9.3. Devices
- 9.3.1. Photovoltaics
- 9.3.2. Batteries, displays, etc
- 9.3.3. Market for printed electronic labels
EXECUTIVE SUMMARY AND CONCLUSIONS
APPENDIX 1: IDTECHEX PUBLICATIONS AND CONSULTANCY
TABLES
- 1.1. Comparison of thin film silicon and organic thin films as transistor
semiconductors.
- 2.1. Comparison of printed polymer ink used in pilot production of organic
transistors vs two thin film inorganic semiconductors for transistors vs
nanosilicon ink
- 2.2. Some of the organisations developing zinc oxide transistors
- 2.3. Some properties of new thin film dielectrics
- 2.4. Benefits and challenges of R2R electronics fabrication were seen as
follows:
- 2.5. Printing choices
- 3.1. Efficiency vs deliverable output power
- 3.2. Efficiencies for thin film solar cells
- 3.3. Technology comparison between inorganic and other photovoltaic cells
on plastic film
- 3.4. Summary of some of the important performance criteria for
photovoltaics by type
- 3.5. Some recent results for inorganic and organic-fullerene photovoltaic
cells
- 3.6. Companies pursuing industrial production of CIGS photovoltaics
- 3.7. Quantum Dots Available
- 3.8. Typical quantum dot materials from Evident and their likely
application.
- 3.9. Thin film market share module cost by technology
- 4.1. Some examples of marketing thrust for laminar batteries
- 4.2. Shapes of battery for small RFID tags advantages and disadvantages
- 4.3. Examples of suppliers of coin type batteries by country
- 4.4. The spectrum of choice of technologies for batteries in smart
packaging
- 4.5. Examples of potential sources of flexible thin film batteries
- 4.6. Examples of universities and research centres developing laminar
batteries
- 4.7. The four generations of delivery skin patches
- 4.8. Examples of drugs and cosmetics applied by company using iontophoresis
- 5.1. Main applications of conductive inks and some major suppliers today
- 5.2. Different options for printing electronics, level of success and
examples of companies
- 5.3. Comparison of metal etch (e.g. copper and aluminium) conductor choices
- 5.4. Electroless metal plate - Additive print process with weakly
conductive ink (e.g. plastics or carbon) followed by wet metal plating
- 5.5. Electro metal plate - Additive print process with weakly conductive
ink (e.g. plastics or carbon) followed by dry metal plating
- 5.6. Printable metallic conductors cure at LT e.g. silver based ink
- 5.7. Parameters for metal ink choices
- 5.8. Examples of suppliers for metal (mainly silver) PTF inks
- 5.9. Examples of companies progressing printed RFID antennas etc
- 5.10. Some companies progressing ink jettable conductors
- 5.11. Process Cost Comparison 1 - low volume - GB £ /sq metre web
production - Antenna on substrate only
- 5.12. Cost breakdown of an average RFID tag in 2004 and target
- 5.13. Possibilities for various new printed conductors.
- 6.1. Charge carrier mobility of carbon nanotubes compared with alternatives
- 6.2. Developers of Carbon Nanotubes for Printed Electronics
- 7.1. Advantages and disadvantages of electrophoretic displays
- 7.2. Comparison between OLEDs and E-Ink of various parameters
- 9.1. The market for inorganic versus organic electronics defined by
chemistry of key element 2011-2021
- 9.2. Percentage share as a whole of the market 2011-2021
- 9.3. Printed electronics materials and other elements of device income
2011-2021 in billions of dollars
- 9.4. Market forecast by component type for 2011-2021 in US $ billions, for
printed and potentially printed electronics including organic, inorganic and
composites
- 9.5. Market size for thin film photovoltaic technologies beyond silicon
technologies % of the market that is printed and flexible
- 9.6. Statistics for electronic labels and their potential locations
FIGURES
- 1.1. SuperPanoramic cockpit with closable opaque layer - a concept of the
US Air Force
- 1.2. US Warfighter's back pack must reduce in weight. Wrist displays,
printed antennas, batteries, electronics and power generation will be part of
this.
- 1.3. The different impact of the new printed electronics on various
existing electric and electronic markets
- 1.4. Organic electronics - the dream
- 1.5. Attributes and problems of inorganic, hybrid and organic thin film
electronics form a spectrum
- 1.6. Elements employed in the silicon chip business where blue refers to
before the 1990s, green for since the 1990s and red for beyond 2005.
- 1.7. Projections for flexible printed and thin film lighting 2007-2025
- 1.8. Tera-Barrier's barrier stack
- 2.1. Transparent inorganic transistor
- 2.2. Example of ZnO based transistor circuit.
- 2.3. Using a nanolaminate as an e-platform
- 2.4. TEM images of solution processed nanolaminates
- 2.5. Semiconductor development
- 2.6. Target range for mobility and processing temperature of semiconductors
- 2.7. Transfer characteristics of gen3 semiconductor system
- 2.8. Current efficiency of a Novaled PIN OLEDTM stack on an inkjet
printed, transparent conductive ITO anode
- 2.9. Cross-sectional schematic view of an amorphous oxide TFT
- 2.10. Transparent and flexible active matrix backplanes fabricated on PEN
films
- 2.11. Molecular precursors synthesized at the University of Oregon
- 2.12. Semprius transfer printing
- 2.13. Performance of Kovio's ink versus others by mobility
- 2.14. Road map
- 2.15. Molybdenite transistor from EPFL Lausanne
- 2.16. Hybrid organic-inorganic transistor and right dual dielectric
transistor
- 2.17. Web as clean room
- 2.18. The basic imprint lithography process
- 2.19. Zinc oxide transistors printed on to paper
- 2.20. SEM image of p-type ZnO nanowires
- 3.1. Wafer vs thin film photovoltaics
- 3.2. Summary of the applicational requirements for the large potential
markets
- 3.3. Progress in improving the efficiency of the different types of
photovoltaic cell 1975-2011
- 3.4. CIGS photovoltaic cell configuration that is not yet printed.
Nanosolar now prints similar structures reel to reel.
- 3.5. CIGS-CGS absorber layer
- 3.6. Roll to roll production of CIGS on metal or polyimide film
- 3.7. An example of flexible, lightweight CdTe photovoltaics on polymer film
- 3.8. Mass production of flexible thin film electronic devices using the
three generations of technology.
- 3.9. A typical DSSC construction
- 3.10. Solar cell researchers
- 3.11. Fullerene-pentacene photovoltaic device
- 3.12. Advantages of Pulse Thermal Processing (PTP)
- 4.1. Inorganic micro-battery development by CEA Liten, illustrating the
various chemistries
- 4.2. CEA Liten Li-Ion battery development
- 4.3. The Power Paper battery
- 4.4. The Infinite Power battery is very small
- 4.5. Infinite Power batteries ready for use
- 4.6. IPS Thinergy rechargeable, solid-state lithium batteries
- 4.7. Reel to reel printing of Blue Spark Technologies batteries
- 4.8. Carbon zinc thin film battery from Blue Spark Technologies
- 4.9. Examples of smart skin patches.
- 4.10. The Estee Lauder smart cosmetic patch with printed inorganic battery
and electrodes launched in 2006 a three pack costing $50 and an eight pack
costing $100
- 4.11. The ultimate dream for smart skin patches for drugs - closed loop
automated treatment
- 4.12. Evolution of smart skin patches
- 5.1. Typical SEM images of Copper flake C1 6000F.
- 5.2. Industrial Inkjet Printhead and nano-Cu ink developed by Samsung
Electro-Mechanics
- 5.3. Silver-based ink as printed and after curing
- 5.4. Conductance in ohms per square for the different printable conductive
materials compared with bulk metal
- 5.5. Loading for spherical conductive fillers
- 5.6. Typical SEM images of CU flake C1 6000F. Copper flake
- 5.7. PolyIC approach to patterned transparent electrodes
- 5.8. Caledon Controls transparent conductive film using printed metal
patterning.
- 5.9. Choice of printing technology for RFID antennas today
- 5.10. Projected tag assembly costs from Alien Technology in US Cents for
volumes of several billions of tags
- 5.11. How negative refractive index works
- 5.12. How to make a working printed metamaterial
- 5.13. Printed metal patterning to form metamaterial
- 5.14. Flexible memristor
- 5.15. Meco's Flex Antenna Plating (FAP) machine
- 5.16. APT's FFD prototype can operate faster than 20 meters per minute.
- 5.17. Additive Process Technologies 2 stage process
- 5.18. Additive Process Technologies antenna cost
- 5.19. New technology to make conductive patterns
- 5.20. Dry Phase Patterned inductor
- 6.1. Properties and morphology of single walled carbon nanotubes
- 6.2. Nanotube shrink-wrap from Unidym
- 6.3. Zinc oxide nanowires generating power
- 7.1. Pelikon's (now MFLEX) prize winning fashion watch
- 7.2. An example of an elumin8 electroluminescent display
- 7.3. Experimental game printed on beer pack by VTT Technology of Finland
- 7.4. Duracell battery testing chipless label - front and reverse view
- 7.5. Principle of operation of electrophoretic displays
- 7.6. E-paper displays on a magazine sold in the US in October 2008
- 7.7. Retail Shelf Edge Labels from UPM
- 7.8. Secondary display on a cell phone
- 7.9. Scheme of the fabricated e-paper nanostructure based on ZnO nanowires
- 7.10. Photo image of (a) bleached, and (b) color state of the flexible ZnO
nanowire electrode
- 7.11. Electronic paper from Fujitsu
- 8.1. Unidym's target markets for transparent conducting nanotube films
- 8.2. NanoMas technology
- 8.3. Konarka thin film solar cell arrays
- 8.4. G24i has a new UK factory printing titanium oxide photovoltaics
- 8.5. G24i's advanced solar technology vs traditional polycrystalline
- 8.6. Printed Flexible Circuits from Soligie
- 8.7. Capabilities of Soligie
- 8.8. Printed electronics from Soligie
- 8.9. Printing presses used for printing electronics at Soligie
- 8.10. An e-label from Soligie
- 8.11. Semiconductor development at Evonik
- 8.12. Target range for mobility and processing temperature of
semiconductors.
- 8.13. Transfer characteristics of gen3 semiconductor system
- 8.14. Current efficiency of a Novaled PIN OLEDTM stack on an inkjet
printed, transparent conductive ITO anode.
- 8.15. Inks developed by InkTec
- 8.16. InkTec Printing methods
- 8.17. Samsung OLED display
- 8.18. NanoGram's Laser Reactive Deposition (LRD) technology
- 9.1. Printed electronics materials and other elements of device income
2011-2021
- 9.2. Market forecast by component type for 2011-2021 in US $ billions, for
printed and potentially printed electronics including organic, inorganic and
composites
- 9.3. Konarka estimates of opening markets for flexible photovoltaics
- 9.4. Organic semiconductor projection by IBM
- 9.5. Technical challenges for the next ten year to improvement of FDICD
capabilities
- 9.6. Facts about media
- 9.7. SM Products Road Map
