The Global Market for Nanoelectronics: Materials and Devices

The electronics industry will witness further significant change and growth in the next decade driven by:

• Scaling
• Growth of mobile wireless devices
• Huge growth in the Internet of Things (IoT)
• Development of flexible and stretchable form functions
• Data, logic and applications moving to the Cloud
• Ubiquitous electronics.

To meet these market demands, power and functionality needs to improve hugely, while being cost effective, driving demand for nanomaterials that will allow for novel architectures, new types of energy harvesting and sensor integration. As well as allowing for greater power, improved performance and bandwith, decreased size and cost, improved flexibility and better thermal management, the exploitation of nanomaterials allows for new device designs, new package architectures, new network architectures and new manufacturing processes. This will lead to greater device integration and density, and reduced time to market.

Semiconducting inorganic nanowires (NWs), carbon nanotubes, nanofibers, nanofibers, quantum dots, graphene and other 2D materials have been extensively explored in recent years as potential building blocks for nanoscale electronics, optoelectronics and photonics components, coatings and devices.

The report covers nanotechnology and nanomaterials related to the following markets and applications:

• Post-Silicon Materials and Devices
• Flexible, Stretchable and Printable Electronics
• Conductive inks
• Wearable health monitoring
• Electronic textiles
• HMI automotive displays
• Displays
• Transistors
• Integrated Circuits
• Other components
• Memory Devices
• Conductive and waterproof electronics coatings
• Photonics
• Lighting
• Solar cells.

FIGURES

Figure 1: Evolution of electronics
Figure 2: Wove Band.
Figure 3: Wearable graphene medical sensor.
Figure 4: Applications timeline for organic and printed electronics
Figure 5: A large transparent conductive graphene film (about 20 × 20 cm2) manufactured by 2D Carbon Tech.
Figure 6: The Tesla S’s touchscreen interface.
Figure 7: Copper based inks on flexible substrate
Figure 8: Graphene layer structure schematic.
Figure 9: Flexible graphene touch screen.
Figure 10: Foldable graphene E-paper
Figure 11: Large-area metal mesh touch panel
Figure 12: Hierarchical Structure of Wood Biomass
Figure 13: Types of nanocellulose
Figure 14: Cellulose nanofiber films
Figure 15: Electronics markets and applications of nanocellulose
Figure 16: LEDs shining on circuitry imprinted on a 5x5cm sheet of CNF.
Figure 17: Nanocellulose photoluminescent paper.
Figure 18: Foldable nanopaper.
Figure 19: Foldable nanopaper antenna
Figure 20: Paper memory (ReRAM)
Figure 21: Quantum dot.
Figure 22: The light-blue curve represents a typical spectrum from a conventional white-LED LCD TV. With quantum dots, the spectrum is tunable to any colours of red, green, and blue, and each Color is limited to a narrow band.
Figure 23: Flexible & stretchable LEDs based on quantum dots.
Figure 24: Schematic of single-walled carbon nanotube
Figure 24a (right): Prototype of a mobile phone produced by 2D Carbon Tech using a graphene touch panel
Figure 25: Stretchable SWNT memory and logic devices for wearable electronics.
Figure 26: Silver nanocomposite ink after sintering and resin bonding of discrete electronic components.
Figure 27: Flexible silver nanowire wearable mesh.
Figure 28: Applications of yttrium oxide nanoparticles
Figure 29: TEM image of carbon onion
Figure 30: Black phosphorus structure.
Figure 31: Black Phosphorus crystal.
Figure 32: Bottom gated flexible few-layer phosphorene transistors with the hydrophobic dielectric encapsulation
Figure 33: Graphitic carbon nitride.
Figure 34: Schematic of germanene.
Figure 35: Graphdiyne structure.
Figure 36: Schematic of Graphane crystal
Figure 37: Structure of hexagonal boron nitride
Figure 38: Structure of 2D molybdenum disulfide.
Figure 39: SEM image of MoS2
Figure 40: Atomic force microscopy image of a representative MoS2 thin-film transistor
Figure 41: Schematic of the molybdenum disulfide (MoS2) thin-film sensor with the deposited molecules that create additional charge.
Figure 42: Schematic of a monolayer of rhenium disulphide
Figure 43: Silicene structure.
Figure 44: Monolayer silicene on a silver (111) substrate.
Figure 45: Silicene transistor
Figure 46: Crystal structure for stanene
Figure 47: Atomic structure model for the 2D stanene on Bi2Te3(111)
Figure 48: Schematic of tungsten diselenide.
Figure 49: Schematic of Indium Selenide (InSe)
Figure 50: BGT Materials graphene ink product
Figure 51: Flexible RFID tag.
Figure 52: Enfucell Printed Battery
Figure 53: Graphene printed antenna
Figure 54: Printed antennas for aircraft
Figure 55: Stretchable material for formed an in-molded electronics
Figure 56: Wearable patch with a skin-compatible, pressure-sensitive adhesive.
Figure 57: Thin film transistor incorporating CNTs
Figure 58: Conductive inks in the wearable electronics market 2017-2027 revenue forecast (million $), by ink types.
Figure 59: Covestro wearables
Figure 60: Royole flexible display
Figure 61: Panasonic CNT stretchable Resin Film
Figure 62: Bending durability of Ag nanowires
Figure 63: NFC computer chip.
Figure 64: NFC translucent diffuser schematic.
Figure 65: Softceptor sensor
Figure 66: BeBop Media Arm Controller
Figure 67: LG Innotek flexible textile pressure sensor
Figure 68: C2Sense flexible sensor
Figure 69: nanofiber conductive shirt original design(top) and current design (bottom).
Figure 70: Garment-based printable electrodes
Figure 71: Wearable gas sensor.
Figure 72: BeBop Sensors Marcel Modular Data Gloves
Figure 73: BeBop Sensors Smart Helmet Sensor System
Figure 74: Torso and Extremities Protection (TEP) system
Figure 75: Global market for wearable electronics, 2015-2027, by application, billions $. Figures do not include medical smart wearables and textiles and smart glasses.
Figure 76: Global transparent conductive electrodes market forecast by materials type, 2012-2027, millions $
Figure 77: BITalino systems.
Figure 78: Connected human body
Figure 79: Flexible, lightweight temperature sensor
Figure 80: Prototype ECG sensor patch
Figure 81: Graphene-based E-skin patch
Figure 82: Wearable bio-fluid monitoring system for monitoring of hydration.
Figure 83: Smart mouth guard.
Figure 84: Smart e-skin system comprising health-monitoring sensors, displays, and ultra flexible PLEDs
Figure 85: Graphene medical patch
Figure 86: TempTraQ wearable wireless thermometer
Figure 87: Mimo baby monitor.
Figure 88: Nanowire skin hydration patch
Figure 89: Wearable sweat sensor
Figure 90: GraphWear wearable sweat sensor.
Figure 91: My UV Patch.
Figure 92: Overview layers of L’Oreal skin patch.
Figure 93: Global medical and healthcare smart textiles and wearables market, 2015-2027, billions $
Figure 94: Global medical and healthcare smart textiles and wearables market, 2015-2027, billions $
Figure 95: Omniphobic-coated fabric
Figure 96: Conductive yarns.
Figure 97: Work out shirt incorporating ECG sensors, flexible lights and heating elements.
Figure 98: BeBop Sensors Smart Helmet Sensor System
Figure 99: Schematic illustration of the fabrication concept for textile-based dye-sensitized solar cells (DSSCs) made by sewing textile electrodes onto cloth or paper
Figure 100: Global smart clothing, interactive fabrics and apparel market 2013-2027 revenue forecast (million $).
Figure 101 Global smart clothing, interactive fabrics and apparel sales by market segment, 2016
Figure 102: Energy harvesting textile
Figure 103: StretchSense Energy Harvesting Kit.
Figure 104: LG Chem Heaxagonal battery.
Figure 105: Printed 1.5V battery.
Figure 106: Energy densities and specific energy of rechargeable batteries.
Figure 107: Stretchable graphene supercapacitor
Figure 108: Schematic illustration of the fabrication concept for textile-based dye-sensitized solar cells (DSSCs) made by sewing textile electrodes onto cloth or paper
Figure 109: Demand for thin film, flexible and printed batteries 2015, by market.
Figure 110: Demand for thin film, flexible and printed batteries 2027, by market.
Figure 111: Samsung QD-LCD TVs, UHD range.
Figure 112: Samsung QLED TV range.
Figure 113: Graphene-enabled bendable smartphone
Figure 114: 3D printed carbon nanotube sensor
Figure 115: Bosch automotive touchscreen with haptic feedback
Figure 116: Canatu’s CNB™ touch sensor.
Figure 117: Quantum dot LED backlighting schematic
Figure 118: Individual red, green and blue microLED arrays based on quantum dots
Figure 119: Methods for integrating QDs into LCD System. (a) On-chip (b) On-edge. (c) On-surface.
Figure 120: On-edge configuration
Figure 121: QD-film integration into a standard LCD display
Figure 122: Inkjet-printed pattern on a QDCF
Figure 123: Samsung 8K 65″ QD Glass
Figure 124: Schematic of Quantum Dot on Glass
Figure 125: QD/OLED hybrid schematic.
Figure 126: LCD using Quantum rods (right) versus a standard LCD
Figure 127: Quantum phosphor schematic in LED TV backlight.
Figure 128: The Wall microLED display
Figure 129: Carbon nanotubes flexible, rechargeable yarn batteries incorporated into flexible, rechargeable yarn batteries
Figure 130: Ink-jet printed 5-inch AM-QLED display (80 dpi)
Figure 131: Flexible LCD
Figure 132: “Full ActiveTM Flex”.
Figure 133: FOLED schematic
Figure 134: Foldable display
Figure 135: Stretchable AMOLED
Figure 136: LGD 12.3” FHD Automotive OLED.
Figure 137: LECTUM® display
Figure 138: Flexible & stretchable LEDs based on quantum dots
Figure 139: QD-TV unit sales 2016-2030, conservative estimates
Figure 140: QD-TV unit sales 2016-2030, optimistic estimates
Figure 141: QD Monitor Unit sales 2015-2030
Figure 142: Transistor architecture trend chart.
Figure 143: CMOS Technology Roadmap
Figure 144: Emerging logic devices
Figure 145: Figure 38: Thin film transistor incorporating CNTs
Figure 146: Graphene IC in wafer tester.
Figure 147: Emerging logic devices
Figure 148: Schematic of NRAM cell
Figure 149: A schematic diagram for the mechanism of the resistive switching in metal/GO/Pt.
Figure 150: Phone coated in WaterBlock submerged in water tank
Figure 151: Demo solar panels coated with nanocoatings
Figure 152: Schematic of barrier nanoparticles deposited on flexible substrates
Figure 153: Schematic of anti-fingerprint nanocoatings.
Figure 154: Toray anti-fingerprint film (left) and an existing lipophilic film (right)
Figure 155: Schematic of AR coating utilizing nanoporous coating
Figure 156: Schematic of KhepriCoat®. Image credit: DSM.
Figure 157: Nanocoating submerged in water
Figure 158: Solar cell with nanowires and graphene electrode
Figure 159: Schematic illustration of the fabrication concept for textile-based dye-sensitized solar cells (DSSCs) made by sewing textile electrodes onto cloth or paper
Figure 160: (a) Schematic of Schottky barrier quantum dots based solar cell
Figure 161: Schematic of QD Solar Cell.
Figure 162: Doped quantum dot LSC
Figure 163: QD coated solar windows
Figure 164: A layer of highly emissive manganese-doped quantum dots onto the outside surface of the outer glass pane (top layer on the left image below) and a layer of copper indium selenide quantum dots onto the inner surface of the inside (bottom) pane
Figure 165: QDSSC Module.
Figure 166: Total QD photovoltaics component revenues 2013-2030 ($100,000s), conservative and optimistic estimates
Figure 167: Fourth generation QD-LEDs.
Figure 168: LG OLED flexible lighting panel
Figure 169: Flexible OLED incorporated into automotive headlight
Figure 170: Flexible & stretchable LEDs based on quantum dots
Figure 171: Total nanotechnology lighting component revenues 2013-2027 ($M), conservative and optimistic estimates
Figure 172: Hybrid graphene phototransistors
Figure 173: Schematic of QD laser device
Figure 174: GFET sensors
Figure 175: First generation point of care diagnostics
Figure 176: Graphene Field Effect Transistor Schematic