Global Markets and Applications for New and High Impact Nanomaterials to 2020: Carbon Nanotubes, Graphene, Nanocellulose, Silicene, Graphyne, Graphdiyne, Graphane and Molybdenum Disulfide
Nanocellulose, graphene, carbon nanotubes, silicone, graphyne, graphdiyne, grapahane and molybdenum disulfide all possess outstanding properties and represent potentially the most economically viable and lucrative nanomaterials through to 2020. Most are relatively new nanomaterials but are coming onto the market fast and will find widespread applications over the next decade in sectors such as composites, electronics, filtration, medical and life sciences, oil and energy, automotive, aerospace, coatings, military, consumer goods and sensors.
WHAT DOES THE REPORT INCLUDE?
WHAT DOES THE REPORT INCLUDE?
- Industry growth to 2020
- Industry structure
- Historical data
- Market forecastsy
- Key market drivers and restraints
- Commercialization timelines to 2020
- Producer, research centre and application developer profiles
1 EXECUTIVE SUMMARY
2 METHODOLOGY
3 NANOCELLULOSE
3.1 INTRODUCTION
3.2 PROPERTIES AND TYPES
3.3 PRODUCTION METHODS
3.4 MARKET STRUCTURE
3.5 SUPPLY CHAIN
3.6 PATENTS AND PUBLICATIONS
3.7 PRODUCTION VOLUMES
3.8 MARKETS AND APPLICATIONS
3.8.1 Composites
3.8.2 Electronics
3.8.3 Construction
3.8.4 Paper and pulp
3.8.5 Filtration
3.8.6 Medicine and life sciences
3.8.7 Paints, films and coatings
3.8.8 Rheologial modifiers/Functional additives
3.8.9 Aerogels
3.8.10 Oil industry
3.9 PRODUCERS, APPLICATION DEVELOPERS AND RESEARCH GROUP PROFILES
4 GRAPHENE
4.1 INTRODUCTION
4.2 PROPERTIES AND TYPES
4.3 MARKET STRUCTURE
4.4 SUPPLY CHAIN
4.5 PATENTS AND PUBLICATIONS
4.6 PRODUCTION VOLUMES
4.7 MARKETS AND APPLICATIONS
4.7.1 Aerospace
4.7.2 Automotive
4.7.3 Biomedical
4.7.4 Coatings and paints
4.7.5 Communications
4.7.6 Composites
4.7.7 Electronics, optoelectronics and data storage
4.7.8 Energy
4.7.9 Sensors
4.8 PRODUCERS, APPLICATION DEVELOPERS AND RESEARCH GROUP PROFILES
5 CARBON NANOTUBES
5.1 INTRODUCTION
5.2 PROPERTIES AND TYPES
5.3 MARKET STRUCTURE
5.4 SUPPLY CHAIN
5.5 PATENTS AND PUBLICATIONS
5.6 PRODUCTION VOLUMES
5.7 MARKETS AND APPLICATIONS
5.7.1 Aerospace
5.7.2 Automotive
5.7.3 Energy
5.7.4 Environment and water
5.7.5 Medical and life sciences
5.7.6 Military and defense
5.7.7 Composites and plastics
5.7.8 Electronics
5.7.9 Sporting & consumer goods
5.7.10 Telecommunications
5.7.11 Textiles
5.8 PRODUCERS, APPLICATION DEVELOPERS AND RESEARCH GROUP PROFILES
6 SILICENE
6.1 INTRODUCTION
6.2 PROPERTIES
6.3 APPLICATIONS
6.4 RESEARCH CENTRE PROFILES
7 GRAPHYNE
7.1 INTRODUCTION
7.2 PROPERTIES
7.3 APPLICATIONS
7.4 RESEARCH CENTRE PROFILES
8 GRAPHDIYNE
8.1 INTRODUCTION
8.2 PROPERTIES
8.3 APPLICATIONS
8.4 RESEARCH CENTRE PROFILES
9 GRAPHANE
9.1 INTRODUCTION
9.2 PROPERTIES
9.3 APPLICATIONS
9.4 RESEARCH CENTRE PROFILES
10 MOLYBDENUM DISULFIDE
10.1 INTRODUCTION
10.2 PROPERTIES
10.3 APPLICATIONS
10.4 RESEARCH CENTRE PROFILES
11 REFERENCES
2 METHODOLOGY
3 NANOCELLULOSE
3.1 INTRODUCTION
3.2 PROPERTIES AND TYPES
3.3 PRODUCTION METHODS
3.4 MARKET STRUCTURE
3.5 SUPPLY CHAIN
3.6 PATENTS AND PUBLICATIONS
3.7 PRODUCTION VOLUMES
3.8 MARKETS AND APPLICATIONS
3.8.1 Composites
3.8.2 Electronics
3.8.3 Construction
3.8.4 Paper and pulp
3.8.5 Filtration
3.8.6 Medicine and life sciences
3.8.7 Paints, films and coatings
3.8.8 Rheologial modifiers/Functional additives
3.8.9 Aerogels
3.8.10 Oil industry
3.9 PRODUCERS, APPLICATION DEVELOPERS AND RESEARCH GROUP PROFILES
4 GRAPHENE
4.1 INTRODUCTION
4.2 PROPERTIES AND TYPES
4.3 MARKET STRUCTURE
4.4 SUPPLY CHAIN
4.5 PATENTS AND PUBLICATIONS
4.6 PRODUCTION VOLUMES
4.7 MARKETS AND APPLICATIONS
4.7.1 Aerospace
4.7.2 Automotive
4.7.3 Biomedical
4.7.4 Coatings and paints
4.7.5 Communications
4.7.6 Composites
4.7.7 Electronics, optoelectronics and data storage
4.7.8 Energy
4.7.9 Sensors
4.8 PRODUCERS, APPLICATION DEVELOPERS AND RESEARCH GROUP PROFILES
5 CARBON NANOTUBES
5.1 INTRODUCTION
5.2 PROPERTIES AND TYPES
5.3 MARKET STRUCTURE
5.4 SUPPLY CHAIN
5.5 PATENTS AND PUBLICATIONS
5.6 PRODUCTION VOLUMES
5.7 MARKETS AND APPLICATIONS
5.7.1 Aerospace
5.7.2 Automotive
5.7.3 Energy
5.7.4 Environment and water
5.7.5 Medical and life sciences
5.7.6 Military and defense
5.7.7 Composites and plastics
5.7.8 Electronics
5.7.9 Sporting & consumer goods
5.7.10 Telecommunications
5.7.11 Textiles
5.8 PRODUCERS, APPLICATION DEVELOPERS AND RESEARCH GROUP PROFILES
6 SILICENE
6.1 INTRODUCTION
6.2 PROPERTIES
6.3 APPLICATIONS
6.4 RESEARCH CENTRE PROFILES
7 GRAPHYNE
7.1 INTRODUCTION
7.2 PROPERTIES
7.3 APPLICATIONS
7.4 RESEARCH CENTRE PROFILES
8 GRAPHDIYNE
8.1 INTRODUCTION
8.2 PROPERTIES
8.3 APPLICATIONS
8.4 RESEARCH CENTRE PROFILES
9 GRAPHANE
9.1 INTRODUCTION
9.2 PROPERTIES
9.3 APPLICATIONS
9.4 RESEARCH CENTRE PROFILES
10 MOLYBDENUM DISULFIDE
10.1 INTRODUCTION
10.2 PROPERTIES
10.3 APPLICATIONS
10.4 RESEARCH CENTRE PROFILES
11 REFERENCES
TABLES & FIGURES
Figure 1: Nanocellulose production volumes tons per year, all types, forecast to 2020 (Conservative estimate)
Figure 2: Nanocellulose production volumes tons per year, all types, forecast to 2017 (Optimistic estimate)
Figure 3: Production of nanocellulose by type, 2012
Figure 4: Demand for nanocellulose by end user market, 2012
Figure 5: Demand for nanocellulose by end user market, 2017
Table 1: Market summary for nanocellulose
Table 2: Commercialization timeline for nanocellulose
Table 3: Main applications by nanocellulose, by type
Table 4: Properties of cellulose nanofibrils relative to metallic and polymeric materials
Table 5: Nanocellulose properties and applications thereof
Table 6: Nanocellulose types
Figure 6: The main steps involved in the preparation of cellulose nanoparticles
Table 7: Nanocellulose nanocrystal sources and scale
Table 8: Market summary for nanocellulose
Table 9: Supply chain for the nanocellulose market
Figure 7: Nanocellulose patents/patent applications, 1997-2011
Figure 8: Patent applications for nanocellulose, by market, 2011
Figure 9: Research publications on nanocellulose materials and composites, 1996-2011
Figure 10: Research publications on nanocellulose materials and composites, 2000-2011 by country
Table 10: Specialty Cellulose Pulp Capacity
Table 11: Nanocellulose producers and production capacity (Current and projected)
Figure 11: Nanocellulose production volumes tons per year, all types, forecast to 2020 (Conservative estimate)
Figure 12: Nanocellulose production volumes tons per year, all types, forecast to 2020 (Optimistic estimate)
Table 12: Estimates for composites markets impacted by nanocellulose
Table 13: Polymer properties
Table 14: Nanocellulose in composites: Market drivers and applications
Table 15: Commercialization timeline for nanocellulose in the composites market, 2010-2020
Table 16: Estimates for electronics markets impacted by nanocellulose
Table 17: Nanocellulose in electronics: Market drivers and applications
Table 18: Commercialization timeline for nanocellulose in the electronics market, 2010-2020
Table 19: Estimates for construction markets impacted by nanocellulose
Table 20: Nanocellulose in construction: Market drivers and applications
Table 21: Commercialization timeline for nanocellulose in the construction market, 2010-2020
Table 22: Estimates for paper and pulp markets impacted by nanocellulose
Table 23: Nanocellulose in paper and pulp: Market drivers and applications
Table 24: Commercialization timeline for nanocellulose in the paper and pulp market, 2010-2020
Table 25: Nanocellulose in filtration: Market drivers and applications
Table 26: Commercialization timeline for nanocellulose in the filtration market, 2010-2020
Table 27: Estimates for medical and life sciences markets impacted by nanocellulose
Table 28: Nanocellulose in medicine and life sciences: Market drivers and applications
Table 29: Commercialization timeline for nanocellulose in the medical and life sciences market, 2010-2020
Table 30: Estimates for coatings and paints markets impacted by nanocellulose
Table 31: Nanocellulose in coatings and surfaces: Market drivers and applications
Table 32: Commercialization timeline for nanocellulose in the paints, films and coatings market, 2010-2020
Table 33: Estimates for rheological modifiers markets impacted by nanocellulose
Table 34: Nanocellulose rheological modifiers: Market drivers and applications
Table 35: Commercialization timeline for nanocellulose in the rheological modifiers market, 2010-2019
Table 36: Estimates for aerogels markets impacted by nanocellulose
Table 37: Nanocellulose in aerogels: Market drivers and applications
Table 38: Commercialization timeline for nanocellulose in the aerogels market, 2010-2020
Table 39: Estimates for oil markets impacted by nanocellulose
Table 40: Nanocellulose in the oil industry: Market drivers and applications
Table 41: Commercialization timeline for nanocellulose in the oil market
Table 42: Engineered graphene properties
Figure 13: Chemical Structure of Graphite, Graphene, Carbon Nanotube and Fullerene
Table 43: Commercial graphite types
Table 44: Comparative properties of graphene with nanoclays and carbon nanotubes
Table 45: Cost comparison of graphene
Table 46: Main production methods for graphene
Table 47: Graphene production overview
Table 48: Market structure for graphene (Competitors, structure, end user markets, market drivers, market challenges)
Table 49: Supply chain for the graphene market
Figure 14: Research papers on graphene, 2004-2011
Figure 15: Patent publications for graphene, 2004-2011
Figure 16: Patent publications for graphene, 2010-2011, by organization type
Figure 17: Main graphene patent applicants
Table 50: Graphene producers, production capacities per year, price and end user markets
Figure 18: Graphene production in tons, 2009-2020
Figure 19: Demand for graphene, by market, tons, volume, 2010
Figure 20: Demand for graphene, by market, tons, percentage, 2010
Figure 21: Demand for graphene, by market, tons, volume, 2011
Figure 22: Demand for graphene, by market, tons, percentage, 2011
Figure 23: Demand for graphene, by market, tons, volume, 2020
Figure 24: Demand for graphene, by market, tons, percentage, 2020
Table 51: Estimates for aerospace markets impacted by graphene
Table 52: Commercialization timeline for graphene in the aerospace market, 2008-2020
Table 53: Estimates for automotive markets impacted by graphene
Table 54: Commercialization timeline for graphene in the automotive sector, 2008-2020
Table 55: Estimates for biomedical markets impacted by graphene
Table 56: Commercialization timeline for graphene in the biomedical sector, 2008-2020
Table 57: Estimates for coatings and paints markets impacted by graphene
Table 58: Commercialization timeline for graphene in the coatings and paints sector, 2008-2020
Table 59: Estimates for communications markets impacted by graphene
Table 60: Commercialization timeline for graphene in the communications sector, 2008-2020
Table 61: Estimates for composites markets impacted by graphene
Table 62: Commercialization timeline for graphene in the composites sector, 2008-2020
Table 63: Comparison of ITO replacement technologies
Table 64: Comparison of graphene to semiconductor materials
Table 65: Estimates for electronics markets impacted by graphene
Table 66: Commercialization timeline for graphene in the electronics and data storage sector, 2008-2020
Figure 25: Graphene based solar cell
Table 67: Estimates for energy markets impacted by graphene
Table 68: Commercialization timeline for graphene in the energy sector, 2008-2020
Table 69: Estimates for energy markets impacted by graphene
Table 70: Commercialization timeline for graphene in the sensors market, 2008-2020
Table 71: Market structure for nanotubes (Competitors, structure, end user markets, market
drivers, market challenges)
Table 72: Supply chain for the carbon nanotubes market
Figure 27: Patent applications for nanotubes, by market
Table 73: Production capacity of main carbon nanotubes producers, 2010-2011, tons
Table 74: Price per KG of carbon nanotubes
Figure 28: Demand for nanotubes, by applications
Figure 29: Demand for carbon nanotubes, 2011, tons
Table 75: Production of carbon nanotubes, conservative estimate 2002-2020, tons
Figure 30: Production of carbon nanotubes, conservative estimate 2002-2020 tons
Table 76: Estimates for aerospace markets impacted by nanotubes
Table 77: Commercialization timeline for nanotubes in the aerospace market, 2010-2020
Table 78: Estimates for automotive markets impacted by nanotubes
Table 79: Commercialization timeline for nanotubes in the automotive market, 2010-2020
Table 80: Estimates for energy markets impacted by nanotubes
Table 81: Commercialization timeline for nanotubes in the energy market, 2010-2020
Table 82: Estimates for environment markets impacted by nanotubes
Table 83: Commercialization timeline for nanotubes in the environment market, 2010-2020
Table 84: Estimates for medical and life sciences markets impacted by nanotubes
Table 85: Commercialization timeline for nanotubes in the medical and life sciences market, 2010-2020
Table 86: Estimates for military and defense markets impacted by nanotubes
Table 87: Commercialization timeline for nanotubes in the military and defense market, 2010-2020
Table 88: Estimates for composites markets impacted by nanotubes
Table 89: Commercialization timeline for nanotubes in the plastics and composites market, 2010-2020
Table 90: Estimates for electronics markets impacted by nanotubes
Table 91: Commercialization timeline for nanotubes in the electronics market, 2010-2020
Table 92: Estimates for sporting goods markets impacted by nanotubes
Table 93: Commercialization timeline for nanotubes in the sporting goods market, 2010-2020
Table 94: Estimates for telecommunications markets impacted by nanotubes
Table 95: Commercialization timeline for nanotubes in the telecommunications market, 2010-2020
Table 96: Estimates for textiles markets impacted by nanotubes
Table 97: Commercialization timeline for nanotubes in the textiles market, 2010-2020
Table 98: Commercialization timeline for silicene, 2012-2020
Table 99: Commercialization timeline for graphyne, 2012-2020
Table 100: Commercialization timeline for graphdiyne, 2012-2020
Table 101: Commercialization timeline for graphane, 2012-2020
Table 102: Commercialization timeline for molybdenum disulfide, 2012-2020
Figure 1: Nanocellulose production volumes tons per year, all types, forecast to 2020 (Conservative estimate)
Figure 2: Nanocellulose production volumes tons per year, all types, forecast to 2017 (Optimistic estimate)
Figure 3: Production of nanocellulose by type, 2012
Figure 4: Demand for nanocellulose by end user market, 2012
Figure 5: Demand for nanocellulose by end user market, 2017
Table 1: Market summary for nanocellulose
Table 2: Commercialization timeline for nanocellulose
Table 3: Main applications by nanocellulose, by type
Table 4: Properties of cellulose nanofibrils relative to metallic and polymeric materials
Table 5: Nanocellulose properties and applications thereof
Table 6: Nanocellulose types
Figure 6: The main steps involved in the preparation of cellulose nanoparticles
Table 7: Nanocellulose nanocrystal sources and scale
Table 8: Market summary for nanocellulose
Table 9: Supply chain for the nanocellulose market
Figure 7: Nanocellulose patents/patent applications, 1997-2011
Figure 8: Patent applications for nanocellulose, by market, 2011
Figure 9: Research publications on nanocellulose materials and composites, 1996-2011
Figure 10: Research publications on nanocellulose materials and composites, 2000-2011 by country
Table 10: Specialty Cellulose Pulp Capacity
Table 11: Nanocellulose producers and production capacity (Current and projected)
Figure 11: Nanocellulose production volumes tons per year, all types, forecast to 2020 (Conservative estimate)
Figure 12: Nanocellulose production volumes tons per year, all types, forecast to 2020 (Optimistic estimate)
Table 12: Estimates for composites markets impacted by nanocellulose
Table 13: Polymer properties
Table 14: Nanocellulose in composites: Market drivers and applications
Table 15: Commercialization timeline for nanocellulose in the composites market, 2010-2020
Table 16: Estimates for electronics markets impacted by nanocellulose
Table 17: Nanocellulose in electronics: Market drivers and applications
Table 18: Commercialization timeline for nanocellulose in the electronics market, 2010-2020
Table 19: Estimates for construction markets impacted by nanocellulose
Table 20: Nanocellulose in construction: Market drivers and applications
Table 21: Commercialization timeline for nanocellulose in the construction market, 2010-2020
Table 22: Estimates for paper and pulp markets impacted by nanocellulose
Table 23: Nanocellulose in paper and pulp: Market drivers and applications
Table 24: Commercialization timeline for nanocellulose in the paper and pulp market, 2010-2020
Table 25: Nanocellulose in filtration: Market drivers and applications
Table 26: Commercialization timeline for nanocellulose in the filtration market, 2010-2020
Table 27: Estimates for medical and life sciences markets impacted by nanocellulose
Table 28: Nanocellulose in medicine and life sciences: Market drivers and applications
Table 29: Commercialization timeline for nanocellulose in the medical and life sciences market, 2010-2020
Table 30: Estimates for coatings and paints markets impacted by nanocellulose
Table 31: Nanocellulose in coatings and surfaces: Market drivers and applications
Table 32: Commercialization timeline for nanocellulose in the paints, films and coatings market, 2010-2020
Table 33: Estimates for rheological modifiers markets impacted by nanocellulose
Table 34: Nanocellulose rheological modifiers: Market drivers and applications
Table 35: Commercialization timeline for nanocellulose in the rheological modifiers market, 2010-2019
Table 36: Estimates for aerogels markets impacted by nanocellulose
Table 37: Nanocellulose in aerogels: Market drivers and applications
Table 38: Commercialization timeline for nanocellulose in the aerogels market, 2010-2020
Table 39: Estimates for oil markets impacted by nanocellulose
Table 40: Nanocellulose in the oil industry: Market drivers and applications
Table 41: Commercialization timeline for nanocellulose in the oil market
Table 42: Engineered graphene properties
Figure 13: Chemical Structure of Graphite, Graphene, Carbon Nanotube and Fullerene
Table 43: Commercial graphite types
Table 44: Comparative properties of graphene with nanoclays and carbon nanotubes
Table 45: Cost comparison of graphene
Table 46: Main production methods for graphene
Table 47: Graphene production overview
Table 48: Market structure for graphene (Competitors, structure, end user markets, market drivers, market challenges)
Table 49: Supply chain for the graphene market
Figure 14: Research papers on graphene, 2004-2011
Figure 15: Patent publications for graphene, 2004-2011
Figure 16: Patent publications for graphene, 2010-2011, by organization type
Figure 17: Main graphene patent applicants
Table 50: Graphene producers, production capacities per year, price and end user markets
Figure 18: Graphene production in tons, 2009-2020
Figure 19: Demand for graphene, by market, tons, volume, 2010
Figure 20: Demand for graphene, by market, tons, percentage, 2010
Figure 21: Demand for graphene, by market, tons, volume, 2011
Figure 22: Demand for graphene, by market, tons, percentage, 2011
Figure 23: Demand for graphene, by market, tons, volume, 2020
Figure 24: Demand for graphene, by market, tons, percentage, 2020
Table 51: Estimates for aerospace markets impacted by graphene
Table 52: Commercialization timeline for graphene in the aerospace market, 2008-2020
Table 53: Estimates for automotive markets impacted by graphene
Table 54: Commercialization timeline for graphene in the automotive sector, 2008-2020
Table 55: Estimates for biomedical markets impacted by graphene
Table 56: Commercialization timeline for graphene in the biomedical sector, 2008-2020
Table 57: Estimates for coatings and paints markets impacted by graphene
Table 58: Commercialization timeline for graphene in the coatings and paints sector, 2008-2020
Table 59: Estimates for communications markets impacted by graphene
Table 60: Commercialization timeline for graphene in the communications sector, 2008-2020
Table 61: Estimates for composites markets impacted by graphene
Table 62: Commercialization timeline for graphene in the composites sector, 2008-2020
Table 63: Comparison of ITO replacement technologies
Table 64: Comparison of graphene to semiconductor materials
Table 65: Estimates for electronics markets impacted by graphene
Table 66: Commercialization timeline for graphene in the electronics and data storage sector, 2008-2020
Figure 25: Graphene based solar cell
Table 67: Estimates for energy markets impacted by graphene
Table 68: Commercialization timeline for graphene in the energy sector, 2008-2020
Table 69: Estimates for energy markets impacted by graphene
Table 70: Commercialization timeline for graphene in the sensors market, 2008-2020
Table 71: Market structure for nanotubes (Competitors, structure, end user markets, market
drivers, market challenges)
Table 72: Supply chain for the carbon nanotubes market
Figure 27: Patent applications for nanotubes, by market
Table 73: Production capacity of main carbon nanotubes producers, 2010-2011, tons
Table 74: Price per KG of carbon nanotubes
Figure 28: Demand for nanotubes, by applications
Figure 29: Demand for carbon nanotubes, 2011, tons
Table 75: Production of carbon nanotubes, conservative estimate 2002-2020, tons
Figure 30: Production of carbon nanotubes, conservative estimate 2002-2020 tons
Table 76: Estimates for aerospace markets impacted by nanotubes
Table 77: Commercialization timeline for nanotubes in the aerospace market, 2010-2020
Table 78: Estimates for automotive markets impacted by nanotubes
Table 79: Commercialization timeline for nanotubes in the automotive market, 2010-2020
Table 80: Estimates for energy markets impacted by nanotubes
Table 81: Commercialization timeline for nanotubes in the energy market, 2010-2020
Table 82: Estimates for environment markets impacted by nanotubes
Table 83: Commercialization timeline for nanotubes in the environment market, 2010-2020
Table 84: Estimates for medical and life sciences markets impacted by nanotubes
Table 85: Commercialization timeline for nanotubes in the medical and life sciences market, 2010-2020
Table 86: Estimates for military and defense markets impacted by nanotubes
Table 87: Commercialization timeline for nanotubes in the military and defense market, 2010-2020
Table 88: Estimates for composites markets impacted by nanotubes
Table 89: Commercialization timeline for nanotubes in the plastics and composites market, 2010-2020
Table 90: Estimates for electronics markets impacted by nanotubes
Table 91: Commercialization timeline for nanotubes in the electronics market, 2010-2020
Table 92: Estimates for sporting goods markets impacted by nanotubes
Table 93: Commercialization timeline for nanotubes in the sporting goods market, 2010-2020
Table 94: Estimates for telecommunications markets impacted by nanotubes
Table 95: Commercialization timeline for nanotubes in the telecommunications market, 2010-2020
Table 96: Estimates for textiles markets impacted by nanotubes
Table 97: Commercialization timeline for nanotubes in the textiles market, 2010-2020
Table 98: Commercialization timeline for silicene, 2012-2020
Table 99: Commercialization timeline for graphyne, 2012-2020
Table 100: Commercialization timeline for graphdiyne, 2012-2020
Table 101: Commercialization timeline for graphane, 2012-2020
Table 102: Commercialization timeline for molybdenum disulfide, 2012-2020
Many industries including electronics, automotive, aerospace, telecommunications and healthcare are exploring the use of high impact nanomaterials such as nanocellulose, carbon nanotubes and graphene. Other 2-D nanomaterials such as silicene, graphyne, graphdiyne, grapahane and molybdenum disulfide are also under intense study.
Nanocellulose, graphene, carbon nanotubes, silicone, graphyne, graphdiyne, grapahane and molybdenum disulfide all possess outstanding properties and represent potentially the most economically viable and lucrative nanomaterials over the next decade.
Nanocellulose has been studied recently due to its mechanical, functional, biocompatible and biodegradable properties. CNTs and graphene are the strongest, lightest and most conductive fibers known to man, with a performance- per-weight greater than any other material.This 539 page report from Future Markets, Inc. examines the scientific and technological trends of in the development of nanocellulose, carbon nanotubes, graphene and other 2-D nanomaterials.
