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Nanomaterials Production 2002-2016: Production Volumes, Revenues and End User Market Demand

September 2011 | 326 pages | ID: N1E1B330DBCEN
Future Markets, Inc.

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Summary

Nanomaterials Production 2002-2016: Production volumes, revenues and end user market demand

Nanomaterials are being applied across a raft of industries and technologies due to their outstanding magnetic, optical, catalytic and electronic properties, which depend greatly on their size, structure, and shape. Nanomaterials Production 2002-2016 is the only market study ever conducted on how much nanomaterials are produced.

Future Markets conservatively estimates the 2010 worldwide production of nanomaterials to be 21,713 tons, a tenfold increase from 2002. Optimistic forecasts for 2010 are 31,574 tons. The conservative market value is $2.64 billion. Optimistic market estimates are also covered in the report.

The production volume in 2016 is conservatively estimated to more than double to 44, 267 tons, driven by demand from applications in electronics, energy, medicine, chemicals, coatings and catalysts.

The market is forecasted from 2002 through to 2016. End user markets are also outlined. The report covers metal oxide nanopowders; carbon nanotubes; fullerenes and POSS; graphene; nanoclays; nanofibers; nanosilver; and quantum dots.

What does the report include?
  • Comprehensive quantitative data and forecasts for the global nanomaterials markets from 2002 to 2017
  • Qualitative insight and perspective on the current market and future trends in end user markets based on interviews with key executives
  • End user market analysis
  • Over 150 tables and figures illustrating market size and by end user demand
  • Over 400 full company profiles of nanocomposites application developers including technology descriptions, revenues, contact details, and end user markets for their products
Who should buy this report?
  • Advanced materials producers, application developers; sales and marketing departments
  • Corporate strategists and policy advisors
  • Technology consultants and analysts, venture capitalists, and readers interested in the advanced materials market
  • New technology teams and application developers in the aerospace and aviation; automotive; consumer goods; electronics and semiconductors; energy; environment and water; materials; medical and bio; military and defense; and packaging and plastics markets.
What’s inside
  • Statistics and data to illustrate nanomaterials market breakdowns
  • Historial and projected analysis of nanomaterials from 2002-2016
  • Clearly presented data to give a complete picture of the future of the nanomaterials market
1 EXECUTIVE SUMMARY

2 METHODOLOGY

3 MARKET VOLUMES AND DEMAND

3.1 Applications of nanomaterials
3.2 Production estimates 2010
3.3 Demand by material type and market
  3.3.1 Aluminium Oxide
  3.3.2 Antimony Tin Oxide
  3.3.3 Bismuth Oxide
  3.3.4 Carbon Nanotubes
  3.3.5 Cerium Oxide
  3.3.6 Cobalt Oxide
  3.3.7 Copper Oxide
  3.3.8 Fullerenes and POSS
  3.3.9 Graphene
  3.3.10 Iron Oxide
  3.3.11 Magnesium Oxide
  3.3.12 Manganese Oxide
  3.3.13 Nanoclays
  3.3.14 Nanofibers
  3.3.15 Nanosilver
  3.3.16 Nickel Oxide
  3.3.17 Quantum Dots
  3.3.18 Silicon Oxide
  3.3.19 Titanium Dioxide
  3.3.20 Yttrium Oxide
  3.3.21 Zinc Oxide
  3.3.22 Zirconium Oxide

4 CARBON NANOTUBES PRODUCERS

5 FULLERENES AND POSS PRODUCERS

6 GRAPHENE PRODUCERS

7 METAL OXIDE NANOPOWDER PRODUCERS

8 NANOCLAY PRODUCERS

9 NANOFIBERS PRODUCERS

10 NANOSILVER PRODUCERS

11 QUANTUM DOTS PRODUCERS

REFERENCES

TABLES & FIGURES

Figure 1: Production volume of nanomaterials, 2002-2016, tons, conservative estimate
Figure 2: Demand for nanomaterials 2010, by applications, percentage
Figure 3: Breakdown of nanomaterials production, by country, 2010, percentage
Table 1: Applications of nanomaterials
Table 2: Nanomaterials, price per KG, price per ton, estimated production total, 2010
Table 3: Production volumes for nanomaterials, 2010, tons, conservative and optimistic estimate
Table 4: Revenues for nanomaterials, 2010, conservative and optimistic estimate, US$
Table 5: Aluminium oxide nanopowders: properties and applications
Figure 4: Demand for aluminium oxide nanopowders, by applications, percentage
Figure 5: Demand for aluminium oxide nanopowders, 2010, tons
Figure 6: Revenues for aluminium oxide nanopowders, 2010, US$
Table 6: Production of aluminium oxide nanopowders, conservative estimate 2002-2016, tons
Figure 7: Production of aluminium oxide nanopowders, conservative estimate 2002-2016, tons
Table 7: Antimony tin oxide nanopowders: Properties and applications
Figure 8: Demand for antimony tin oxide nanopowders, by applications
Figure 9: Demand for antimony tin oxide nanopowders, 2010, tons
Figure 10: Revenues for antimony tin oxide nanopowders, 2010, US$
Table 8: Production of antimony tin oxide nanopowders, conservative estimate 2002-2016, tons
Figure 11: Production of antimony tin oxide nanopowders, conservative estimate 2002-2016, tons
Table 9: Bismuth oxide nanopowders: Properties and applications
Figure 12: Demand for bismuth oxide nanopowders, by applications
Figure 13: Demand for bismuth oxide nanopowders, 2010, tons
Figure 14: Revenues for bismuth oxide nanopowders, 2010, US$
Table 10: Production of bismuth oxide nanopowders, conservative estimate 2002-2016, tons
Figure 15: Production of bismuth oxide nanopowders, conservative estimate 2002-2016, tons
Table 11: Carbon Nanotubes: Properties and applications
Table 12: Production capacity of main carbon nanotubes producers, 2010, tons
Table 13: Price per KG of carbon nanotubes, 2010 (pricing based on quantity of 3 ton per year)
Figure 16: Demand for nanotubes, by applications
Figure 17: Demand for carbon nanotubes, 2010, tons
Figure 18: Revenues for carbon nanotubes, 2010, US$
Table 14: Production of carbon nanotubes, conservative estimate 2002-2016, tons
Figure 19: Production of carbon nanotubes, conservative estimate 2002-2016, tons
Table 15: Cerium oxide nanopowders: Properties and applications
Figure 20: Demand for cerium oxide nanopowders, by applications
Figure 21: Demand for cerium oxide nanopowders, 2010, tons
Figure 22: Revenues for cerium oxide nanopowders, 2010, US$
Table 16: Production of cerium oxide nanopowders, conservative estimate 2002-2016, tons
Figure 23: Production of cerium oxide nanopowders, conservative estimate 2002-2016, tons
Table 17: Cobalt oxide nanopowders: Properties and applications
Figure 24: Demand for cobalt oxide nanopowders, by applications
Figure 25: Demand for cobalt oxide nanopowders, 2010, tons
Figure 26: Revenues for cobalt oxide nanopowders, 2010, US$
Table 18: Production of cobalt oxide nanopowders, conservative estimate 2002-2016, tons
Figure 27: Production of cobalt oxide nanopowders, conservative estimate 2002-2016, tons
Table 19: Copper oxide nanopowders: Properties and applications
Figure 28: Demand for copper oxide nanopowders, by applications
Figure 29: Demand for copper oxide nanopowders, 2010, tons
Figure 30: Revenues for copper oxide nanopowders, 2010, US$
Table 20: Production of copper oxide nanopowders, conservative estimate 2002-2016, tons
Figure 31: Production of copper oxide nanopowders, conservative estimate 2002-2016, tons
Figure 32: Buckminsterfullerene, C60
Table 21: Fullerenes: Properties and applications
Figure 33: Polyhedral oligomeric silsesquioxanes (POSS)
Table 22: Pricing and availability for POSS and other high profile specialty additives
Table 23: Commercial uses of POSS, realized and potential
Figure 34: Demand for fullerenes and POSS, by applications
Figure 35: Demand for fullerenes and POSS, 2010, tons
Figure 36: Revenues for fullerenes and POSS, 2010, US$
Table 24: Production of fullerenes and POSS, conservative estimate 2002-2016, tons
Figure 37: Production of fullerenes and POSS, conservative estimate 2002-2016, tons
Table 25: Engineered graphene properties (Source: Graphene Frontiers, Ruoff etc.)
Figure 38: Chemical Structure of Graphite, Graphene, Carbon Nanotube and Fullerene
Table 26: Commercial graphite types
Table 27: Comparative properties of graphene with nanoclays and carbon nanotubes
Table 28: Cost comparison of graphene
Table 29: Graphene producers, production capacities per year, price and end user markets
Figure 39: Demand for graphene nanomaterials, by applications
Figure 40: Demand for graphene, 2010, tons
Table 30: Production of graphene, conservative estimate 2009-2016, tons
Figure 41: Production of graphene, conservative estimate 2009-2016, tons
Table 31: Iron oxide nanopowders: Properties and applications
Figure 42: Demand for iron oxide nanopowders, by applications
Figure 43: Demand for iron oxide nanopowders, 2010, tons
Figure 44: Revenues for iron oxide nanopowders, 2010, US$
Table 32: Production of iron oxide nanopowders, conservative estimate 2002-2016, tons
Figure 45: Production of iron oxide nanopowders, conservative estimate 2002-2016, tons
Table 33: Magnesium oxide nanopowders: Properties and applications
Figure 46: Demand for magnesium oxide nanopowders, by applications
Figure 47: Demand for magnesium oxide nanopowders, 2010, tons
Figure 48: Revenues for magnesium oxide nanopowders, 2010, US$
Table 34: Production of magnesium oxide nanopowders, conservative estimate 2002-2016, tons
Figure 49: Production of magnesium oxide nanopowders, conservative estimate 2002-2016, tons
Table 35: Manganese oxide nanopowders: Properties and applications
Figure 50: Demand for manganese oxide nanopowders, by applications
Figure 51: Demand for manganese oxide nanopowders, 2010, tons
Table 36: Production of manganese oxide nanopowders, conservative estimate 2002-2016, tons
Figure 53: Production of manganese oxide nanopowders, conservative estimate 2002-2016, tons
Table 37: Nanoclay nanocomposites: Types and application
Table 38: Applications timeline for nanoclays
Figure 54: Demand for nanoclays, by applications
Figure 55: Demand for nanoclays, 2010, tons
Figure 56: Revenues for nanoclays, 2010, US$
Table 40: Production of nanoclays, conservative estimate 2002-2016, tons
Figure 57: Production of nanoclays, conservative estimate 2002-2016, tons
Table 41: Applications timeline for nanofibers
Figure 58: Demand for nanofibers, by applications
Figure 59: Demand for nanofibers, 2010, tons
Figure 60: Revenues for nanofibers, 2010, US$
Table 42: Production of nanofibers, conservative estimate 2002-2016, tons
Figure 61: Production of nanofibers, conservative estimate 2002-2016, tons
Table 43: Nanosilver: Properties and applications
Figure 62: Demand for nanosilver, by applications
Figure 63: Demand for nanosilver, 2010, tons
Figure 64: Revenues for nanosilver, 2010, US$
Table 44: Production of nanosilver, conservative estimate 2002-2016, tons
Figure 45: Production of nanosilver, conservative estimate 2002-2016, tons
Table 46: Nickel oxide nanopowders: Properties and applications
Figure 65: Demand for nickel oxide nanopowders, by applications
Figure 66: Demand for nickel oxide nanopowders, 2010, tons
Figure 67: Revenues for nickel oxide nanopowders, 2010, US$
Table 47: Production of nickel oxide nanopowders, conservative estimate 2002-2016, tons
Figure 68: Production of nickel oxide nanopowders, conservative estimate 2002-2016, tons
Table 48: Quantum dots: Properties and applications
Figure 69: Demand for quantum dots, by applications
Figure 70: Demand for quantum dots, 2010, kilograms
Figure 71: Revenues for quantum dots, 2010, US$
Table 49: Production of quantum dots, conservative estimate 2008-2016, kilograms
Figure 72: Production of quantum dots, conservative estimate 2002-2016, kilograms
Table 50: Silicon oxide nanopowders: Properties and applications
Figure 73: Demand for silicon oxide nanopowders, by applications
Figure 74: Demand for silicon oxide nanopowders, 2010, tons
Figure 75: Revenues for silicon oxide nanopowders, 2010, US$
Table 51: Production of silicon oxide nanopowders, conservative estimate 2002-2016, tons
Figure 76: Production of silicon oxide nanopowders, conservative estimate 2002-2016, tons
Table 52: Titanium dioxide nanopowders: Properties and applications
Figure 77: Demand for titanium dioxide nanopowders, by applications
Figure 78: Demand for titanium dioxide nanopowders, 2010, tons
Figure 79: Revenues for titanium dioxide nanopowders, 2010, US$
Table 53: Production of titanium dioxide nanopowders, conservative estimate 2002-2016, tons
Figure 80: Production of titanium dioxide nanopowders, conservative estimate 2002-2016, tons
Table 54: Yttrium oxide nanopowders: Properties and applications
Figure 81: Demand for yttrium oxide nanopowders, by applications
Figure 82: Demand for yttrium oxide nanopowders, 2010, tons
Figure 83: Revenues for yttrium oxide nanopowders, 2010, US$
Table 55: Production of yttrium oxide nanopowders, conservative estimate 2002-2016, tons
Figure 84: Production of yttrium oxide nanopowders, conservative estimate 2002-2016, tons
Table 56: Zinc oxide nanopowders: Properties and applications
Figure 85: Demand for zinc oxide nanopowders, by applications
Figure 86: Demand for zinc oxide nanopowders, 2010, tons
Figure 87: Revenues for zinc oxide nanopowders, 2010, US$
Table 57: Production of zinc oxide nanopowders, conservative estimate 2002-2016, tons
Figure 88: Production of zinc oxide nanopowders, conservative estimate 2002-2016, tons
Table 58: Zirconium oxide nanopowders: Properties and applications
Figure 89: Demand for zirconium oxide nanopowders, by applications
Figure 90: Demand for zirconium oxide nanopowders, 2010, tons
Figure 91: Revenues for zirconium oxide nanopowders, 2010, US$
Table 59: Production of zirconium oxide nanopowders, conservative estimate 2002-2016, tons
Figure 92: Production of zirconium oxide nanopowders, conservative estimate 2002-2016, tons


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