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市場調查報告書

打破規則:新的超材料,誘導物質性能至新方向

Breaking the Rules: Emerging Metamaterials Drive Performance in New Directions

出版商 Lux Research 商品編碼 309490
出版日期 內容資訊 英文
商品交期: 最快1-2個工作天內
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打破規則:新的超材料,誘導物質性能至新方向 Breaking the Rules: Emerging Metamaterials Drive Performance in New Directions
出版日期: 2014年07月23日 內容資訊: 英文
簡介

所謂奈米材料,是源自小心調整的微型結構/奈米結構,具有非凡機械性、電磁性、音響性特性的材料。使用遠比光的波長小解析度的「超級鏡片」,及在物體週邊完全扭曲電磁性輻射的「透明斗篷」等代表性案例,尤其在通訊、電子學、國防的領域,展現帶來大規模且創新效果的可能性。可是,這樣的技術可否實現,取決於細微圖形化可實現,且是否能開發有成本效益的製造方法。

本報告提供全球超材料的開發、實用化的現況與未來展望相關分析、主要開發企業的進展,及短、中、長期性的市場機會調查,依據專利活動和到目前為止的商用化的動向,今後應用領域相關考察。

摘要整理

市場環境

  • 由於正確模式化材料的微結構,開發商可引出其他材料找不到的有效特性

市場分析

  • 許多企業、組織進行超材料的開發,不過往往商業化遲滯,也很難建立確實的預測

未來展望

圖表一覽

  • 圖:說明市場結構對技術特性的影響的長期分析天線
  • 圖:這50年的超材料開發動向
  • 表格:超材料的新特性:3個觀點的評估
  • 圖:實現SRR(隙環共振器)的排列和金屬粒子產生的電磁超材料
  • 圖:音響性超材料幾乎由任何物質都能做出
  • 圖:Duke和Penn State在論文發表上領先全球
  • 表格:部分產品推出團隊,專門在電磁的超材料
  • 表格:美國、EU、中國政府的研究開發(R&D)佔支出額大半
  • 圖:以通訊、電子學、國防部門為目標的開發企業
  • 圖:超材料的應用領域的擴大預測
目錄

Metamaterials are materials that derive unusual mechanical, electromagnetic, or acoustic properties from a carefully controlled microstructure or nanostructure. Proof-of-concept demonstrations such as "superlenses" that can produce images with resolutions much smaller than the wavelength of light used, or "invisibility cloaks" that redirect electromagnetic radiation completely around an object, suggest high long-term disruptive potential, particularly in communications, electronics, and defense. However, practical implementation of these technologies depends on developing cost-effective manufacturing methods that allow fine patterning. This report assesses the current state of metamaterial research and commercial progress, identifies leading developers, and highlights near-, medium-, and long-term opportunities. In addition, the report forecasts future metamaterials adoption based on patent activity and commercial milestones to date.

Table of Contents

EXECUTIVE SUMMARY

LANDSCAPE

By finely patterning material microstructure, developers can tune effective properties to values not found in any bulk materials.

ANALYSIS

Many organizations develop metamaterials, but commercial adoption will be slow and staggered.

OUTLOOK

Table of Figures

  • Figure 1: Graphic Log-periodic Antenna Illustrates How Structure Can Influence Properties
  • Figure 2: Graphic Metamaterials Development Dates Back 50 Years
  • Figure 3: Table Three Major Classes of Metamaterials Exhibit Novel Properties
  • Figure 4: Graphic Arrays of SRRs (left) and Metallic Particles (right) Enable Electromagnetic Metamaterials
  • Figure 5: Graphic Acoustic Metamaterials Can Be Made from Almost Any Substance
  • Figure 6: Graphic Duke and Penn State Lead on Published Papers
  • Figure 7: Table Limited Start-up Community Focuses on Electromagnetic Metamaterials
  • Figure 8: Table U.S., EU, and China Lead Government R&D Funding
  • Figure 9: Graphic Corporate Developers Target Communications, Electronics, and Defense
  • Figure 10: Graphic Widespread Use of Metamaterials Projected in 2024
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