兆赫的商業機會:能源、醫療、安防、通訊及其他市場與科技領域(2027-2047 年)
市場調查報告書
商品編碼
2065420

兆赫的商業機會:能源、醫療、安防、通訊及其他市場與科技領域(2027-2047 年)

Terahertz Business Opportunities: Energy, Medical, Security, Telecoms, Other Markets, Technology 2027-2047

出版日期: | 出版商: Zhar Research | 英文 346 Pages | 商品交期: 最快1-2個工作天內

價格
簡介目錄

概括

兆赫領域目前正處於快速發展階段,蘊藏著巨大的機遇,而本報告正是該領域的重要指南。由於該領域日新月異,過時的資訊已不再適用。本報告基於博士級的分析,全面涵蓋了2025年至2026年的研究和相關措施。此外,本報告權威性強,並提供了切實可行的觀點。 2026年,報告的第一作者彼得·哈羅普博士在日本舉辦了一場兆赫網路研討會,並提供日語同聲傳譯,吸引了許多參與者。他也為韓國亞洲大學和倫敦瑪麗女王大學的教授和研究人員舉辦了兆赫講座。

視野開闊,觀點獨特,表達清晰。

本報告涵蓋了從微瓦到兆瓦級、從電子學到重型電機工程的廣泛應用領域。報告重點介紹了兆赫波段(0.1–10 THz)的現有和潛在應用,著重闡述了特定材料和裝置的獨特且寶貴的特性。此波段有時稱為亞太赫茲波段(0.1–0.3 THz),較遠的波段則稱為遠紅外線波段。

本報告旨在為兆赫價值鏈上的所有參與者提供支持,特別是材料、硬體和系統領域的從業者。報告包含八個章節、八份SWOT分析、27張全新資訊圖表、多份藍圖以及42條說明的預測線。這體現了我們對商業性成功和社會貢獻的清晰闡述。哪些合作夥伴及收購專案前景可期?哪些應用和產業最具發展潛力?本報告兼顧正面和負面兩方面,避免誇大其詞和盲目樂觀。說明並評估了大量的科學研究和企業發展成果,並為進一步研究提供了參考資料。

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目錄

第1章:摘要整理與結論

  • 本報告的目的和範圍
  • 本分析的調查方法與重點領域
  • 主要結論,包括三張資訊圖表。
  • 實行技術和SWOT評估
  • 兆赫研究領域的領先中心,擁有關鍵領域的專家。
  • 藍圖
  • 市場預測:附表格、圖表和說明。
    • 太赫茲硬體:以 5 個類別分類
    • 太赫茲硬體市場區域構成比:按 4 個區域分類
    • 光學和光電子學 6G 材料和裝置市場
    • 按安裝位置(客戶端設備、CPE、RIS、其他)分類的 6G 功能性材料市場構成比
    • 智慧型手機及後續設備的全球銷售:兩種情景
    • 基地台市場:6G 與 5G:年銷售量
    • 如果6G成功,6G基地台市場的規模將非常龐大。
    • 6G RIS的市場規模
    • 6G RIS的銷售面積
    • 6G RIS 的平均價格:出廠價,包含電子元件。
    • 6G RIS市場規模:主動型、4種半被動型,以及以太赫茲和其他頻率分類
    • 6G全被動式超材料反射陣列市場:OWC與整體狀況
    • 電磁超構裝置市場:依應用領域分類

第2章:2025年和2026年應用的介紹和擴展

  • 定義和範圍
  • 本報告介紹了九種有用的太赫茲特性。
  • 太赫茲頻率與其他頻率相比的應用
  • 太赫茲技術的醫療及相關應用
  • 6G通訊與太赫茲技術是在後期添加的。
  • 用於食品分析的太赫茲技術
  • 用於量子和地球觀測的兆赫電光技術:TEQO
  • Teradar機器人車輛導航
  • 提供軍用衛星隱身及其他功能。
  • 兆赫技術用於封裝積體電路的無損缺陷檢測

第3章:太赫茲的醫學診斷、治療與生理效應

  • 概述
  • 太赫茲的生理效應:熱效應與非熱效應
  • 兆赫技術在神經科學領域的進展
  • 利用兆赫診斷和治療頭頸部疾病
  • 兆赫內視鏡技術的進展
  • 視網膜、人工電子耳和心臟植入的精確刺激和無線控制。
  • 太赫茲醫療設備
    • 分子、蛋白質和細胞感測與成像:太赫茲生物檢測、奈米顯微鏡、超高解析度成像和光譜學概述。
    • 太赫茲感測器、超高解析度成像、奈米顯微鏡、光譜學:眾多重大進展
    • 用於醫療和其他用途的兆赫離子凝膠和水凝膠
  • SHINE Technologies(美國)
  • TeraSense(美國)
  • Teraview(美國):包括藥品和電池的品管。

第4章:太赫茲迴旋管及相關裝置在核融合發電、感測、光譜、軍事應用等方面的應用。

  • 概述
  • 迴旋管設計及其應用
  • 太赫茲迴旋管驅動的等離子體技術:研究方向與應用
  • 太赫茲迴旋管及相關裝置的性能與改進
  • 太赫茲迴旋管的應用
    • 軍事和安全應用:微波和太赫茲
    • 用於核融合發電和其他高功率應用的等離子體加熱:眾多研究進展
    • 感測、成像、安全
    • 材料加工
    • 核磁共振和其他高精度光譜學
    • 其他案例

第5章:將太赫茲頻率加入 6G 和其他通訊技術中

  • 概述
    • 6G頻段、硬體及其他計劃
    • 太赫茲和其他RIS
  • 資訊圖表:從1G到6G部署的進展以及太赫茲技術的到來
  • Infogram:6G 在基礎設施和客戶端設備方面的材料機遇
  • 資訊圖表:6G光元件/光電子元件應用擴展
  • 分析太赫茲和其他 6G 技術在地面和航太領域的應用機遇,並附有資訊圖表。
  • 針對太赫茲、近紅外線和可見光頻率的最新 6G 相關研究,提供材料和成功建議。
  • 資訊圖表:從離散基板和層壓薄膜到完全智慧材料整合的發展趨勢
  • 資訊圖表:按運作頻率的 6G 硬體列印選項
  • 5項SWOT分析
  • 2025年至2026年6G兆赫研究進展
  • 中興通訊(中國)
  • Toptica(德國)

第6章:用於高速通訊、診斷及其他應用的太赫茲波導管

  • 概述:定義、基本類型、SWOT分析
  • 挑戰與創新,包括進展
  • 太赫茲波導管的應用與研究進展
    • 天文物理學
    • 化學分析
    • 高速通訊和無線通訊系統
    • 無損檢測
    • 醫學診斷
    • 流程監控
    • 安全與檢查
    • 感測、生物分子鑑定、非侵入性細胞分析
    • 光譜學
    • 發送器和加速器
  • 目前及未來的太赫茲波導管材料及實用原理
  • 採用 3D 列印技術製造的長卷聚合物太赫茲電纜、波導管。

第7章 感測器、成像、光譜、產生器和實行技術:太赫茲超材料、2D材料、太赫茲雷射器

  • 研究進展:概述
  • 實行技術:超材料、2D材料、技術進步
  • 感應器
    • 基礎:仿生技術、輸入、結構、輸出、智慧感測器
    • 例如:光子晶體光纖表面等離子體共振(PCF-SPR)太赫茲感測器
    • 其他利用或檢測太赫茲的感測器及其進展
  • 超高解析度成像和光譜學的基本原理及進展
  • 發生器:X光源和太赫茲雷射產生領域的進展
  • 太赫茲雷射

第8章兆赫層狀結構與晶片結構:天線、片上裝置、自旋電子學、等離子體激元學、太赫茲場效電晶體、諧振隧道二極體

  • 概述及近期案例
  • 太赫茲天線
    • 任務
    • 資訊圖表:太赫茲天線的未來
    • 太赫茲天線設計方案:研究進展
    • 太赫茲光電導天線:研究進展
  • 下一代片上太赫茲系統:包括自旋電子學、等離子激元學和太赫茲場效電晶體。
    • 概述及新興的大面積太赫茲光子電路
    • 自旋電子學
    • 等離子體激元:太赫茲場效電晶體
    • ROHM(日本):諧振隧道二極體晶片
簡介目錄

Summary

Terahertz is now a rapidly-growing, large opportunity and your essential guide is the new 346-page Zhar Research report, “Terahertz Business Opportunities: Energy, Medical, Security, Telecoms, Other Markets, Technology 2027-2047”. Its PhD level analysis intensively covers research and initiatives 2025-6 because old news is useless in this fast-moving topic. It is commercially-oriented. The report is authoritative. In 2026, its primary author Dr Peter Harrop presented a well-attended Terahertz webinar across Japan, with Japanese translation. He also lectured on Terahertz to professors and researchers at Ajou University in Korea and Queen Mary University London.

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Your next growth opportunity

Here is your next growth opportunity leveraging your device and materials skills with many examples of premium pricing embracing new cancer treatments to energising planned fusion power reactors. Monetise your skills in state-of-the-art materials and fabrication including graphene, sensors, antennas and lasers achieving what was previously impossible.

Wide scope, independent viewpoint, lucid presentation

The report spans microwatt to megawatt applications – electronics to heavy electrical engineering. It includes existing and potential applications created by the valuable, unique properties of certain materials and devices in this Terahertz region of 0.1-10THz. It is sometimes called sub-THz at 0.1-0.3THz and far infrared beyond that.

The report assists all in the terahertz value chain, particularly those in materials, hardware and systems. See 8 chapters, 8 SWOT appraisals, 27 new infograms, several roadmaps and 42 forecast lines with explanations because the emphasis is on clarity concerning achievement of commercial success and benefitting society. What partners and acquisitions? Which applications and industries are most promising? Negatives are presented alongside positives not evangelism and frothy forecasting. A flood of scientific reports and company advances are described, assessed and referenced for your further reading.

The executive summary and conclusions (55 pages) has basics, key conclusions, materials analysis, the SWOT appraisals, main infograms and roadmaps. The introduction (22 pages) explains terahertz frequencies and several applications with 2025-6 research examples.

Exceptionally wide medical uses, companies involved

Chapter 3. THz medical diagnosis, treatment and physiological effects takes 41 pages to cover one of the sectors that is most advanced in commercial use of THz frequencies. Indeed later chapters on various THz technologies have much on medical aspects as well. See physiological effects, thermal and non-thermal from heavy doses, THz terahertz technology in neuroscience and generally with many examples from research and current practice using harmless low doses. Terahertz endoscopy advances through 2025-6 are here. Understand other THz medical tools notably sensors including sensing and imaging molecules, proteins, cells: THz bio-detection, nanoscopy, super-resolution imaging, including medical super-resolution imaging, nanoscopy and spectroscopy: many major advances 2025-6. See THz ionogels and hydrogels. Three company activities are profiled: SHINE Technologies, TeraSense and Teraview.

Gyrotrons and derivatives demanded

Chapter 4. concerns THz gyrotrons, allied devices for nuclear fusion power, sensing, spectroscopy, military etc (32 pages) concerns these large devices that are starting to be commercialised and have a large potential. About half concerns their design evolution with much emphasis on latest research advances 2025-6 including use of advanced materials such as high temperature superconductors. Then applications, actual and potential of THz Gyrotrons are detailed including military, security, plasma heating for nuclear fusion power and other high power compared to use for sensing, imaging and in security scanning, material processing, nuclear magnetic resonance, other high precision spectroscopy and more.

Communications big later

6G Communications is planned to launch in 2030 but with almost no use of THz because it will relay almost entirely on 5G frequencies and advances above the physical layer to save cost. However, around 2035 it must heavily use THz and optical frequencies if it is to meet most of its promises so Chapter 5. “6G and other communications adding THz frequencies” (48 pages) covers this large commercial opportunity for many THz technologies in detail. This includes transmitters, reconfigurable intelligent surfaces enhancing the propagation path, receivers and other aspects. There are many SWOT appraisals and 2025-6 research advances interpreted, even analysis of the winning materials. Learn how multi-frequency systems will emerge, “so one gets through” in various weather conditions but, in the THz band, over 1THz is assessed as useless for wireless telecommunications.

Enabling technologies

The remaining chapters concern enabling technologies for emerging THz applications- devices and special materials and constructs – all widely-applicable “horizontals”. Chapter 6. Is “THz waveguides for high-speed communication, diagnostics, other” (38 pages). Learn how they will be important in astrophysics, chemical analysis, high-speed communication and wireless systems, non-destructive testing, medical diagnostics,, sensing, biomolecule identification and non-invasive cell analysis, process monitoring, security, inspection, spectroscopy, transmitters and accelerators. Advanced materials demonstrated for THz waveguides include PTFE porous fiber, PBVE, PE-PP metamaterials, InAs, GaP and sapphire all covered in detail emphasising 2025-6 advances and THz waveguide manufacturing technologies such as infinity 3D printing.

Chapter 7. Sensors, imaging, spectroscopy, generators and enabling technologies THz metamaterials, 2D materials, THz lasers takes 71 pages because there is considerable progress and potential here. It teaches you how THz metamaterials are mainly usefully laminar, populated with components to create metasurfaces but trending to multi-purpose structural electronics. THz metamaterials. Graphene is, by far, the winning THz 2D material but what others are in contention and why? Sensors are so important, they are covered from basics to biomimetics, inputs, anatomy, outputs, smart sensors. Enjoy the example Photonic Crystal Fiber Surface Plasmon Resonance (PCF-SPR) THz sensors and other sensors using or detecting THz with advances through 2025-6. Then comes THz super-resolution imaging and spectroscopy basics and advances through 2025-6, generators: X-ray sources, THz lasers and THz laser-generated fields advances through 2025-6, uniques and applications.

Chapter 8 then ends the report with 21 pages on “Terahertz laminar constructs: antennas, spintronics and plasmonics”. There is an overview with recent examples, THz antennas including challenges, infogram on their future, design options with research advances 2025-6. Here are THz emerging new photoconductive antennas and the employment of spintronics and plasmonics.

This is the clearest, unbiassed, most up-to-date guide to your multi-billion-dollar, new commercial opportunities with this technology. Get in just as the sales surge.

CAPTION: Primary mentions of THz device non-metals in latest research and analysis. Source: Zhar Research report, “Terahertz Business Opportunities: Energy, Medical, Security, Telecoms, Other Markets, Technology 2027-2047”.

Table of Contents

1. Executive summary and conclusions

  • 1.1 Purpose and scope of this report
  • 1.2 Methodology and focus of this analysis
  • 1.3 Key conclusions with three infograms
  • 1.4 Enabling technologies and SWOT appraisals
    • 1.4.1 Techniques for THz generation
    • 1.4.2 THz waveguide and fiber designs and their uses
    • 1.4.3 Infogram: The future of THz antennas
    • 1.4.4 Seven SWOT appraisals
  • 1.5 Centers of THz excellence and specialists in key verticals
  • 1.6 Roadmaps 2027-2047
    • 1.6.1 6G Communication systems, materials and standards roadmaps in six lines 2027-2047
    • 1.6.2 Fusion and allied systems, materials and hardware roadmap for technology vs market 2027-2047
  • 1.7 Market forecasts in 44 lines with tables, graphs and explanation 2027-2047
    • 1.7.1 THz hardware in 5 categories, $ billion 2027-2047 tables, graphs, explanation
    • 1.7.2 Percentage share of terahertz hardware value market by four regions 2026-2046
    • 1.7.3 Optical and optronic 6G materials and device market 2027-2047
    • 1.7.4 Functional materials for 6G value market % by location: client devices, CPE, RIS, other 2027-2047
    • 1.7.5 Smartphone and successor billion units sold globally 2024-2047 in two scenarios
    • 1.7.6 Market for 6G vs 5G base stations units millions yearly 2025-2047
    • 1.7.7 6G base stations market value $bn if 6G successful 2029-2047
    • 1.7.8 6G RIS value market 2027-2047 $ billion
    • 1.7.9 6G RIS area sales yearly billion square meters 2027-2047
    • 1.7.10 Average 6G RIS price $/ square m. ex-factory including electronics 2028-2047
    • 1.7.11 6G RIS value market $ billion: active vs four semi-passive categories by THz and other frequency 2026-2047
    • 1.7.12 6G fully passive metamaterial reflect-array market OWC and total $ billion 2029-2047
    • 1.7.13 Electromagnetic meta-device market $ billion by application segment 2025-2047

2. Introduction with examples of widening applications in 2025 and 2026

  • 2.1 Definition and scope
  • 2.2 Nine useful THz characteristics appearing in this report
  • 2.3 THz uses compared to adjoining frequencies
  • 2.4 Medical and allied applications of THz technology
  • 2.5 6G Communications adding THz later
  • 2.7 THz technology for food analysis
  • 2.8 Terahertz Electro-optics for Quantum and Earth Observation TEQEO
  • 2.9 Teradar robot vehicle navigation
  • 2.10 Providing military satellite stealth and other functions
  • 2.11 Terahertz Technology for Non⁃Destructive Defect Detection in Packaged Integrated Circuits

3. THz medical diagnosis, treatment and physiological effects

  • 3.1 Overview
  • 3.2 THz physiological effects, thermal and non-thermal
  • 3.3 Advances of terahertz technology in neuroscience
    • 3.3.1 General potential
    • 3.3.2 Terahertz stimulation alleviates anxiety: research advances
  • 3.4 THz diagnosis and treatment of head and neck diseases
  • 3.5 Terahertz endoscopy advances through 2025-6
  • 3.6 Precise stimulation and wireless control in retinal, cochlear, cardiac implants
  • 3.7 THz medical tools
    • 3.7.1 Sensing and imaging molecules, proteins, cells: THz bio-detection, nanoscopy, super-resolution imaging, spectroscopy overview
    • 3.7.2 THz sensors, super-resolution imaging, nanoscopy and spectroscopy: many major advances 2025-6
    • 3.7.3 Terahertz ionogels and hydrogels for medical and other purposes
  • 3.8 SHINE Technologies USA
  • 3.9 TeraSense USA
  • 3.10 Teraview USA including pharmaceutical and battery quality control

4. THz gyrotrons, allied devices for nuclear fusion power, sensing, spectroscopy, military etc

  • 4.1 Overview
  • 4.2 Gyrotron designs and their uses
  • 4.3 Plasma technology sometimes powered by THz gyrotrons: initiatives, applications
  • 4.4 Capability and improvement of THz gyrotrons and allied devices 2025-2046
    • 4.4.1 Increasing frequency to aid performance including Kyoto Fusioneering Japan
    • 4.4.2 Many THz gyrotron research advances 2025-6
  • 4.5 Applications of THz Gyrotrons
    • 4.5.1 Military and security applications: microwave and THz
    • 4.5.2 Plasma heating for nuclear fusion power and other high power: many research advances 2025-6
    • 4.5.3 Sensing, imaging and security
    • 4.5.4 Material processing
    • 4.5.5 Nuclear magnetic resonance and other high precision spectroscopy
    • 4.5.6 Other examples

5. 6G and other communications adding THz frequencies

  • 5.1 Overview
    • 5.1.1 6G frequencies, hardware and other plans
    • 5.1.2 THz and other RIS
  • 5.2 Infogram: Progress from 1G-6G rollouts 1980-2046 with THz arrival
  • 5.3 Infogram: 6G materials opportunities with infrastructure and client devices 2026-2046
  • 5.4 Infograms: increasing adoption of optics/ optronics for 6G
    • 5.4.1 Infogram of some options
    • 5.4.2 Poor progress to make THz useful outdoors for 6G Communications
    • 5.4.3 Sub-THz range meters achieved in good weather by LG and Samsung with Gbps levels of data
    • 5.4.4 The case for multi-frequency 6G Phase Two including THz “so one gets through”
    • 5.4.5 Primary wireless transmission parameters of 6G compared by frequency: subTHz to visible
    • 5.4.6 Pie chart: Mismatch of planned and researched 6G frequencies may invite usurpers
  • 5.5 Analysis of 6G opportunities THz and other on Earth and in aerospace with infograms
  • 5.6 Winning materials in 245 latest THz, nearIR and visible frequency 6G-related researches and recommendations
  • 5.7 Infogram: Trend from discrete boards, stacked films to full smart material integration
  • 5.8 Infogram: Printing options for 6G hardware by frequency of operation
  • 5.9 Five SWOT appraisals
    • 5.9.1 SWOT appraisal of 6G adding sub-THz, THz, near infrared and visible frequencies
    • 5.9.2 SWOT appraisal of Optical Wireless Communications for 6G
    • 5.9.3 6G RIS SWOT appraisal
    • 5.9.4 Simultaneous Transmission And Reflection STAR-RIS SWOT appraisal
    • 5.9.5 SWOT appraisal of terahertz far infrared cable waveguides in 6G system design
  • 5.10 6G THz research advances through 2025-6
  • 5.11 ZTE China
  • 5.12 Toptica Germany

6.THz waveguides for high-speed communication, diagnostics, other

  • 6.1 Overview: definition, basic types, SWOT
    • 6.1.1 Definition, basic types
    • 6.1.2 A closer look with examples and SWOT
  • 6.2 Challenges and innovations with 2025-6 advances
  • 6.3 THz waveguide applications with some 2025-6 research advances
    • 6.3.1 Astrophysics
    • 6.3.2 Chemical analysis
    • 6.3.3 High-speed communication and wireless systems
    • 6.3.4 Non-destructive testing
    • 6.3.5 Medical diagnostics
    • 6.3.6 Process monitoring
    • 6.3.7 Security and inspection
    • 6.3.8 Sensing, biomolecule identification, non-invasive cell analysis
    • 6.3.9 Spectroscopy
    • 6.3.10 Transmitters and accelerators
  • 6.4. Current and future THz waveguide materials and principles in action
    • 6.4.1 Formulations: examples of compounds and plasmonics advances through 2025-6
    • 6.4.2 Advanced materials demonstrated for THz waveguides: 2025-6 research advances
  • 6.5 Manufacturing polymer THz cable in long reels and waveguides and 3D printing

7. Sensors, imaging, spectroscopy, generators and enabling technologies THz metamaterials, 2D materials, THz lasers

  • 7.1 Overview research advances 2025-6
  • 7.2 Enabling technologies: metamaterials, 2D materials with advances 2025-6
    • 7.2.1 THz metamaterials
    • 7.2.2 THz 2D materials
  • 7.3 Sensors
    • 7.3.1 Basics: biomimetics, inputs, anatomy, outputs, smart sensors
    • 7.3.2 Example: Photonic Crystal Fiber Surface Plasmon Resonance (PCF-SPR) THz sensors
    • 7.3.3 Other sensors using or detecting THz with advances through 2025-6
  • 7.4 Super-resolution imaging and spectroscopy basics and advances through 2025-6
  • 7.5 Generators: X-ray sources, THz laser-generated fields advances through 2025-6
  • 7.6 THz lasers
    • 7.6.1 Uniques and applications
    • 7.6.2 Technologies
    • 7.6.3 Research advances through 2025-6

8. Terahertz laminar and chip constructs: antennas, on-chip, spintronics, plasmonics, TeraFET, resonant tunnelling diodes

  • 8.1 Overview with recent examples
  • 8.2 Terahertz antennas
    • 8.2.1 Challenges
    • 8.2.2 Infogram: The future of THz antennas
    • 8.2.3 THz antenna design options with research advances 2025-6
    • 8.2.4 THz photoconductive antennas: research advances 2025-6
  • 8.3 Next-generation on-chip THz systems, including spintronics, plasmonics, TeraFET 2025-6
    • 8.3.1 Overview and emerging large area THz photonic circuits
    • 8.3.2 Spintronics
    • 8.3.3 Plasmonics including TeraFET
    • 8.3.4 ROHM Japan and resonant tunnelling diode chips