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세계의 열전재료 시장 분석과 예측(2018-2023년) : 텔루르화 비스무트, 텔루르화 납, 실리콘 게르마늄

Global Thermoelectric Materials Market: Focus on Type (Bismuth Telluride, Lead Telluride and Silicon Germanium) and Application (Healthcare, Automotive, Industrial, Electrical and Electronics) - Analysis & Forecast, 2018-2023

리서치사 BIS Research Inc.
발행일 2018년 11월 상품 코드 748998
페이지 정보 영문 201 Pages
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세계의 열전재료 시장 분석과 예측(2018-2023년) : 텔루르화 비스무트, 텔루르화 납, 실리콘 게르마늄 Global Thermoelectric Materials Market: Focus on Type (Bismuth Telluride, Lead Telluride and Silicon Germanium) and Application (Healthcare, Automotive, Industrial, Electrical and Electronics) - Analysis & Forecast, 2018-2023
발행일 : 2018년 11월 페이지 정보 : 영문 201 Pages

열전재료(Thermoelectric Materials)는 폐열을 전력으로 변환할 수 있어 장기간 R&D의 대상이었습니다. 자동차, 산업, 헬스케어 등 다양한 산업에서 이 기술의 이용이 에너지 자원 수요를 감소시키고 에너지의 적정 이용을 초래할 전망입니다. 각 공장이 온실가스의 배출 초과로 인해 생산이 제한되는 가운데 배출 감축에 기여할 수 있는 열전재료는 세계 시나리오의 초점이 되고 있습니다. 이 기술은 여전히 개발 초기 단계이나, 실현 가능성과 유효성의 검증을 위해 몇몇 파일럿 프로젝트가 진행되고 있습니다.

세계의 열전재료 시장을 조사했으며, 시장 및 제품의 개요, 시장 성장에 대한 각종 영향요인 및 시장 기회 분석, 주요 기업 개발·기업 전략, 공급망 분석, 연구 단계의 열전재료, 재료 종류·용도·지역/주요 국가별 동향과 시장 규모의 추이와 예측, 주요 기업의 개요 등을 정리하여 전해드립니다.

개요

제1장 시장 역학

  • 시장 성장 촉진요인
  • 시장 성장 억제요인
  • 시장 기회

제2장 경쟁 분석

  • 주요 개발·전략
  • 기타

제3장 산업 분석

  • 공급망 분석
  • 산업의 매력
  • 시장 기회 매트릭스 분석
  • 국가별 점유율 분석
  • 열전현상
  • 연구 단계의 열전재료
    • 칼코겐화물
    • 반-호이슬러 합금
    • 스쿠테루드광
    • 클라트레이트
    • 텔루르화안티몬(Sb2Te3)

제4장 열전재료 시장 분석·예측 : 종류별

  • 전제 요인
  • 제약
  • 시장 개요
  • 텔루르화 비스무트(Bi2Te3)
  • 텔루르화 납(PbTe)
  • 실리콘 게르마늄(SiGe)

제5장 세계의 열전재료 시장 분석·예측 : 용도별

  • 산업용
  • 자동차
  • 전기·전자
  • 헬스케어
  • 기타

제6장 열전재료 시장 분석·예측 : 지역별

  • 아시아태평양
    • 종류별
    • 용도별
    • 국가별
      • 중국
      • 일본
      • 한국
      • 기타
  • 북미
    • 종류별
    • 용도별
    • 국가별
      • 미국
      • 캐나다
      • 멕시코
  • 유럽
    • 종류별
    • 용도별
    • 국가별
      • 독일
      • 프랑스
      • 영국
      • 러시아
      • 기타
  • 기타 지역
    • 종류별
    • 용도별
    • 국가별
      • UAE
      • 브라질
      • 기타

제7장 기업 개요

  • 개요
  • EVERREDtronics Ltd.
  • Ferrotec(USA) Corporation.
  • Hitachi Ltd.
  • Jingyi Metal Material(Shanghai) Co., Ltd.
  • KELK Ltd.
  • Marlow Industries, Inc.
  • Norilsk Nickel
  • P&N Technology(Xiamen) Co., Ltd.
  • Panasonic Corporation
  • Reade International Corp.,
  • Sigma Aldrich Corporation
  • TECTEG MFR.
  • TEGma AS
  • Thermonamic Electronics(Jiangxi) Corp., Ltd.
  • TOSHIBA MATERIALS CO., LTD.

제8장 조사 범위·조사 방법

KSA 18.12.05

List of Tables

  • Table 1 Global Thermoelectric Materials Market Snapshot, 2017 and 2023
  • Table 1.1 Thermoelectric Materials with Cost
  • Table 2.1 Product Launches (2015-2018)
  • Table 2.2 Other Key Developments (2015-2018)
  • Table 4.1 Global Thermoelectric Materials Market (by Type), Metric Tons, 2016-2023
  • Table 4.2 Global Thermoelectric Materials Market (by Type), $Thousand, 2016-2023
  • Table 5.1 Global Thermoelectric Materials Market (by Application), Metric Tons, 2016-2023
  • Table 5.2 Global Thermoelectric Materials Market (by Application), $Thousand, 2016-2023
  • Table 6.1 Global Thermoelectric Materials Market (by Region), Metric Tons, 2016-2023
  • Table 6.2 Global Thermoelectric Materials Market (by Region), $Thousand, 2016-2023
  • Table 6.3 Asia-Pacific Thermoelectric Materials Market (by Type), Metric Tons, 2016-2023
  • Table 6.4 Asia-Pacific Thermoelectric Materials Market (by Type), $Thousand, 2016-2023
  • Table 6.5 Asia-Pacific Thermoelectric Materials Market (by Application), Metric Tons, 2016-2023
  • Table 6.6 Asia-Pacific Thermoelectric Materials Market (by Application), $Thousand, 2016-2023
  • Table 6.7 Asia-Pacific Thermoelectric Materials Market (by Country), Metric Tons, 2016-2023
  • Table 6.8 Asia-Pacific Thermoelectric Materials Market (by Country), $Thousand, 2016-2023
  • Table 6.9 List of Institutions based in China
  • Table 6.10 List of Thermoelectric Module Producers
  • Table 6.11 China Thermoelectric Materials Market (by Application), Metric Tons, 2016-2023
  • Table 6.12 China Thermoelectric Materials Market (by Application), $Thousand, 2016-2023
  • Table 6.13 List of Thermoelectric Module Manufacturers
  • Table 6.14 Japan Thermoelectric Materials Market (by Application), Metric Tons, 2016-2023
  • Table 6.15 Japan Thermoelectric Materials Market (by Application), $Thousand, 2016-2023
  • Table 6.16 South Korea Thermoelectric Materials Market (by Application), Metric Tons, 2016-2023
  • Table 6.17 South Korea Thermoelectric Materials Market (by Application), $Thousand, 2016-2023
  • Table 6.18 Rest-of-Asia-Pacific Thermoelectric Materials Market (by Application), Metric Tons, 2016-2023
  • Table 6.19 Rest-of-Asia-Pacific Thermoelectric Materials Market (by Application), $Thousand, 2016-2023
  • Table 6.20 North America Thermoelectric Materials Market (by Type), Metric Tons, 2016-2023
  • Table 6.21 North America Thermoelectric Materials Market (by Type), $Thousand, 2016-2023
  • Table 6.22 North America Thermoelectric Materials Market (by Application), Metric Tons, 2016-2023
  • Table 6.23 North America Thermoelectric Materials Market (by Application), $Thousand, 2016-2023
  • Table 6.24 North America Thermoelectric Materials Market (by Country), Metric Tons, 2016-2023
  • Table 6.25 North America Thermoelectric Materials Market (by Country), $Thousand, 2016-2023
  • Table 6.26 List of Thermoelectric Module and Device Manufacturers
  • Table 6.27 U.S. Thermoelectric Materials Market (by Application), Metric Tons, 2016-2023
  • Table 6.28 U.S. Thermoplastic Materials Market (by Application), $Thousand, 2016-2023
  • Table 6.29 Canada Thermoelectric Materials Market (by Application), Metric Tons, 2016-2023
  • Table 6.30 Canada Thermoelectric Materials Market (by Application), $Thousand, 2016-2023
  • Table 6.31 Mexico Thermoelectric Materials Market (by Application), Metric Tons, 2016-2023
  • Table.6.32 Mexico Thermoelectric Materials Market (by Application), $Thousand, 2016-2023
  • Table 6.33 Projects Facilitating Research on Thermoelectric Material
  • Table 6.34 Europe Thermoelectric Materials Market (by Type), Metric Tons, 2016-2023
  • Table 6.35 Europe Thermoelectric Materials Market (by Type), $Thousand, 2016-2023
  • Table 6.36 Europe Thermoelectric Materials Market (by Application), Metric Tons, 2016-2023
  • Table 6.37 Europe Thermoelectric Materials Market (by Application), $Thousand, 2016-2023
  • Table 6.38 Europe Thermoelectric Materials Market (by Country), Metric Tons, 2016-2023
  • Table 6.39 Europe Thermoelectric Materials Market (by Country), $Thousand, 2016-2023
  • Table 6.40 Germany Thermoelectric Materials Market (by Application), Metric Tons, 2016-2023
  • Table 6.41 Germany Thermoelectric Materials Market (by Application), $Thousand, 2016-2023
  • Table 6.42 France Thermoelectric Materials Market (by Application), Metric Tons, 2016-2023
  • Table 6.43 France Thermoelectric Materials Market (by Application), $Thousand, 2016-2023
  • Table 6.44 U.K. Thermoelectric Materials Market (by Application), Metric Tons, 2016-2023
  • Table 6.45 U.K. Thermoelectric Materials Market (by Application), $Thousand, 2016-2023
  • Table 6.46 Russia Thermoelectric Materials Market (by Application), Metric Tons, 2016-2023
  • Table 6.47 Russia Thermoelectric Materials Market (by Application), $Thousand, 2016-2023
  • Table 6.48 Rest-of-Europe Thermoelectric Materials Market (by Application), Metric Tons, 2016-2023
  • Table 6.49 Rest-of-Europe Thermoelectric Materials Market (by Application), $Thousand, 2016-2023
  • Table 6.50 Rest-of-the-World Thermoelectric Materials Market (by Type), Metric Tons, 2016-2023
  • Table 6.51 Rest-of-the-World Thermoelectric Materials Market (by Type), $Thousand, 2016-2023
  • Table 6.52 Rest-of-the-World Thermoelectric Materials Market (by Application), Metric Tons, 2016-2023
  • Table 6.53 Rest-of-the-World Thermoelectric Materials Market (by Application), $Thousand, 2016-2023
  • Table 6.54 Rest-of-the-World Thermoelectric Materials Market (by Country), Metric Tons, 2016-2023
  • Table 6.55 Rest-of-the-World Thermoelectric Materials Market (by Country), $Thousand, 2016-2023
  • Table 6.56 U.A.E. Thermoelectric Materials Market (by Application), Metric Tons, 2016-2023
  • Table 6.57 U.A.E. Thermoelectric Materials Market (by Application), $Thousand, 2016-2023
  • Table 6.58 Brazil Thermoelectric Materials Market (by Application), Metric Tons, 2016-2023
  • Table 6.59 Brazil Thermoelectric Materials Market (by Application), $Thousand, 2016-2023
  • Table 6.60 Others Thermoelectric Materials Market (by Application), Metric Tons, 2016-2023
  • Table 6.61 Others Thermoelectric Materials Market (by Application), $Thousand, 2016-2023
  • Table 7.1 EVERREDtronics Ltd.
  • Table 7.2 Ferrotec (USA) Corporation.
  • Table 7.3 Hitachi Ltd.: Product Portfolio
  • Table 7.4 Jingyi Metal Material (Shanghai) Co., Ltd.
  • Table 7.5 KELK Ltd.
  • Table 7.6 Marlow Industries, Inc.
  • Table 7.7 Norilsk Nickel: Product Portfolio
  • Table 7.8 P&N Technology (Xiamen) Co., Ltd.
  • Table 7.9 Panasonic Corporation: Product Portfolio
  • Table 7.10 TECTEG MFR.
  • Table 7.11 Sigma Aldrich Corporation
  • Table 7.12 TECTEG MFR.
  • Table 7.13 TEGma AS
  • Table 7.14 Thermonamic Electronics(Jiangxi) Corp., Ltd.
  • Table 7.15 TOSHIBA MATERIALS CO., LTD.: Product Portfolio

List of Figures

  • Figure 1 Global Thermoelectric Materials Market Snapshot
  • Figure 2 Global Thermoplastic Materials Market (by Type), 2017, 2018, and 2023
  • Figure 3 Global Thermoelectric Materials Market (by Application), 2017 and 2023
  • Figure 4 Global Thermoelectric Materials Market (by Region), 2017
  • Figure 5 Global Thermoelectric Materials Market (by Country), $Thousand, 2017
  • Figure 1.1 Market Dynamics
  • Figure 1.2 Impact Analysis of Drivers
  • Figure 1.3 Average Annual Fuel Use by Vehicle Type (2015)
  • Figure 1.4 World Carbon Dioxide Emission from Transport (% of Total Fuel Combustion)
  • Figure 1.5 Utilization of Fuel in a Vehicle
  • Figure 1.6 Impact Analysis of Restraints
  • Figure 1.7 Impact Analysis of Opportunity
  • Figure 2.1 Strategies Adopted by the Key Players
  • Figure 2.2 Share of Key Market Strategies and Developments, 2015-2018
  • Figure 2.3 Global Thermoelectric Materials Market Share Analysis 2017
  • Figure 3.1 Global Thermoelectric Materials Market Supply Chain
  • Figure 3.2 Global Thermoelectric Materials Porter's Five Forces Analysis
  • Figure 3.3 Global Thermoelectric Materials Market Opportunity Matrix (by Region), $Thousand, 2018-2023
  • Figure 3.4 Global Thermoelectric Materials Market Opportunity Matrix (by Country), 2017
  • Figure 3.5 Country Share Analysis of Global Thermoelectric Materials Market, 2017
  • Figure 3.6 Country Share Analysis of Global Thermoelectric Materials Market, 2017
  • Figure 4.1 Global Thermoelectric Material Market (by Type)
  • Figure 4.2 Global Thermoelectric Materials Market (by Type), 2017 and 2023
  • Figure 4.3 Bismuth Telluride in Global Thermoelectric Materials Market, 2016-2023
  • Figure 4.4 Lead Telluride in Global Thermoelectric Materials Market, 2016-2023
  • Figure 4.5 Silicon Germanium in Global Thermoelectric Materials Market, 2016-2023
  • Figure 5.1 Global Thermoelectric Materials Market (by Application)
  • Figure 5.2 Global Thermoelectric Materials Market (by Application), 2017 and 2023
  • Figure 5.3 Global Thermoelectric Materials Market in Industrial Application, 2016-2023
  • Figure 5.4 Global Thermoelectric Materials Market for Automotive Application, 2016-2023
  • Figure 5.5 Global Thermoelectric Materials Market for Electrical & Electronics Application, 2016-2023
  • Figure 5.6 Global Thermoelectric Materials Market for Healthcare Application, 2016-2023
  • Figure 5.7 Global Thermoelectric Materials Market for Other Applications, 2016-2023
  • Figure 6.1 Thermoelectric Materials Market (by Region)
  • Figure 6.2 Thermoelectric Materials Market Overview (by Region)
  • Figure 6.3 Global Thermoelectric Materials Market Share (by Region), 2016 & 2023, $Thousand and Metric Tons
  • Figure 6.4 Primary Energy Consumption (Million Tons Oil Equivalent)
  • Figure 6.5 Asia-Pacific Thermoelectric Materials Market (by Type), Metric Tons, 2017, 2018, and 2023
  • Figure 6.6 Asia-Pacific Thermoelectric Materials Market (by Type), $Thousand, 2017, 2018, and 2023
  • Figure 6.7 Asia-Pacific Thermoelectric Materials Market (by Application), Metric Tons, 2017 and 2023
  • Figure 6.8 Asia-Pacific Thermoelectric Materials Market (by Application), 2017 and 2023
  • Figure 6.9 Asia-Pacific Thermoelectric Materials Market (by Country), Metric Tons, 2017 and 2023
  • Figure 6.10 Asia-Pacific Thermoelectric Materials Market (by Country), $Thousand, 2017 and 2023
  • Figure 6.11 China Thermoelectric Materials Market, 2016-2023
  • Figure 6.12 Japan Thermoelectric Materials Market, 2016-2023
  • Figure 6.13 South Korea Thermoelectric Materials Market, 2016-2023
  • Figure 6.14 Rest-of-Asia-Pacific Thermoelectric Materials Market, 2016-2023
  • Figure 6.15 Primary Energy Consumption (Million Tons Oil Equivalent)
  • Figure 6.16 North America Thermoelectric Materials Market (by Type), 2017, 2018, and 2023
  • Figure 6.17 North America Thermoelectric Materials Market (by Type), 2017, 2018, and 2023
  • Figure 6.18 North America Thermoelectric Materials Market (by Application), 2017 and 2023
  • Figure 6.19 North America Thermoelectric Materials Market (by Application), 2017 and 2023
  • Figure 6.20 North America Thermoelectric Materials Market (by Country), 2017 and 2023
  • Figure 6.21 U.S. Thermoelectric Materials Market, 2016-2023
  • Figure 6.22 Canada Thermoelectric Materials Market, 2016-2023
  • Figure 6.23 Mexico Thermoelectric Materials Market, 2016-2023
  • Figure 6.24 Primary Energy Consumption (Million Tons Oil Equivalent) for Europe, 2013-2017
  • Figure 6.25 Europe Thermoelectric Materials Market (by Type), 2017, 2018, and 2023
  • Figure 6.26 Europe Thermoelectric Materials Market (by Type), 2017, 2018, and 2023
  • Figure 6.27 Europe Thermoelectric Materials Market (by Application), 2017 & 2023
  • Figure 6.28 Europe Thermoelectric Materials Market (by Application), 2017 and 2023
  • Figure 6.29 Europe Thermoelectric Materials Market (by Country), Metric Tons, 2017 and 2023
  • Figure 6.30 Europe Thermoelectric Materials Market (by Country), $Thousand, 2017 and 2023
  • Figure 6.31 Germany Thermoelectric Materials Market, 2016-2023
  • Figure 6.32 France Thermoelectric Materials Market, 2016-2023
  • Figure 6.33 U.K. Thermoelectric Material Market, 2016-2023
  • Figure 6.34 Russia Thermoelectric Material Market, 2016-2023
  • Figure 6.35 Rest-of-Europe Thermoelectric Materials Market, 2016-2023
  • Figure 6.36 Rest-of-the-World Thermoelectric Materials Market (by Type), 2017, 2018, and 2023
  • Figure 6.37 Rest-of-the-World Thermoelectric Materials Market (by Type), 2017, 2018, and 2023
  • Figure 6.38 Rest-of-the-World Thermoelectric Materials Market (by Application), 2017 and 2023
  • Figure 6.39 Rest-of-the-World Thermoelectric Materials Market (by Application), 2016-2023
  • Figure 6.40 Rest-of-the-World Thermoelectric Materials Market (by Country), Metric Tons, 2017 and 2023
  • Figure 6.41 Rest-of-the-World Thermoelectric Materials Market (by Country), $Thousand, 2017 and 2023
  • Figure 6.42 U.A.E. Thermoelectric Materials Market, 2016-2023
  • Figure 6.43 Brazil Thermoelectric Materials Market, 2016-2023
  • Figure 6.44 Others Thermoelectric Materials Market, 2016-2023
  • Figure 7.1 Share of Key Companies
  • Figure 7.2 EVERREDtronics Ltd.: SWOT Analysis
  • Figure 7.3 Ferrotec (USA) Corporation.: SWOT Analysis
  • Figure 7.4 Hitachi Ltd.: Overall Financials, 2015-2017
  • Figure 7.5 Hitachi Ltd.: Net Revenue by Business Segment, 2015-2017
  • Figure 7.6 Hitachi Ltd.: Net Revenue by Geographical Area, 2015-2017
  • Figure 7.7 Hitachi Ltd.: SWOT Analysis
  • Figure 7.8 Jingyi Metal Material (Shanghai) Co., Ltd.: SWOT Analysis
  • Figure 7.9 KELK Ltd.: SWOT Analysis
  • Figure 7.10 Marlow Industries, Inc.: SWOT Analysis
  • Figure 7.11 Norilsk Nickel: Overall Financials, 2015-2017
  • Figure 7.12 Norilsk Nickel: Net Revenue by Business Segment, 2015-2017
  • Figure 7.13 Norilsk Nickel: Net Revenue by Geographical Area, 2015-2017
  • Figure 7.14 Norilsk Nickel: SWOT Analysis
  • Figure 7.15 P&N Technology (Xiamen) Co., Ltd.: SWOT Analysis
  • Figure 7.16 Panasonic Corporation: Overall Financials, 2015-2017
  • Figure 7.17 Panasonic Corporation: Net Revenue by Business Segment, 2015-2017
  • Figure 7.18 Panasonic Corporation: Net Revenue by Geographical Area, 2015-2017
  • Figure 7.19 Panasonic Corporation: SWOT Analysis
  • Figure 7.20 Reade International Corp., SWOT Analysis
  • Figure 7.21 Sigma Aldrich Corporation: SWOT Analysis
  • Figure 7.22 TECTEG MFR.: SWOT Analysis
  • Figure 7.23 TEGma AS: SWOT Analysis
  • Figure 7.24 Thermonamic Electronics(Jiangxi) Corp., Ltd.: SWOT Analysis
  • Figure 7.25 TOSHIBA MATERIALS CO., LTD.: SWOT Analysis
  • Figure 8.1 Global Thermoelectric Materials Market Scope
  • Figure 8.2 Report Design
  • Figure 8.3 Primary Interviews Breakdown (by Player, Designation, and Region)
  • Figure 8.4 Sources of Secondary Research
  • Figure 8.5 Data Triangulation
  • Figure 8.6 Top-down and Bottom-up Approach

Global Thermoelectric Materials Market is Anticipated to Reach $78,875.7 thousand by 2023, BIS Research Report

Thermoelectric materials have been a topic of massive research and development since a long time, as they follow the principle of converting waste heat into usable electricity. Usage of this niche technology in various end-user industries such as automobiles, industrial, and healthcare might result in proper utilization of energy, which would eventually result in decreasing the demand for energy resources. Various environment regulations lead factories to cut down on their production limits due to excessive greenhouse gas emissions. Thermoelectric materials contribute in the reduction of greenhouse gas emissions which has become a major area of focus in the global scenario. Although at an emerging state, thermoelectric materials have been used in several pilot projects to test their feasibility and efficiency. Many companies such as Panasonic Corporation and Hitachi Ltd., among others are actively engaged in the research and development of thermoelectric materials given their high potential.

Bismuth telluride, lead telluride, and silicon germanium are some of the thermoelectric materials widely used in the end-user industries. Bismuth telluride is the traditionally used thermoelectric material owing to its features. It is an alloy made of bismuth and telluride. It could be found in various forms such as in pieces, powder, lump, ingots, and chunks, among others. It can be used as a thermoelectric material and utilized in power generation device or cooling modules such as refrigerator. It also finds its application in topological insulators.

The global thermoelectric materials market is expected to grow at a CAGR of 8.49% and 9.09% between 2018 and 2023 in terms of value and volume, respectively.

The report is a compilation of different segments of the global thermoelectric materials market, including market breakdown by type, application, and geographical areas. Herein the revenue generated from the types (bismuth telluride, lead telluride, and silicon germanium), application (healthcare, automotive, industrial, electrical and electronics, and others), and geographies (North America, Europe, Asia-Pacific, and Rest-of-the-World) are tracked to calculate the overall market size both in terms of value ($thousand) and volume (metric tons). While highlighting the key driving and restraining forces for this market, the report also provides a detailed summary of the global thermoelectric materials market. It also includes the key participants involved in the industry at the relevant sections.

Key questions answered in the report:

  • What was the size, in terms of value ($thousand) and volume (metric tons), of the thermoelectric materials market in 2017, and what will be the growth rate during the forecast period 2018-2023?
  • What will be the market size of different types of thermoelectric materials (by value and volume) and their growth rate during the forecast period 2018-2023?
  • What will be the market size of different types of applications in the thermoelectric materials market (by value and volume) and their growth rate during the forecast period 2018-2023?
  • What will be the market size for different regions and countries in terms of value and volume in the thermoelectric materials market and their growth rate in the forecast period 2018-2023?
  • What are the major driving forces that tend to increase the demand for thermoelectric materials in various end-user industries during the forecast period?
  • What are the major challenges inhibiting the growth of the global thermoelectric materials market?
  • What is the competitive strength of key players in the global thermoelectric materials market by analyzing through market share analysis?
  • Who are the key players (along with their detailed analysis and profiles including their financials, company snapshots, key products and services, and SWOT analysis) in the market?

The report further includes a thorough analysis of the impact of the Porter's Five Forces to understand the overall attractiveness of the industry. The most commonly used strategy for developing a better hold on the market has been through business expansions. Moreover, the company profile section highlights significant information about the key companies involved along with their financial positions, key strategies, and developmental activities in recent years.

Further, the report includes an exhaustive analysis of the geographical split into North America, Europe, Asia-Pacific (APAC), and Rest-of-the-World. Each geography details the individual driving and restraining forces in addition to the key players from that region. This report is a meticulous compilation of research on more than 100 players in the global thermoelectric materials market and draws upon the insights from in-depth interviews with the key opinion leaders of more than 50 leading companies, market participants, and vendors. The report also profiles approximately 15 companies with their financial analysis, SWOT, and product portfolio.

The company profiles in the report include Hitachi Ltd., Panasonic Corporation, Norilsk Nickel, EVERREDtronics Ltd., Ferrotec (USA) Corporation., Jingyi Metal Material (Shanghai) Co., Ltd., KELK Ltd., Marlow Industries, Inc., P&N Technology (Xiamen) Co., Ltd., Reade International Corp., Sigma Aldrich Corporation, TECTEG MFR., TEGma AS, Thermonamic Electronics(Jiangxi) Corp., Ltd., and TOSHIBA MATERIALS CO., LTD.

Executive Summary

The increase in the global population coupled with the boost in the economic growth owing to the modernization has led to an increase in the energy consumption worldwide. The major source of the energy comes from conventional resources which not only raises sustainability concerns but also results in adverse environment impact such as climate instability and increase in the carbon dioxide levels. As per the "Global Energy & CO2 Status Report 2017" report by International Energy Agency (IEA), the source of 72% of the energy came from fossil fuels and a growth of 1.4% was witnessed in the emission of energy-related carbon dioxide in 2017. These facts emphasize on the extent of the issue that needs to be addressed with the help of proper energy harvesting.

The upsurge in the energy consumption also impacts the cost of the conventional resources. Therefore, proper utilization of resource is a major topic of research in ongoing days of economic expansion within the countries.

A large chunk of heat is wasted in the process of conversion energy into usable electricity or in any other form. Thermoelectric technology comes up with a solution to minimize this wastage of heat. Thermoelectric materials have the potential to reduce energy consumption by converting waste heat produced during the process of energy utilization into usable form of electricity. It is anticipated that thermoelectric materials market would have enormous opportunity to grow owing to the initiation of several advancements in the end-user industries where the materials are widely used.

Thermoelectric materials have been a topic of massive research and development since a long time as they follow the principle of converting waste heat into usable electricity. Usage of this niche technology in various end-user industries such as automobiles, industrial, and healthcare might result in proper utilization of energy which would eventually result in decreasing the demand for energy resources.

Bismuth telluride, lead telluride, and silicon germanium are some of the thermoelectric materials widely used in the end-user industries. Bismuth Telluride is the traditionally-used thermoelectric material owing to its features. It is an alloy made of bismuth and telluride. It could be found in various forms such as in pieces, powder, lump, ingots, and chunks, among others. It can be used as a thermoelectric material and utilized in power generation device or cooling modules such as refrigerator. It also finds its application in topological insulators.

In terms of value, the global thermoelectric materials market is expected to grow at a CAGR of 8.49% during the forecast period 2018-2023. The factors driving the demand of thermoelectric materials in the global market are improved vehicle fuel efficiency using thermoelectric modules, increasing awareness of green energy, rising awareness by government officials, and rapid commercialization of thermoelectric generators in the automobile industry. The automobile industry is amidst a revolution where the industry is accelerating its pace toward becoming more sustainable and greener. Proper utilization of waste heat in the automobile industry is another concern that has been gaining traction since a long time. As per the American Society of Mechanical Engineers (ASME), the heat energy lost due to the internal fuel combustion in the automobiles is almost 65%. Thermoelectric generators with the help of thermoelectric materials can convert waste heat into electricity. Many automobile industries have been actively participating by including technologies that would reduce heat wastage.

Ford, for example, is incorporating bismuth telluride as a thermoelectric material for its thermoelectric generator to minimize its fuel energy wastage. Volvo Group have started the RENOTER project for a duration of 3 years with 8 partners, whereby targets are set for permissible heat wastage for different types of vehicles.

In terms of value, in 2017, bismuth telluride accounted for the largest share of 67.36% in the global thermoelectric materials market. The high use of bismuth telluride in thermoelectric devices and modules for waste heat recovery, refrigeration, electronics cooling, thermal comfort, and others is expected to propel the demand of bismuth telluride in the thermoelectric materials market.

Since the demand for energy consumption is accelerating with the depleting fuel resources, thermoelectric material and their usage has become a topic of interest among several institutes and governments. Universities, such as The University of Queensland, have been actively engaging in enhancing the performance of bismuth telluride at several temperatures to use it in various devices and make it as energy efficient as possible.

The industrial segment dominated the global thermoelectric materials market in terms of value with a market share of 41.56% in 2017. Owing to the ability of thermoelectric materials to harness the waste heat from various power plants and effectively convert them into electricity, the demand of thermoelectric materials such as bismuth telluride is expected to grow during the forecast period.

Asia-Pacific region occupied the highest share of 44.98% in 2017 which is further expected to increase to 45.60% by 2023. China is the highest revenue generating country in Asia-Pacific, and it is also expected to show the fastest growth during the forecast period. The country has many manufacturers of thermoelectric materials and devices and has been promoting the use of TEGs. The growth of these TEGs has further enhanced the consumption of thermoelectric materials in the country. Additionally, several ongoing research activities in various institutes in the country are expected to propel the demand of thermoelectric materials market in the country. The automotive segment in the China thermoelectric materials market is expected to be the fastest growing application during the forecast period. There are research and development activities ongoing to use thermoelectric materials for automotive applications such as cooling and heating seats and harnessing the waste heat to generate electricity for various electrical activities in the country.

Table of Contents

Executive Summary

1 Market Dynamics

  • 1.1 Drivers
    • 1.1.1 Improved Vehicle Fuel Efficiency Using Thermoelectric Modules
    • 1.1.2 Increasing Awareness of Green Energy and Rising Awareness by Various Government Officials
    • 1.1.3 Rapid Commercialization of Thermoelectric Generators in the Automobile Industry
  • 1.2 Restraints
    • 1.2.1 High Production Cost of Thermoelectric Material
    • 1.2.2 Inability to Produce High Power Electricity Output
  • 1.3 Opportunities
    • 1.3.1 Rise in the Demand for Thermoelectric Materials in Medical Devices

2 Competitive Insights

  • 2.1 Key Market Developments and Strategies
    • 2.1.1 Product Launches
    • 2.1.2 Others
  • 2.2 Market Share Analysis

3 Industry Analysis

  • 3.1 Supply Chain Analysis
  • 3.2 Industry Attractiveness
    • 3.2.1 Threat of New Entrants
    • 3.2.2 Bargaining Power of Buyers
    • 3.2.3 Bargaining Power of Suppliers
    • 3.2.4 Threat from Substitutes
    • 3.2.5 Intensity of Competitive Rivalry
  • 3.3 Opportunity Matrix Analysis
  • 3.4 Country Share Analysis
  • 3.5 Thermoelectric Phenomenon
    • 3.5.1 Seebeck Effect
    • 3.5.2 Peltier Effect
    • 3.5.3 Thomson Effect
  • 3.6 Thermoelectric Materials in the Research Phase
    • 3.6.1 Chalcogenides Materials
    • 3.6.2 Half Heusler Alloys
    • 3.6.3 Skutterudites
    • 3.6.4 Clathrates
    • 3.6.5 Antimony Telluride (Sb2Te3)

4 Global Thermoelectric Material Market (by Type), $Thousand and Metric Tons, 2016-2023

  • 4.1 Assumptions
  • 4.2 Limitations
  • 4.3 Market Overview
  • 4.4 Bismuth Telluride (Bi2Te3)
  • 4.5 Lead Telluride (PbTe)
  • 4.6 Silicon Germanium (SiGe)

5 Global Thermoelectric Materials Market (by Application), $Thousand and Metric Tons, 2016-2023

  • 5.1 Industrial
  • 5.2 Automotive
  • 5.3 Electrical & Electronics
  • 5.4 Healthcare
  • 5.5 Others

6 Thermoelectric Material Market (by Region), $Thousand and Metric Tons, 2016-2023

  • 6.1 Asia-Pacific
    • 6.1.1 Asia-Pacific Thermoelectric Materials Market (by Type)
    • 6.1.2 Asia-Pacific Thermoelectric Materials Market (by Application)
    • 6.1.3 Asia-Pacific Thermoelectric Materials Market (by Country)
      • 6.1.3.1 China

6.1.3.1.1 China Thermoelectric Materials Market (by Application)

      • 6.1.3.2 Japan

6.1.3.2.1 Japan Thermoelectric Materials Market (by Application)

      • 6.1.3.3 South Korea

6.1.3.3.1 South Korea Thermoelectric Materials Market (by Application)

      • 6.1.3.4 Rest-of-Asia-Pacific

6.1.3.4.1 Rest-of-Asia-Pacific Thermoelectric Materials Market (by Application)

  • 6.2 North America
    • 6.2.1 North America Thermoelectric Materials Market (by Type)
    • 6.2.2 North America Thermoelectric Materials Market (by Application)
    • 6.2.3 North America Thermoelectric Materials Market (by Country)
      • 6.2.3.1 The U.S.

6.2.3.1.1 U.S. Thermoelectric Materials Market (by Application)

      • 6.2.3.2 Canada

6.2.3.2.1 Canada Thermoelectric Materials Market (by Application)

      • 6.2.3.3 Mexico

6.2.3.3.1 Mexico Thermoelectric Materials Market (by Application)

  • 6.3 Europe
    • 6.3.1 Europe Thermoelectric Materials Market (by Type)
    • 6.3.2 Europe Thermoelectric Materials Market (by Application)
    • 6.3.3 Europe Thermoelectric Materials Market (by Country)
      • 6.3.3.1 Germany

6.3.3.1.1 Germany Thermoelectric Materials Market (by Application)

      • 6.3.3.2 France

6.3.3.2.1 France Thermoelectric Materials Market (by Application)

      • 6.3.3.3 The U.K.

6.3.3.3.1 U.K. Thermoelectric Materials Market (by Application)

      • 6.3.3.4 Russia

6.3.3.4.1 Russia Thermoelectric Materials Market (by Application)

      • 6.3.3.5 Rest-of-Europe

6.3.3.5.1 Rest-of-Europe Thermoelectric Materials Market (by Application)

  • 6.4 Rest-of-the-World
    • 6.4.1 Rest-of-the-World Thermoelectric Materials Market (by Type)
    • 6.4.2 Rest-of-the-World Thermoelectric Materials Market (by Application)
    • 6.4.3 Rest-of-the-World Thermoelectric Materials Market (by Country)
      • 6.4.3.1 The U.A.E.

6.4.3.1.1 U.A.E. Thermoelectric Materials Market (by Application)

      • 6.4.3.2 Brazil

6.4.3.2.1 Brazil Thermoelectric Materials Market (by Application)

      • 6.4.3.3 Others

6.4.3.3.1 Others Thermoelectric Materials Market (by Application)

7 Company Profile

  • 7.1 Overview
  • 7.2 EVERREDtronics Ltd.
    • 7.2.1 Company Overview
    • 7.2.2 Product Portfolio Pertaining to Thermoelectric Materials Market
    • 7.2.3 Corporate Summary
    • 7.2.4 SWOT Analysis
  • 7.3 Ferrotec (USA) Corporation.
    • 7.3.1 Company Overview
    • 7.3.2 Product Portfolio Pertaining to Thermoelectric Materials Market
    • 7.3.3 Corporate Summary
    • 7.3.4 SWOT Analysis
  • 7.4 Hitachi Ltd.
    • 7.4.1 Company Overview
    • 7.4.2 Product Portfolio Pertaining to Thermoelectric Materials Market
    • 7.4.3 Financials
      • 7.4.3.1 Financial Summary
    • 7.4.4 SWOT Analysis
  • 7.5 Jingyi Metal Material (Shanghai) Co., Ltd.
    • 7.5.1 Company Overview
    • 7.5.2 Product Portfolio Pertaining to Thermoelectric Materials Market
    • 7.5.3 Corporate Summary
    • 7.5.4 SWOT Analysis
  • 7.6 KELK Ltd.
    • 7.6.1 Company Overview
    • 7.6.2 Product Portfolio Pertaining to Thermoelectric Materials Market
    • 7.6.3 Corporate Summary
    • 7.6.4 SWOT Analysis
  • 7.7 Marlow Industries, Inc.
    • 7.7.1 Company Overview
    • 7.7.2 Product Portfolio Pertaining to Thermoelectric Materials Market
    • 7.7.3 Corporate Summary
    • 7.7.4 SWOT Analysis
  • 7.8 Norilsk Nickel
    • 7.8.1 Company Overview
    • 7.8.2 Product Portfolio Pertaining to Thermoelectric Materials Market
    • 7.8.3 Financials
      • 7.8.3.1 Financial Summary
    • 7.8.4 SWOT Analysis
  • 7.9 P&N Technology (Xiamen) Co., Ltd.
    • 7.9.1 Company Overview
    • 7.9.2 Product Portfolio Pertaining to Thermoelectric Materials Market
    • 7.9.3 Corporate Summary
    • 7.9.4 SWOT Analysis
  • 7.10 Panasonic Corporation
    • 7.10.1 Company Overview
    • 7.10.2 Product Portfolio Pertaining to Thermoelectric Materials Market
    • 7.10.3 Financials
      • 7.10.3.1 Financial Summary
    • 7.10.4 SWOT Analysis
  • 7.11 Reade International Corp.,
    • 7.11.1 Company Overview
    • 7.11.2 Product Portfolio Pertaining to Thermoelectric Materials Market
    • 7.11.3 Corporate Summary
    • 7.11.4 SWOT Analysis
  • 7.12 Sigma Aldrich Corporation
    • 7.12.1 Company Overview
    • 7.12.2 Product Portfolio Pertaining to Thermoelectric Materials Market
    • 7.12.3 Corporate Summary
    • 7.12.4 SWOT Analysis
  • 7.13 TECTEG MFR.
    • 7.13.1 Company Overview
    • 7.13.2 Product Portfolio Pertaining to Thermoelectric Materials Market
    • 7.13.3 Corporate Summary
    • 7.13.4 SWOT Analysis
  • 7.14 TEGma AS
    • 7.14.1 Company Overview
    • 7.14.2 Product Portfolio Pertaining to Thermoelectric Materials Market
    • 7.14.3 Corporate Summary
    • 7.14.4 SWOT Analysis
  • 7.15 Thermonamic Electronics(Jiangxi) Corp., Ltd.
    • 7.15.1 Company Overview
    • 7.15.2 Product Portfolio Pertaining to Thermoelectric Materials Market
    • 7.15.3 Corporate Summary
    • 7.15.4 SWOT Analysis
  • 7.16 TOSHIBA MATERIALS CO., LTD.
    • 7.16.1 Company Overview
    • 7.16.2 Product Portfolio Pertaining to Thermoelectric Materials Market
    • 7.16.3 Corporate Summary
    • 7.16.4 SWOT Analysis

8 Report Scope & Methodology

  • 8.1 Report Scope
  • 8.2 Global Thermoelectric Materials Market Research Methodology
    • 8.2.1 Assumptions
    • 8.2.2 Limitations
    • 8.2.3 Primary Data Sources
    • 8.2.4 Secondary Data Sources
    • 8.2.5 Data Triangulation
    • 8.2.6 Market Estimation and Forecast
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