固体酸化物燃料電池（SOFC）市場は2033年までに68億米ドル規模に達する見込み

固体酸化物燃料電池 2023-2033年: 技術、用途、市場予測

6つの主要アプリケーション分野の１0年間のSOFC市場予測、用途分野分析、プレイヤーのベンチマーク、さらにSOFCの既存および最新技術動向の市場調査レポート。

By Dr Conor O'Brien and Dr Alex Holland

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製品情報概要目次価格

このレポートは固体酸化物燃料電池の市場、技術、有力企業を徹底検証しています。対象は6つの主要用途分野、2016-2022年市場実績データと2023年から2033年の市場予測が盛り込まれています。これによるとSOFCが成長段階に入り、2033年に68億米ドルの市場価値に達する見込みであり、今後10年間で25.1％のCAGRを実現すると見ています。

「固体酸化物燃料電池 2023-2033年」が対象とする主なコンテンツ

（詳細は目次のページでご確認ください）

● 全体概要と結論

● 固体酸化物燃料電池（SOFC）の主要技術と材料

□ 正極、負極、電解質、インターコネクトの材料トレンド分析

□ SOFC技術の最新研究開発概要

● 市場に影響を及ぼす規制と環境配慮事項

● SOFC燃料選択肢（メタン、天然ガス、メタノール、バイオ燃料、水素、アンモニア、合成燃料等）の分析

● 定置型SOFCの成長機会のある市場分野（商用、公益事業、住宅用、オフグリッド等）解説

● 移動用途SOFC（船舶、補助電源装置、無人航空機等）での市場分析

● 固体酸化物電解セル（SOEC）概要

● 主要有力企業インタビューを含む企業概要

● SOFC市場規模、市場概観、市場予測

「固体酸化物燃料電池 2023-2033年」は以下の情報を提供します

本レポートでは、固体酸化物燃料電池（SOFC）の技術・材料に関する重要な市場情報、6つの主要アプリケーション分野の概要、SOFC市場の主要企業の評価などを掲載しています。

固体酸化物燃料電池の技術と材料の概要:

競合する燃料電池技術とのベンチマーク比較

固体酸化物燃料電池の最重要用途分野の詳細解説:

高出力定置型電力を供給するSOFCの成長機会がある市場分野（商用、産業用、公益事業等）の広範にわたる解説
熱電併給（CHP）システム（住宅用、オフグリッド等）に焦点を置いた低出力定置型電力のSOFCの市場分析

SOFC市場の有力企業検証

主要企業の売上高（提供サービス別内訳を含む）、損益、従業員数、インストールベース、IP活動分析を含む歴史的評価
パートナーシップ、ライセンス契約、In-house R&D を通じて市場に参入する小規模企業から大規模な多国籍企業までをカバー

固体酸化物燃料電池の市場予測

6つの主要用途別メガワット需要（MW）の10年間詳細予測
実績データ、企業インタビューと提示目標に基づく固体酸化物燃料電池の価格動向
6つの主要用途別SOFC市場価値（米ドル単位）の10年間詳細予測

Solid Oxide Fuel Cell (SOFC) Market to Reach US$6.8 billion by 2033

With the drive towards zero-emission power generation, fuel cells are continuing to generate noticeable interest, especially as part of the much hyped 'hydrogen economy'. The fuel flexibility of solid oxide fuel cells (SOFC) is of particular interest - capable of running on zero/low carbon emission fuels such as hydrogen, ammonia, and e-fuels, as well as light hydrocarbons. With applications ranging from utility-scale power generation to small off-grid residential units, will solid oxide fuel cells be the zero-emission power generation solution of tomorrow?

IDTechEx covers the energy and decarbonization sector comprehensively, detailing carbon capture technology, both electric and fuel cell vehicles, and hydrogen production. They have released a report, Solid Oxide Fuel Cells 2023-2033: Technology, Applications, Players and Forecasts, which includes granular 10-year forecasts segmented by application area for both megawatt demand and market valuation, while also detailing the price progression outlook for solid oxide fuel cells. It reveals that SOFCs are entering the growth phase, with market value set to grow to US$6.8 billion in 2033.

Historic annual installations (MW) for solid oxide fuel cells (2016-2022), and a breakdown of market share by application area for 2023.

A solid oxide fuel cell stack consists of hundreds of individual cells, featuring an electrolyte sandwiched between an anode and cathode, positioned between interconnects. A stack is integrated into a module in combination with the balance of plant. Due to high operating temperatures, one of the most critical issues to overcome for SOFCs is the matching of thermal expansion coefficient of neighboring components to limit stresses during operation. The typical material choice for the ceramic electrolyte is yttria-stabilized zirconia (YSZ) but ceria-based alternatives are emerging, enabling a reduction in operating temperature, and hence limiting degradation issues.

SOFCs are best suited to continuous, steady state operation due to extended ramp up times. The ability to operate on a fuel of natural gas allows the SOFC to be connected to gas grid for continuous supply of fuel. Continuous operation leads to a constant power output for SOFCs, which is particularly well suited for power generation for the grid, alongside commercial and industrial (C&I) applications. Combined heat and power (CHP) can be supplied to industrial/commercial spaces, while power alone is useful for applications such as data centres, critical operations (health care etc), and utility scale electricity generation. Each of the major application areas is covered in this IDTechEx report, detailing the suitability for SOFCs and comparison with competing solutions.

The landscape of players in the SOFC market is set to change dramatically over the coming decade. Bloom Energy are established as the current dominant player, with an installation base approaching 1 GW. However, competitors are emerging with both small companies and large multinationals entering the market through partnerships, licensing agreements or in-house R&D. IDTechEx provides an independent assessment of these emerging players including technology differentiators (including fuel flexibility) and targeted applications within the market.

This report provides critical solid oxide fuel cell (SOFC) market intelligence for technology and materials, an overview of six major application areas and includes an assessment of the key players in the SOFC market.

An overview of solid oxide fuel cell technologies and materials:

Assessment of material trends for anode, cathode, electrolyte, and interconnect components.
Overview of latest research and development for SOFC technology.
Benchmarking with competing fuel cell technologies.
Analysis and benchmarking of fuel choices for SOFC (methane, natural gas, methanol, biofuel, hydrogen, ammonia, e-fuel, etc).

A detailed account of the most critical application areas for solid oxide fuel cells:

Extensive description of market sectors with growth opportunity for SOFC providing high-power stationary power (commercial, industrial, utilities, etc).
Assessment of market sectors for SOFC providing low-power stationary power with a focus on combined heat and power (CHP) (residential, off-grid, etc).
Overview of market sectors utilising SOFC for mobile applications (marine, auxiliary power units, unmanned aerial vehicles, etc).

An evaluation of players in the SOFC market:

Historical assessment of major players including analysis of revenue (including split by service provided), profit/loss, employee numbers, installation base and IP activity.
Coverage of emerging players - both small companies and large multinationals entering the market through partnerships, licensing agreements or in-house R&D.

Solid oxide fuel cell market forecasts:

Granular 10-year SOFC market forecasts for megawatt demand (MW) segmented by six major application areas.
Outlook for price progression of solid oxide fuel cells based on historic data, company interviews and stated targets.
Granular 10-year forecast for SOFC market valuation ($USD) segmented by six major application areas.

For more details on the market forecasts, technology trends, key application areas and major players for the solid oxide fuel cell market, see the IDTechEx market report "Solid Oxide Fuel Cells 2023-2033: Technology, Applications, Players and Forecasts. For more information on IDTechEx's other reports and market intelligence offerings, please visit www.IDTechEx.com/Research.

Report Metrics	Details
Historic Data	2016 - 2022
CAGR	The global market for solid oxide fuel cells is projected to reach US$6.8 billion in 2033, representing a CAGR of 25.1% when compared to the market in 2023.
Forecast Period	2023 - 2033
Forecast Units	Demand (MW), Value (USD$)

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Table of Contents

1.	EXECUTIVE SUMMARY AND CONCLUSIONS
1.1.	Introduction to fuel cells
1.2.	SOFC working principle
1.3.	SOFC assembly and materials
1.4.	Overview of key players
1.5.	Why now?
1.6.	Desire for emission-free fuels
1.7.	Fuel choices for SOFCs
1.8.	Normalized benchmarking of SOFC fuels
1.9.	Commercial use of fuels in SOFCs
1.10.	LCOE from solid oxide fuel cells
1.11.	Main applications for SOFCs
1.12.	SOFCs for C&I Applications
1.13.	SOFCs for Utilities
1.14.	SOFCs for Data & Telecommunications
1.15.	SOFCs for Residential Applications
1.16.	Latest research for SOFCs
1.17.	SOFCs for marine applications
1.18.	Solid Oxide Electrolyzer (SOEC) overview
1.19.	SOFC demand (MW) by application 2020-2033
1.20.	Price progression ($/kW) for SOFCs
1.21.	SOFC market value outlook by application 2023-2033
1.22.	Market share (MW) by application
2.	MARKET FORECASTS
2.1.	Long-term forecasting of technologies
2.2.	Forecast methodology
2.3.	Forecast assumptions
2.4.	SOFC demand (MW) 2016-2033
2.5.	SOFC demand (MW) by application 2020-2033
2.6.	Price progression ($/kW) for SOFCs
2.7.	SOFC market value outlook 2023-2033
2.8.	SOFC market value outlook by application 2023-2033
3.	INTRODUCTION
3.1.1.	Introduction to fuel cells
3.1.2.	What is a fuel cell?
3.1.3.	SOFC working principle
3.1.4.	Alternative fuel cell technologies: PEMFC
3.1.5.	Alternative fuel cell technologies
3.1.6.	Comparison of fuel cell technologies
3.1.7.	SOFC assembly and materials
3.1.8.	Electrolyte
3.1.9.	Anode
3.1.10.	Cathode
3.1.11.	Interconnect for planar SOFCs
3.1.12.	Tubular SOFC
3.1.13.	Polarization losses
3.1.14.	SOFC variations
3.1.15.	Combined heat & power (CHP)
3.1.16.	Government targets
3.1.17.	EU 'Fit for 55'
3.1.18.	Overview of players in the SOFC market - USA
3.1.19.	Overview of players in the SOFC market - Europe
3.1.20.	Overview of players in the SOFC market - China
3.1.21.	Overview of players in the SOFC market - APAC
3.2.	Latest SOFC Research & Developments
3.2.1.	AVL enable development of SOFC systems
3.2.2.	Low temperature SOFCs
3.2.3.	Kyocera's cylinder-plate fuel electrode supports
3.2.4.	Automated operation learning system
3.2.5.	3D printing for SOFCs
3.2.6.	Power generation from unused biomass resources
3.2.7.	AMON Project
4.	FUELS FOR SOFCS
4.1.	Desire for emission-free fuels
4.2.	Low carbon fuels for fuel cells
4.3.	Classification of fuels by carbon emissions
4.4.	Natural gas for SOFCs
4.5.	Liquified natural gas (LNG)
4.6.	Hydrogen economy
4.7.	Colours of hydrogen
4.8.	Hydrogen for SOFCs
4.9.	Ammonia for SOFCs
4.10.	Ammonia production - Haber Bosch
4.11.	Ammonia production - Nitrogen electrolyser
4.12.	Overview of e-fuels
4.13.	Benchmarking volumetric energy density of SOFC fuels
4.14.	Benchmarking carbon emissions of SOFC fuels
4.15.	Normalized benchmarking of SOFC fuels
4.16.	Commercial use of fuels in SOFCs
5.	COMMERCIAL & INDUSTRIAL APPLICATIONS FOR SOFCS
5.1.	SOFC for C&I applications
5.2.	Worldwide energy demand growth
5.3.	Data centres
5.4.	Utilities - LCOE
5.5.	LCOE from solid oxide fuel cells
5.6.	Utilities case study: South Korea
5.7.	Commercial case study: Walmart
5.8.	Data case study: AT&T
5.9.	Utilities case study 2: Mitsubishi Power
5.10.	Integrated gasification fuel cell
5.11.	Integrated gasification fuel cell (2)
6.	MAIN PLAYERS FOR C&I APPLICATIONS
6.1.	Bloom Energy
6.1.1.	Bloom Energy - Overview
6.1.2.	Bloom Energy - Technology
6.1.3.	Bloom Energy - Installation Base
6.1.4.	Bloom Energy - Financials
6.1.5.	Bloom Energy - Financials Analysis
6.1.6.	Bloom Energy - Example customers
6.1.7.	Bloom Energy - Example customers (2)
6.1.8.	Bloom-SK Fuel Cell
6.1.9.	Bloom Energy - SWOT
6.2.	Ceres Power & Partners
6.2.1.	Ceres Power - Overview
6.2.2.	Ceres Power - Technology
6.2.3.	Ceres Power - Financials
6.2.4.	Ceres Power - SWOT
6.2.5.	Ceres Power & Partners
6.2.6.	Ceres Power & Bosch/Weichai
6.2.7.	Ceres Power & Miura
6.2.8.	Ceres Power & Doosan
6.2.9.	Ceres Power & BOSAL
6.3.	Other Notable Players
6.3.1.	Cummins - Overview
6.3.2.	Cummins - Applications
6.3.3.	Cummins - SWOT
6.3.4.	Mitsubishi Power - Overview
6.3.5.	Mitsubishi Power - Technology
6.3.6.	Mitsubishi Power - SWOT
6.3.7.	FuelCell Energy - Overview
6.3.8.	FuelCell Energy - IGFC
6.3.9.	FuelCell Energy - SWOT
7.	RESIDENTIAL APPLICATIONS FOR SOFCS
7.1.1.	SOFC for residential applications
7.1.2.	Incorporation with solar power
7.1.3.	Modularity of systems
7.1.4.	Feed-in tariffs (FiT)
7.1.5.	Comparison with residential batteries
7.1.6.	Outlook for residential SOFCs
7.2.	Players offering residential and off-grid SOFCs
7.2.1.	OxEon Energy
7.2.2.	Upstart Power
7.2.3.	Aris Renewable Energy
7.2.4.	Edge autonomy
7.2.5.	Osaka Gas
7.2.6.	Sunfire fuel cells
7.2.7.	Comparison of residential SOFCs
8.	MARINE APPLICATIONS FOR SOFCS
8.1.	Introduction to SOFCs for marine applications
8.2.	Overview of policy drivers
8.3.	The International Maritime Organization (IMO)
8.4.	Emission control areas
8.5.	Sulphur and nitrous oxide emissions
8.6.	Traditional solutions: Scrubbers & speed reduction
8.7.	Shifting emission policy focus
8.8.	Marine CO2 emissions and targets
8.9.	Reducing greenhouse gases: EEXI & CII
8.10.	EU-specific policy
8.11.	SOFC for marine
8.12.	Fuel cell supplier market share 2019-2024
8.13.	Fuel cell deliveries by vessel type 2019-2024
8.14.	Average power of FC deliveries 2019-2024
8.15.	Solid oxide fuel cell players
8.16.	Alma Clean Power
8.17.	Bloom Energy
8.18.	Ceres / Doosan
8.19.	SOFC Barriers & future commentary
8.20.	Comparison of commercial marine fuel cells
9.	SOFC POWERED VEHICLES
9.1.	Volkswagen
9.2.	Nissan
9.3.	Unmanned vehicles
9.4.	Auxiliary power units
9.5.	Outlook for SOFC powered vehicles
10.	SOLID OXIDE ELECTROLYSIS
10.1.	Electrolyzer systems overview
10.2.	Electrolyzer systems comparison - Operating parameters
10.3.	Pros and cons of electrolyzer technologies
10.4.	SOEL Overview
10.5.	SOEL Systems: A substitute for AWE?
10.6.	Solid Oxide Electrolyzer: Introduction
10.7.	Solid Oxide Electrolyzer efficiency
10.8.	Reversible SOFC
10.9.	SOEL Electrolyzers systems: Materials, specifics
10.10.	SOEL Market
10.11.	SOEL Supply chain
10.12.	New high-temperature electrolysis technology
11.	COMPANY PROFILES
11.1.	Alma Clean Power
11.2.	AVL
11.3.	Bloom Energy
11.4.	Ceres Power
11.5.	Cummins
11.6.	FuelCell Energy
11.7.	OxEon Energy
11.8.	SolydEra (SOLIDpower)
11.9.	Edge Autonomy
11.10.	Elcogen
11.11.	HyAxiom
11.12.	Osaka Gas
11.13.	Redox Power Systems
11.14.	Sunfire
11.15.	Upstart Power