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1876665

先進儲氫材料市場預測至2032年：按材料類型、儲存機制、實體儲存方法、應用、最終用戶和地區分類的全球分析

Advanced Materials for Hydrogen Storage Market Forecasts to 2032 - Global Analysis By Material Type, Storage Mechanism, Physical Storage Method, Application, End User and By Geography

出版日期: 2025年11月01日 | 出版商:

Stratistics Market Research Consulting | 英文 200+ Pages | 商品交期: 2-3個工作天內

價格

簡介目錄圖表

根據 Stratistics MRC 的研究，預計 2025 年全球儲氫先進材料市場價值為 5.345 億美元，到 2032 年將達到 13.9602 億美元，預測期內複合年成長率為 14.7%。

專為儲氫而設計的先進材料是清潔能源技術發展的關鍵要素，它們能夠提供更安全、更有效率且儲氫容量更高的儲氫方案。金屬氫化物、多孔碳和金屬有機框架（MOFs）等創新解決方案在可控條件下展現出優異的吸氫和脫氫性能。這些材料克服了傳統高壓或低溫儲氫技術的局限性，並支援永續能源的部署。目前的研究重點在於提高儲氫密度、可逆性和反應速率，以期實用化燃料電池、交通運輸和攜帶式電源等領域。

根據美國能源局氫能計畫的數據，氫化鎂（MgH2）的理論儲氫容量約為7.6 wt%，但實際可逆儲氫量接近5至6 wt%。同時，氫化鋁鈉（NaAlH4）在最佳條件下已被證實具有約5.6 wt%的可逆儲氫容量。

對清潔能源的需求日益成長

全球向永續低碳能源來源轉型正顯著推動先進儲氫材料市場的發展。氫氣作為一種零排放燃料，其潛力需要高效率的儲氫解決方案。與傳統的高壓儲氫方法相比，金屬氫化物和金屬有機框架（MOF）等材料提供了更安全、更緊湊的選擇。政府政策、產業舉措以及在交通運輸、發電和工業應用領域的日益普及，都在推動對這些技術的投資。人們對清潔能源解決方案的日益關注，促進了儲氫材料研發和創新，這對於支撐氫能經濟和推動整體市場擴張至關重要。

尖端材料的生產成本高昂

先進的儲氫材料，例如金屬有機框架（MOFs）、金屬氫化物和多孔碳，由於合成方法複雜且原料高成本，製造成本十分昂貴。這種高昂的製造成本限制了它們的大規模應用，尤其是在價格至關重要的市場。製造過程通常需要精確的環境條件、專用設備以及大量的能源消耗，增加了整體成本。因此，儘管這些材料具有高效性和優異的儲氫性能，但工業界可能仍然不願採用它們。克服成本障礙對於其廣泛的商業化至關重要，而探索經濟高效且可規模化生產方法是促進先進儲氫技術在全球普及的當務之急。

交通運輸領域的擴張

交通運輸業為先進儲氫材料的發展提供了巨大的機會。氫燃料電池汽車，包括轎車、巴士和卡車，需要高效、緊湊且安全的儲氫解決方案。金屬氫化物、金屬有機框架（MOF）和多孔碳等材料能夠提升儲氫容量、延長續航里程並增強車輛整體性能。全球範圍內旨在減少排放和獎勵清潔交通的政策正在推動這些材料的應用。對加氫網路的投資以及汽車製造商與材料供應商之間的合作進一步促進了市場擴張。總而言之，交通運輸業在推動儲氫材料的商業化和全球部署方面具有巨大的潛力。

來自其他儲存技術的激烈競爭

先進儲氫材料市場正受到包括壓縮氫、液態氫和化學儲氫系統在內的多種競爭技術的威脅。儘管這些替代技術在效率和安全性方面存在挑戰，但由於其成本低廉且基礎設施完善，因此仍具有吸引力。日益激烈的競爭對金屬氫化物和金屬有機框架（MOF）等創新材料的應用帶來了挑戰。為了保持競爭力，企業必須加強研發、創新和商業化投入。如果缺乏差異化且經濟高效的解決方案，尖端材料製造商將面臨市場佔有率流失的風險。因此，來自替代技術的競爭對市場擴張、盈利以及先進儲氫解決方案的廣泛應用構成了重大威脅。

新冠疫情的影響：

新冠疫情對先進儲氫材料市場造成了顯著衝擊。供應鏈中斷、工廠停工以及研發延誤暫時抑制了市場成長。物流限制和工業活動減少導致交通運輸、能源和工業應用領域對儲氫解決方案的需求下降。基礎設施投資和技術研發步伐放緩，影響了商業化進程。儘管面臨這些挑戰，但隨著疫情後復甦策略強調清潔能源、永續性和氫能應用，市場展現了韌性。在長期永續性舉措、全球對可再生能源併網日益成長的興趣以及政府扶持政策的推動下，預計未來幾年市場將重拾成長勢頭，實現加速成長。

預計在預測期內，金屬氫化物細分市場將佔據最大的市場佔有率。

由於其卓越的儲氫容量、安全性和可靠性，金屬氫化物預計將在預測期內佔據最大的市場佔有率。其可逆的氫吸收和釋放能力使其成為交通運輸、攜帶式設備和固定式能源應用的理想選擇。廣泛的研究、易於操作以及與燃料電池的兼容性正在推動其廣泛應用。合金設計和奈米結構方面的持續改進正在提升儲氫性能和動力學。隨著各行業對高效、安全儲氫的需求不斷成長，金屬氫化物有望保持其作為最重要材料的地位，並繼續在先進儲氫市場中發揮主導作用。

預計在預測期內，汽車產業將實現最高的複合年成長率。

預計在預測期內，汽車產業將實現最高成長率，這主要得益於氫燃料電池汽車和燃料電池電動車（FCEV）的日益普及。嚴格的排放標準、政府補貼以及全球脫碳舉措正在推動交通運輸領域採用緊湊、高效且安全的儲氫技術。金屬氫化物、金屬有機框架（MOF）和奈米結構碳等材料能夠提高儲氫效率、安全性和車輛性能。此外，對加氫站的投資以及汽車製造商與材料製造商之間的合作也在推動這些技術的應用。因此，汽車產業是成長最快的產業，並為先進儲氫材料的應用提供了巨大的機會。

佔比最大的地區：

由於工業快速成長、政府主導的清潔能源政策以及氫能技術的日益普及，亞太地區預計將在整個預測期內保持最大的市場佔有率。日本、中國和韓國等主要國家正大力投資氫能基礎設施、燃料電池汽車和先進的儲氫解決方案。旨在減少碳排放的政策，以及對金屬氫化物、金屬有機框架（MOF）和奈米結構碳等材料的大量投資，正在鞏固該地區的市場領導地位。政府和產業界的合作正在推動技術創新和大規模應用。因此，亞太地區將繼續保持全球最大的市場佔有率，並成為氫能儲存技術發展的關鍵中心。

預計年複合成長率最高的地區：

在預測期內，由於對氫能基礎設施、燃料電池開發和清潔能源計畫的大量投資，北美預計將實現最高的複合年成長率。美國和加拿大都在積極推行碳減排策略，推動了對安全高效儲氫解決方案的需求。金屬氫化物、金屬有機框架（MOFs）和奈米結構碳等材料在運輸、能源和工業領域的應用日益廣泛。政府獎勵、產業夥伴關係以及氫動力汽車和固定式應用的擴展正在加速市場普及。該地區對創新和技術進步的重視，使其成為先進儲氫解決方案成長最快的市場。

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公司概況
- 對其他市場參與者（最多 3 家公司）進行全面分析
- 主要參與者（最多3家公司）的SWOT分析
區域細分
- 根據客戶要求，提供主要國家的市場估算、預測和複合年成長率（註：可行性需確認）。
競爭基準化分析
- 根據主要參與者的產品系列、地理覆蓋範圍和策略聯盟基準化分析

介紹
北美洲
- 美國
- 加拿大
- 墨西哥
歐洲
- 德國
- 英國
- 義大利
- 法國
- 西班牙
- 其他歐洲
亞太地區
- 日本
- 中國
- 印度
- 澳洲
- 紐西蘭
- 韓國
- 亞太其他地區
南美洲
- 阿根廷
- 巴西
- 智利
- 南美洲其他地區
中東和非洲
- 沙烏地阿拉伯
- 阿拉伯聯合大公國
- 卡達
- 南非
- 其他中東和非洲地區

第11章重大進展

協議、夥伴關係、合作和合資企業
收購與併購
新產品上市
業務拓展
其他關鍵策略

第12章企業概況

Linde plc
Air Liquide SA
Air Products and Chemicals, Inc.
Chart Industries, Inc.
Hexagon Purus AS
Nel ASA
McPhy Energy SA
Toshiba Energy Systems & Solutions Corporation
VRV SPA
Hbank Technologies Inc.
Hexagon Composites ASA
Otto Chemie Pvt. Ltd.
GKN Hydrogen GmbH
Toray Industries, Inc.
Hexcel Corporation

簡介目錄圖表

Product Code: SMRC32347

According to Stratistics MRC, the Global Advanced Materials for Hydrogen Storage Market is accounted for $534.50 million in 2025 and is expected to reach $1396.02 million by 2032 growing at a CAGR of 14.7% during the forecast period. Advanced materials designed for hydrogen storage represent a crucial component in advancing clean energy technologies, providing safer and more efficient storage options with high hydrogen capacity. Innovative solutions, such as metal hydrides, porous carbons, and metal-organic frameworks (MOFs), exhibit superior hydrogen uptake and release under controlled conditions. These materials overcome limitations of conventional high-pressure or cryogenic storage techniques, supporting sustainable energy deployment. Efforts concentrate on improving storage density, reversibility, and kinetics to make them viable for fuel cells, transport, and portable power applications.

According to the U.S. Department of Energy (DOE) Hydrogen Program, data shows that magnesium hydride (MgH2) has a theoretical hydrogen storage capacity of ~7.6 wt%, with practical reversible values closer to 5-6 wt%, while sodium alanate (NaAlH4) demonstrates ~5.6 wt% reversible hydrogen capacity under optimized conditions.

Market Dynamics:

Driver:

Growing demand for clean energy

The global shift toward sustainable and low-carbon energy sources significantly propels the market for advanced hydrogen storage materials. Hydrogen's potential as a zero-emission fuel demands efficient storage solutions, and materials such as metal hydrides and MOFs provide safer and more compact options than traditional high-pressure methods. Government policies, industrial initiatives, and increasing adoption in transportation, power generation, and industrial applications are driving investments in these technologies. The heightened focus on clean energy solutions encourages continuous research, development, and innovation in storage materials, making them essential for supporting a hydrogen-based energy economy and enhancing the market's overall expansion.

Restraint:

High production costs of advanced materials

Advanced hydrogen storage materials, such as MOFs, metal hydrides, and porous carbons, are expensive to produce due to intricate synthesis methods and high-cost raw materials. The elevated production cost limits their large-scale adoption, especially in markets where affordability is crucial. Manufacturing often demands precise environmental conditions, specialized equipment, and substantial energy consumption, increasing overall expenses. Consequently, industries may be reluctant to integrate these materials despite their efficiency and superior hydrogen storage properties. Overcoming cost-related barriers is essential for widespread commercialization, making research into affordable and scalable production methods a priority for enhancing the global adoption of advanced hydrogen storage technologies.

Opportunity:

Expansion in transportation sector

The transportation industry represents a major opportunity for the growth of advanced hydrogen storage materials. Vehicles powered by hydrogen fuel cells, including cars, buses, and trucks, require high-efficiency, compact, and safe storage solutions. Materials like metal hydrides, MOFs, and porous carbons improve storage capacity, vehicle range, and overall performance. Global policies to reduce emissions, combined with incentives for clean transportation, are driving adoption. Investment in hydrogen refueling networks and collaboration between automotive manufacturers and material suppliers further stimulate market expansion. Overall, the transportation sector offers substantial potential for advancing the commercialization and global deployment of hydrogen storage materials.

Threat:

Intense competition from alternative storage technologies

The market for advanced hydrogen storage materials is threatened by competing storage technologies, including compressed hydrogen, liquid hydrogen, and chemical storage systems. These alternatives may benefit from lower costs or existing infrastructure, making them appealing despite limitations in efficiency or safety. Intensifying competition challenges the adoption of innovative materials such as metal hydrides and MOFs. To remain competitive, companies must invest in R&D, innovation, and commercialization. Without differentiation or cost-effective solutions, advanced material manufacturers risk losing market share. Consequently, competition from alternative technologies represents a major threat to market expansion, profitability, and the widespread adoption of advanced hydrogen storage solutions.

Covid-19 Impact:

The COVID-19 pandemic significantly influenced the advanced hydrogen storage materials market. Supply chain interruptions, factory shutdowns, and delays in R&D hindered growth temporarily. Limitations on logistics and reduced industrial operations decreased demand for hydrogen storage solutions in transportation, energy, and industrial applications. Investment in infrastructure and technology development slowed, impacting commercialization timelines. Despite these challenges, the market demonstrated resilience as post-pandemic recovery strategies emphasized clean energy, sustainability, and hydrogen adoption. With increasing global focus on renewable energy integration and supportive government policies, the market is expected to regain momentum and achieve accelerated growth in the coming years, driven by long-term sustainability initiatives.

The metal hydrides segment is expected to be the largest during the forecast period

The metal hydrides segment is expected to account for the largest market share during the forecast period because of their superior hydrogen storage capacity, safety, and dependability. They allow reversible hydrogen uptake and release, making them ideal for transportation, portable devices, and stationary energy applications. Extensive research, handling convenience, and compatibility with fuel cells enhance their widespread adoption. Ongoing improvements in alloy design and nanostructuring increase storage performance and reaction speed. As the demand for efficient, safe hydrogen storage grows across industries, metal hydrides continue to dominate, maintaining their position as the most prominent material segment within the advanced hydrogen storage market.

The automotive segment is expected to have the highest CAGR during the forecast period

Over the forecast period, the automotive segment is predicted to witness the highest growth rate, fueled by the rising deployment of hydrogen-powered vehicles and fuel cell electric vehicles (FCEVs). Stringent emission standards, government subsidies, and global decarbonization initiatives are encouraging the use of compact, efficient, and safe hydrogen storage technologies in transportation. Materials like metal hydrides, MOFs, and nanostructured carbons improve storage efficiency, safety, and vehicle performance. Additionally, investments in hydrogen refueling stations and partnerships between automakers and material producers drive adoption. As a result, the automotive industry represents the fastest-growing segment, offering significant opportunities for advanced hydrogen storage material applications.

Region with largest share:

During the forecast period, the Asia Pacific region is expected to hold the largest market share due to rapid industrial growth, government-backed clean energy initiatives, and increasing adoption of hydrogen-based technologies. Leading nations including Japan, China, and South Korea are heavily investing in hydrogen infrastructure, fuel cell vehicles, and research on advanced storage solutions. Policies aimed at reducing carbon emissions, combined with significant funding in materials such as metal hydrides, MOFs, and nanostructured carbons, reinforce the region's market leadership. Collaborative efforts between governments and industries drive technological innovation and large-scale implementation. Consequently, Asia-Pacific continues to maintain the largest market share globally, serving as a key hub for hydrogen storage advancement.

Region with highest CAGR:

Over the forecast period, the North America region is anticipated to exhibit the highest CAGR due to substantial investments in hydrogen infrastructure, fuel cell development, and clean energy initiatives. Both the U.S. and Canada are actively pursuing carbon reduction strategies, driving demand for safe and efficient storage solutions. Materials like metal hydrides, MOFs, and nanostructured carbons are increasingly utilized in transportation, energy, and industrial sectors. Government incentives, industry partnerships, and the expansion of hydrogen-powered vehicles and stationary systems accelerate market adoption. The region's focus on innovation and technology advancement makes North America the most rapidly growing market for advanced hydrogen storage solutions.

Key players in the market

Some of the key players in Advanced Materials for Hydrogen Storage Market include Linde plc, Air Liquide SA, Air Products and Chemicals, Inc., Chart Industries, Inc., Hexagon Purus AS, Nel ASA, McPhy Energy SA, Toshiba Energy Systems & Solutions Corporation, VRV S.P.A, Hbank Technologies Inc., Hexagon Composites ASA, Otto Chemie Pvt. Ltd., GKN Hydrogen GmbH, Toray Industries, Inc. and Hexcel Corporation.

Key Developments:

In August 2025, Air Liquide announces that it has signed a binding agreement with Macquarie Asia-Pacific Infrastructure Fund 2, for the acquisition of DIG Airgas, a leading national player in South Korea. It is expected to close in the first semester of 2026. The proposed transaction values DIG Airgas at an enterprise value of 2.85 billion euros / 4.6 trillion South Korean won.

In July 2025, Linde announced a new long-term agreement with Blue Point Number One, which is a joint venture comprising CF Industries, JERA, and Mitsui & Co. Under this agreement, Linde will supply industrial gases to Blue Point's low-carbon ammonia plant, which will have a capacity of 1.4 million metric tons.

In July 2025, Chart Industries, Inc. announced that, prior to entering into the definitive agreement with Baker Hughes Company that was announced separately today, the Company and Flowserve Corporation terminated their previously announced merger agreement.

Material Types Covered:

Metal Hydrides
Chemical Hydrides
Carbon-based Materials
Nanostructured Materials
Metal-Organic Frameworks (MOFs)
Ammonia Borane
Other Material Types

Storage Mechanisms Covered:

Adsorption-Based Storage
Absorption-Based Storage
Chemical Reaction-Based Storage

Physical Storage Methods Covered:

Compressed Gas Storage
Liquid Hydrogen Storage

Applications Covered:

Fuel Cell Vehicles (FCVs)
Portable Power Systems
Stationary Power Systems
Industrial Hydrogen Storage
Aerospace & Defense Systems

End Users Covered:

Automotive
Energy & Power
Chemical Manufacturing
Aerospace
Marine
Other End Users

Regions Covered:

North America
- US
- Canada
- Mexico
Europe
- Germany
- UK
- Italy
- France
- Spain
- Rest of Europe
Asia Pacific
- Japan
- China
- India
- Australia
- New Zealand
- South Korea
- Rest of Asia Pacific
South America
- Argentina
- Brazil
- Chile
- Rest of South America
Middle East & Africa
- Saudi Arabia
- UAE
- Qatar
- South Africa
- Rest of Middle East & Africa

What our report offers:

Market share assessments for the regional and country-level segments
Strategic recommendations for the new entrants
Covers Market data for the years 2024, 2025, 2026, 2028, and 2032
Market Trends (Drivers, Constraints, Opportunities, Threats, Challenges, Investment Opportunities, and recommendations)
Strategic recommendations in key business segments based on the market estimations
Competitive landscaping mapping the key common trends
Company profiling with detailed strategies, financials, and recent developments
Supply chain trends mapping the latest technological advancements

Free Customization Offerings:

All the customers of this report will be entitled to receive one of the following free customization options:

Company Profiling
- Comprehensive profiling of additional market players (up to 3)
- SWOT Analysis of key players (up to 3)
Regional Segmentation
- Market estimations, Forecasts and CAGR of any prominent country as per the client's interest (Note: Depends on feasibility check)
Competitive Benchmarking
- Benchmarking of key players based on product portfolio, geographical presence, and strategic alliances

1 Executive Summary

2 Preface

2.1 Abstract
2.2 Stake Holders
2.3 Research Scope
2.4 Research Methodology
- 2.4.1 Data Mining
- 2.4.2 Data Analysis
- 2.4.3 Data Validation
- 2.4.4 Research Approach
2.5 Research Sources
- 2.5.1 Primary Research Sources
- 2.5.2 Secondary Research Sources
- 2.5.3 Assumptions

3 Market Trend Analysis

3.1 Introduction
3.2 Drivers
3.3 Restraints
3.4 Opportunities
3.5 Threats
3.6 Application Analysis
3.7 End User Analysis
3.8 Emerging Markets
3.9 Impact of Covid-19

4 Porters Five Force Analysis

4.1 Bargaining power of suppliers
4.2 Bargaining power of buyers
4.3 Threat of substitutes
4.4 Threat of new entrants
4.5 Competitive rivalry

5 Global Advanced Materials for Hydrogen Storage Market, By Material Type

5.1 Introduction
5.2 Metal Hydrides
5.3 Chemical Hydrides
5.4 Carbon-based Materials
5.5 Nanostructured Materials
5.6 Metal-Organic Frameworks (MOFs)
5.7 Ammonia Borane
5.8 Other Material Types

6 Global Advanced Materials for Hydrogen Storage Market, By Storage Mechanism

6.1 Introduction
6.2 Adsorption-Based Storage
6.3 Absorption-Based Storage
6.4 Chemical Reaction-Based Storage

7 Global Advanced Materials for Hydrogen Storage Market, By Physical Storage Method

7.1 Introduction
7.2 Compressed Gas Storage
7.3 Liquid Hydrogen Storage

8 Global Advanced Materials for Hydrogen Storage Market, By Application

8.1 Introduction
8.2 Fuel Cell Vehicles (FCVs)
8.3 Portable Power Systems
8.4 Stationary Power Systems
8.5 Industrial Hydrogen Storage
8.6 Aerospace & Defense Systems

9 Global Advanced Materials for Hydrogen Storage Market, By End User

9.1 Introduction
9.2 Automotive
9.3 Energy & Power
9.4 Chemical Manufacturing
9.5 Aerospace
9.6 Marine
9.7 Other End Users

10 Global Advanced Materials for Hydrogen Storage Market, By Geography

10.1 Introduction
10.2 North America
- 10.2.1 US
- 10.2.2 Canada
- 10.2.3 Mexico
10.3 Europe
- 10.3.1 Germany
- 10.3.2 UK
- 10.3.3 Italy
- 10.3.4 France
- 10.3.5 Spain
- 10.3.6 Rest of Europe
10.4 Asia Pacific
- 10.4.1 Japan
- 10.4.2 China
- 10.4.3 India
- 10.4.4 Australia
- 10.4.5 New Zealand
- 10.4.6 South Korea
- 10.4.7 Rest of Asia Pacific
10.5 South America
- 10.5.1 Argentina
- 10.5.2 Brazil
- 10.5.3 Chile
- 10.5.4 Rest of South America
10.6 Middle East & Africa
- 10.6.1 Saudi Arabia
- 10.6.2 UAE
- 10.6.3 Qatar
- 10.6.4 South Africa
- 10.6.5 Rest of Middle East & Africa

11 Key Developments

11.1 Agreements, Partnerships, Collaborations and Joint Ventures
11.2 Acquisitions & Mergers
11.3 New Product Launch
11.4 Expansions
11.5 Other Key Strategies

12 Company Profiling

12.1 Linde plc
12.2 Air Liquide SA
12.3 Air Products and Chemicals, Inc.
12.4 Chart Industries, Inc.
12.5 Hexagon Purus AS
12.6 Nel ASA
12.7 McPhy Energy SA
12.8 Toshiba Energy Systems & Solutions Corporation
12.9 VRV S.P.A
12.10 Hbank Technologies Inc.
12.11 Hexagon Composites ASA
12.12 Otto Chemie Pvt. Ltd.
12.13 GKN Hydrogen GmbH
12.14 Toray Industries, Inc.
12.15 Hexcel Corporation

簡介目錄圖表

List of Tables

Table 1 Global Advanced Materials for Hydrogen Storage Market Outlook, By Region (2024-2032) ($MN)
Table 2 Global Advanced Materials for Hydrogen Storage Market Outlook, By Material Type (2024-2032) ($MN)
Table 3 Global Advanced Materials for Hydrogen Storage Market Outlook, By Metal Hydrides (2024-2032) ($MN)
Table 4 Global Advanced Materials for Hydrogen Storage Market Outlook, By Chemical Hydrides (2024-2032) ($MN)
Table 5 Global Advanced Materials for Hydrogen Storage Market Outlook, By Carbon-based Materials (2024-2032) ($MN)
Table 6 Global Advanced Materials for Hydrogen Storage Market Outlook, By Nanostructured Materials (2024-2032) ($MN)
Table 7 Global Advanced Materials for Hydrogen Storage Market Outlook, By Metal-Organic Frameworks (MOFs) (2024-2032) ($MN)
Table 8 Global Advanced Materials for Hydrogen Storage Market Outlook, By Ammonia Borane (2024-2032) ($MN)
Table 9 Global Advanced Materials for Hydrogen Storage Market Outlook, By Other Material Types (2024-2032) ($MN)
Table 10 Global Advanced Materials for Hydrogen Storage Market Outlook, By Storage Mechanism (2024-2032) ($MN)
Table 11 Global Advanced Materials for Hydrogen Storage Market Outlook, By Adsorption-Based Storage (2024-2032) ($MN)
Table 12 Global Advanced Materials for Hydrogen Storage Market Outlook, By Absorption-Based Storage (2024-2032) ($MN)
Table 13 Global Advanced Materials for Hydrogen Storage Market Outlook, By Chemical Reaction-Based Storage (2024-2032) ($MN)
Table 14 Global Advanced Materials for Hydrogen Storage Market Outlook, By Physical Storage Method (2024-2032) ($MN)
Table 15 Global Advanced Materials for Hydrogen Storage Market Outlook, By Compressed Gas Storage (2024-2032) ($MN)
Table 16 Global Advanced Materials for Hydrogen Storage Market Outlook, By Liquid Hydrogen Storage (2024-2032) ($MN)
Table 17 Global Advanced Materials for Hydrogen Storage Market Outlook, By Application (2024-2032) ($MN)
Table 18 Global Advanced Materials for Hydrogen Storage Market Outlook, By Fuel Cell Vehicles (FCVs) (2024-2032) ($MN)
Table 19 Global Advanced Materials for Hydrogen Storage Market Outlook, By Portable Power Systems (2024-2032) ($MN)
Table 20 Global Advanced Materials for Hydrogen Storage Market Outlook, By Stationary Power Systems (2024-2032) ($MN)
Table 21 Global Advanced Materials for Hydrogen Storage Market Outlook, By Industrial Hydrogen Storage (2024-2032) ($MN)
Table 22 Global Advanced Materials for Hydrogen Storage Market Outlook, By Aerospace & Defense Systems (2024-2032) ($MN)
Table 23 Global Advanced Materials for Hydrogen Storage Market Outlook, By End User (2024-2032) ($MN)
Table 24 Global Advanced Materials for Hydrogen Storage Market Outlook, By Automotive (2024-2032) ($MN)
Table 25 Global Advanced Materials for Hydrogen Storage Market Outlook, By Energy & Power (2024-2032) ($MN)
Table 26 Global Advanced Materials for Hydrogen Storage Market Outlook, By Chemical Manufacturing (2024-2032) ($MN)
Table 27 Global Advanced Materials for Hydrogen Storage Market Outlook, By Aerospace (2024-2032) ($MN)
Table 28 Global Advanced Materials for Hydrogen Storage Market Outlook, By Marine (2024-2032) ($MN)
Table 29 Global Advanced Materials for Hydrogen Storage Market Outlook, By Other End Users (2024-2032) ($MN)