ガス分離膜 2026-2036年:材料、市場、有力企業、予測

脱炭素化用途における市場展望:バイオガス改良(バイオメタン・再生可能天然ガス)、二酸化炭素回収、水素、ヘリウム。膜材料、有力企業、市場予測。

By , and
製品情報 概要 目次 FAQ (よくある質問) 価格 Related Content
本調査レポートでは、ガス分離膜の市場、材料、有力企業を解説します。取り上げる具体的な脱炭素化用途としては、バイオガス改良(バイオメタン・RNG)、CCUS(天然ガス処理・燃焼後回収)、水素分離(アンモニア製造、精製・石油化学、メタノール製造、ブルー水素製造、アンモニア分解)、ヘリウムなどがあります。2025年から2036年までのガス分離膜の予測を掲載しており、この製品分野における最も包括的な調査となっています。新用途向けのガス分離膜市場が17%の年平均成長率で2036年まで成長するなど、大きな機会があることを明らかにしています。
「ガス分離膜 2026-2036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
■ ガス分離膜製造
  • 大手ガス分離膜メーカー
  • 膜製造技術
■ バイオガス改良
■ CCUS
  • 天然ガスのスウィートニング用(硫化物除去)ガス分離膜
  • 燃焼後炭素回収向けガス分離膜
  • その他CCUS用途(酸素燃焼、EOR、DAC)のガス分離膜
■ 水素
  • 水素バリューチェーン概要
  • 既存水素用途向けガス分離膜
  • 最新水素用途のガス分離膜(ブルー水素・燃焼前炭素回収、水素分離、アンモニア分解)
  • 水素分離用高分子膜材料イノベーション
  • アンモニア分解などの用途での水素精製用の金属膜
■ ヘリウム
■ 市場予測
  • ガス分離膜の市場予測
  • バイオメタンの市場予測
  • 天然ガス市場予測
  • 燃焼後炭素回収用膜の市場予測
  • 水素製造用膜の市場予測(アンモニア製造、精製・石油化学、メタノール製造、ブルー水素製造)
■ 企業概要
 
「ガス分離膜 2026-2036年」は以下の情報を提供します
市場分析:脱炭素化用途のガス分離膜
  • 膜材料収益と膜材料領域(5つの応用分野別)の2036年までの市場予測、バイオメタンの生産予測(地域別)、天然ガス生産、燃焼後炭素回収、水素の各用途のその他ガス市場予測
  • 大手膜メーカー概要(主要製品、パートナーシップ、市場動向など)
  • 主要新興市場の市場評価・展望(商業動向、市場推進要因、企業状況など)
  • バイオガス改良とバイオメタン(RNG)
  • 二酸化炭素回収(天然ガス処理、燃焼後回収、直接空気回収や酸素燃焼などの新用途)
  • 水素分離(アンモニア製造、メタノール製造、石油化学・精製、ブルー水素、アンモニア分解、水素分離などの新用途)
  • ヘリウムの生産と回収
技術評価:新旧のガス分離膜材料
  • 高分子膜、セラミック膜、金属膜、複合膜の技術概要
  • ガス分離用途ごとに、代替分離技術(PSA法や深冷分離法など)と比較し、ペインポイントと技術面を解説
  • 気体混合物分離用の先進膜の主要技術評価(TRL、ベンチマーク評価)(例:薄膜複合(TFC)膜、促進輸送膜(FTM)、固有微細孔性高分子(PIM)、混合マトリックス膜(MMM)など)
 
Gas separation is a widespread industrial process. Among gas separation technologies, membranes have distinct advantages such as high energy efficiency and compact design. Mature applications for gas separation membranes, such as natural gas processing, have existed commercially for decades using simple polymeric materials such as cellulose acetate and polyimide. As governments and industries alike strive to reach net-zero by 2050 targets, new decarbonization applications are emerging for membranes, with new membrane materials being developed in the pursuit of improved performance.
 
"Gas Separation Membranes 2026-2036: Materials, Markets, Players, and Forecasts" provides a comprehensive outlook for gas separation membrane markets, with an in-depth analysis of the technological and economic aspects, alongside new materials, that are shaping this market. In it, IDTechEx focuses on the gas separation membrane applications most relevant to increasing demand for energy security and decarbonization, namely:
  • Biogas upgrading to produce biomethane/renewable natural gas (RNG)
  • CCUS (carbon capture, utilization, and storage)- natural gas processing, post-combustion capture, and other applications (DAC, EOR, and oxy-fuel combustion)
  • Hydrogen separations including mature applications (ammonia production, refining & petrochemical, and methanol production) and emerging applications (blue hydrogen/pre-combustion carbon capture, hydrogen deblending, and ammonia cracking)
  • Helium separation/recovery
 
This IDTechEx report analyses key market opportunities for both incumbent polymer membranes and new membrane materials within existing and emerging markets.
IDTechEx forecasts emerging membrane markets (biogas upgrading, post-combustion capture, blue hydrogen) will see the largest growth in revenue by 2036. Image source: IDTechEx
 
Membranes are the leading technology for biogas upgrading:
Membranes have rapidly become the leading technology for biogas upgrading, driven by their simplicity, low OPEX, and superior energy efficiency. This IDTechEx report provides a comprehensive overview of the biogas upgrading space, including regional biomethane demand forecasts, market drivers/barriers for RNG, leading membrane players and materials, emerging membrane materials, and alternative biogas upgrading technologies.
 
Gas separation membranes for post-combustion carbon capture are scaling up:
Outside of natural gas processing (CO2/CH4 separation), incumbent polymer membranes do not perform well at carbon capture (usually CO2/N2 separation). However, compared to incumbent amine-solvent post-combustion capture technologies, the lower energy demand of membranes could significantly lower carbon capture costs. Therefore, post-combustion capture will be a significant market growth opportunity for new membrane materials.
 
This IDTechEx report includes market research on projects, players, materials, benchmarking, and economic analysis for gas separation membranes in post-combustion carbon capture. Gas separation membranes for post-combustion capture, although not yet at the megatonne per annum scale, are continuing to scale up, with projects capable of capturing 10,000s tonnes per annum of CO2 coming online in 2025/2026.
 
Established and emerging hydrogen applications present opportunities for membranes:
Membranes are already established for mature hydrogen applications such as ammonia and methanol production. The most economic performance is usually achieved by deploying gas separation membranes in hybrid systems alongside technologies such as pressure swing adsorption (PSA). For emerging applications, new membrane materials such as palladium membranes are being explored, offering advantages such as high hydrogen purity. In this report, IDTechEx provides a detailed overview of gas separation membranes for hydrogen separations, assessing key markets, players, and materials.
 
New gas separation membrane materials can improve performance:
Incumbent asymmetric polymer membranes are easy to fabricate and cheap to produce. However, new gas separation membrane materials can enhance separation performance. This IDTechEx report analyses emerging players and materials for gas separation membranes, including players seeking to commercialize advanced polymer materials, metals, ceramics, carbon-based membranes, and new composite structures (such as thin film composites and mixed matric membranes). New membrane materials examined include Pd-metallic membranes, PEG-based membranes, facilitated transport membranes, mixed matrix membranes with MOFs, carbon fiber membranes, graphene membranes, zeolite ceramic membranes, polybenzimidazole membranes, and carbon molecular sieves.
 
Development of new membrane materials encompasses advanced polymer materials, new composite structures, and can go beyond polymeric materials to metals and ceramics. Image source: IDTechEx
 
Key Aspects: This report provides the following information:
 
Market Analysis: Gas Separation Membranes for Decarbonization Applications
  • Granular market forecasts until 2036 for revenue from membrane materials and area of membrane material (subdivided into 5 application areas), biomethane production forecasts (segmented by region), and other gas market forecasts for natural gas production, post-combustion carbon capture, and hydrogen applications.
  • Detailed overview of major membrane manufacturers, including key products, partnerships, and market developments.
  • Market assessment and outlook for key emerging markets. This includes commercial developments, market drivers and company landscapes:
  • Biogas upgrading to biomethane (RNG)
  • Carbon capture (natural gas processing, post-combustion, and emerging applications such as direct air capture and oxyfuel combustion)
  • Hydrogen separation (ammonia production, methanol production, petrochemical/refining, and emerging applications such as blue hydrogen, ammonia cracking, and hydrogen deblending)
  • Helium production and recovery
 
Technology Assessment: Incumbent and Emerging Gas Separation Membrane Materials
  • Technology overview of polymeric, ceramic, metal, and composite membranes.
  • For each gas separation application, a comparison against alternative separation techniques (e.g., PSA or cryogenic) and discussion on pain points and technical -Key technology assessments (TRL, benchmarking) for emerging membranes targeting the separation of gas mixtures. Examples include thin film composite (TFC) membranes, facilitated transport membranes (FTMs), polymers of intrinsic microporosity (PIM), mixed matrix membranes (MMMs), and many more.
Report MetricsDetails
Historic Data1990 - 2024
CAGREmerging decarbonization gas separation membrane markets will grow at a 17% CAGR to 2036
Forecast Period2025 - 2036
Forecast UnitsRevenue from membrane materials (US$), area of membrane material (m2), gas markets (bcm/Mtpa)
Regions CoveredWorldwide
Segments CoveredNatural gas processing, biogas upgrading (segmented by region), post-combustion carbon capture, blue hydrogen, grey hydrogen (ammonia production, refining & petrochemical, methanol production), and % of membrane technology usage.
IDTechEx のアナリストへのアクセス
すべてのレポート購入者には、専門のアナリストによる最大30分の電話相談が含まれています。 レポートで得られた重要な知見をお客様のビジネス課題に結びつけるお手伝いをいたします。このサービスは、レポート購入後3ヶ月以内にご利用いただく必要があります。
詳細
この調査レポートに関してのご質問は、下記担当までご連絡ください。

アイディーテックエックス株式会社 (IDTechEx日本法人)
担当: 村越美和子 m.murakoshi@idtechex.com
1.EXECUTIVE SUMMARY
1.1.Introduction to gas separation membranes for decarbonization
1.2.Gas separation membrane markets: Maturities and opportunities
1.3.Leading polymer materials for gas separation membranes
1.4.Material developments for gas separation membranes
1.5.Commercial maturity of materials for gas separation membranes applications in this report
1.6.Key players in gas separation membranes by material
1.7.Developing new membrane materials: Key trends
1.8.Overview of gas separation membranes for decarbonization applications
1.9.Gas separation membranes for biogas upgrading
1.10.Gas separation membranes for natural gas processing
1.11.Gas separation membranes for post-combustion carbon capture
1.12.Gas separation membranes for hydrogen
1.13.Gas separation membranes for helium
1.14.Overview of gas separation membranes in decarbonization
1.15.Main gas separation polymer membrane manufacturers
1.16.Recent industry progress in gas separation membranes for decarbonization
1.17.IDTechEx forecast: Revenue from gas separation membranes
1.18.Access More With an IDTechEx Subscription
2.INTRODUCTION
2.1.Introduction to gas separation membranes for decarbonization
2.2.Gas separation membrane markets: Maturities and opportunities
2.3.Why use membranes for gas separation?
2.4.Membranes: Operating principles
2.5.Leading polymer materials for gas separation membranes
2.6.Polymeric membrane module design: Hollow fibre vs spiral wound
2.7.Material developments for gas separation membranes
2.8.Comparing gas separation membrane materials
2.9.Polymeric-based membranes for gas separation: Overview
2.10.Ceramic-based membranes for gas separation: Overview
2.11.Metallic-based membranes for gas separation: Overview
2.12.Composite membranes for gas separation: Overview
2.13.Asymmetric membranes vs TFC membranes
2.14.Overcoming the Robeson limit: Achieving maximum selectivity and permeability
2.15.Developing new membrane materials: Key trends
2.16.Polymer membranes usually require multi-stage processes
2.17.Overview of gas separation membranes in decarbonization
3.GAS SEPARATION MEMBRANE MANUFACTURING
3.1.Leading gas separation membrane manufacturers
3.1.1.History of gas separation membranes
3.1.2.Air Liquide
3.1.3.Air Products
3.1.4.Honeywell UOP
3.1.5.UBE
3.1.6.Evonik
3.1.7.SLB
3.1.8.MTR (Membrane Technology and Research)
3.1.9.Airrane
3.1.10.Main gas separation polymer membrane manufacturers
3.1.11.2024/2025 Industry News: Gas Separation Membranes
3.2.Membrane fabrication techniques
3.2.1.Conventional membrane manufacturing: Phase inversion
3.2.2.Single asymmetric membrane vs dual layer membrane
3.2.3.Hybrid NIPS and TIPS gas separation membrane fabrication
3.2.4.Manufacturing thin film composites
3.2.5.Manufacturing organic hybrid membranes: SK Innovation
3.2.6.Manufacturing carbon membranes: Toray
4.BIOGAS UPGRADING
4.1.Introduction to biogas upgrading
4.2.Biomethane markets (renewable natural gas markets)
4.3.Barrier: Biomethane production more expensive than natural gas
4.4.Biomethane/RNG market commentary
4.5.Membranes have become the favoured technology for biogas upgrading
4.6.Main players in biogas upgrading gas separation membranes
4.7.Market share of biogas upgrading membranes
4.8.Biomethane: Main plant players
4.9.Desirable properties for biogas upgrading membranes
4.10.Evonik: 3-stage membrane process for biogas upgrading
4.11.Additional stages in membrane biogas upgrading
4.12.Hybrid process: Membranes and cryogenic for upgrading landfill gas
4.13.Emerging materials for biogas upgrading membranes
4.14.Alternatives to membranes: Developments in biogas upgrading technologies
5.CCUS
5.1.Introduction
5.1.1.What is Carbon Capture, Utilization and Storage (CCUS)?
5.1.2.Why CCUS and why now?
5.1.3.The CCUS value chain
5.1.4.Main CO2 capture systems
5.1.5.Development of the CCUS business model
5.1.6.CCUS business model: full value chain
5.1.7.CCUS business model: Networks and hub model
5.1.8.CCUS business model: Partial-chain
5.1.9.Main CO2 capture technologies
5.1.10.Comparison of CO2 capture technologies
5.1.11.Amine solvents dominate carbon capture but there are opportunities for membranes
5.1.12.No single carbon capture technology will be the best across all applications
5.1.13.Carbon capture technology providers for existing large-scale projects
5.1.14.Technology readiness levels of carbon capture technologies
5.2.Gas separation membranes for natural gas sweetening
5.2.1.Introduction to natural gas processing with carbon capture
5.2.2.Development of membranes for natural gas processing
5.2.3.Market share of natural gas separation membranes
5.2.4.Gas separation membranes for natural gas sweetening
5.2.5.Natural gas processing: spiral wound and hollow fiber membranes
5.2.6.H2S considerations in CH4/CO2 separation for natural gas sweetening
5.2.7.Overview of largest natural gas processing CCUS projects
5.2.8.Fluoropolymer gas separation membranes for natural gas processing
5.3.Gas separation membranes for post-combustion carbon capture
5.3.1.Post-combustion CO₂ capture
5.3.2.Membranes for post-combustion CO2 capture
5.3.3.When should alternatives to solvent-based carbon capture be used?
5.3.4.Overcoming the Robeson limit for post-combustion carbon capture
5.3.5.Leading players in membrane-based post-combustion capture
5.3.6.Polymer membranes for post-combustion carbon capture: PEG membranes
5.3.7.Economics of polymer membranes for post-combustion capture
5.3.8.Increasing CO2 recovery rates for polymer membranes: MTR example
5.3.9.Polymer membranes for post-combustion carbon capture: emerging materials
5.3.10.Facilitated transport membranes (FTM) for post-combustion carbon capture
5.3.11.Energy demand of post-combustion carbon capture technologies
5.3.12.Economics of FTMs for post-combustion carbon capture
5.3.13.Facilitated transport membrane materials for post-combustion carbon capture
5.3.14.Challenges and innovations for membranes in post-combustion capture
5.3.15.2024/2025 Industry News: Membranes for post-combustion capture
5.3.16.Benchmarking membranes for post-combustion capture
5.3.17.Graphene membranes for post-combustion carbon capture: Emerging material
5.3.18.MOF membranes for post-combustion carbon capture: Emerging material
5.4.Gas separation membranes for other CCUS applications (oxyfuel, EOR, DAC)
5.4.1.Oxy-fuel combustion CO₂ capture
5.4.2.Oxygen separation technologies for oxy-fuel combustion
5.4.3.What is CO2-EOR?
5.4.4.What happens to the injected CO2?
5.4.5.Membrane technology for EOR
5.4.6.CO2 capture/separation mechanisms in DAC
5.4.7.Membranes for direct air capture
5.4.8.IDTechEx CCUS Portfolio
6.HYDROGEN
6.1.Overview of the hydrogen value chain
6.1.1.State of the hydrogen market today
6.1.2.Major drivers for low-carbon hydrogen production & adoption
6.1.3.Key legislation & funding mechanisms driving hydrogen development
6.1.4.The colors of hydrogen
6.1.5.Hydrogen value chain overview
6.1.6.Blue hydrogen: Main syngas production technologies
6.1.7.Blue hydrogen production - SMR with CCUS example
6.1.8.Cost comparison of different types of hydrogen
6.1.9.Overview of hydrogen storage
6.1.10.Overview of hydrogen distribution
6.1.11.Hydrogen carriers - overview
6.1.12.Hydrogen carriers - liquid hydrogen (LH2) vs ammonia & LOHCs
6.1.13.Overview of hydrogen applications
6.1.14.Hydrogen purity requirements
6.2.Gas separation membranes for established hydrogen applications
6.2.1.Gas separation membranes used for hydrogen separation - overview
6.2.2.Common gas separations where hydrogen is used & competing technologies
6.2.3.Example application - hydrogen recovery from ammonia reactor purge gas
6.2.4.Example application - hydrogen recovery in refinery applications
6.2.5.Key gas separation membrane players in established hydrogen separations
6.2.6.Market share of hydrogen separation membranes in mature applications
6.3.Gas separation membranes in emerging hydrogen applications (blue hydrogen/pre-combustion carbon capture, hydrogen deblending, ammonia cracking)
6.3.1.Emerging opportunities for gas separation membranes in hydrogen
6.3.2.Key membrane players targeting emerging hydrogen applications
6.3.3.Gas separation membranes in blue hydrogen production (pre-combustion capture)
6.3.4.Honeywell UOP - membranes in CO2 fractionation for blue hydrogen
6.3.5.Air Liquide hybrid technology for CCUS: Blue hydrogen
6.3.6.Hydrogen blending & deblending with natural gas
6.3.7.Hydrogen deblending - applicability of membrane separations
6.3.8.Hydrogen deblending - Linde & Evonik system case study (1)
6.3.9.Hydrogen deblending - Linde & Evonik system case study (2)
6.3.10.Hydrogen deblending - National Gas case study (UK)
6.3.11.Electrochemical hydrogen separation - competitor to gas separation membranes
6.3.12.Electrochemical hydrogen separation - key players
6.3.13.Membranes in ammonia cracking
6.4.Innovations in polymer membrane materials for hydrogen separation
6.4.1.Key R&D areas for gas separation membranes
6.4.2.Polymer membrane developments for hydrogen separation - DiviGas
6.4.3.Polymer membrane developments for hydrogen separation - DiviGas
6.4.4.Polymer membrane developments for hydrogen separation - Membravo
6.4.5.Other commercial developments for polymer membranes in hydrogen separation
6.4.6.Polymers of intrinsic microporosity for hydrogen separation - Osmoses
6.4.7.Key academic research areas for H2 separation - mixed matrix membranes
6.4.8.Case study - novel mixed matrix membrane (MMM) for hydrogen
6.4.9.Key academic research areas for H2 separation - carbon molecular sieves
6.4.10.Case study - novel hybrid boronitride-CMS membrane for hydrogen
6.5.Metallic membranes for hydrogen purification in ammonia cracking & other applications
6.5.1.Metallic membranes for hydrogen purification - overview
6.5.2.Metallic membranes for hydrogen purification - materials
6.5.3.Key application markets for metallic membranes
6.5.4.Key metallic membrane players - Hydrogen Mem-Tech (1)
6.5.5.Key metallic membrane players - Hydrogen Mem-Tech (2)
6.5.6.Key metallic membrane players - H2SITE (1)
6.5.7.Key metallic membrane players - H2SITE (2)
6.5.8.Key metallic membrane players - H2SITE (3)
6.5.9.Other players developing metallic composite membrane systems
6.5.10.Other players developing metallic composite membrane systems
6.5.11.Other players developing metallic composite membrane systems
6.5.12.Other players developing metallic composite membrane systems
6.5.13.IDTechEx Hydrogen & Fuel Cell Research Portfolio
7.HELIUM
7.1.Helium markets
7.2.Typical helium supply chain and separation processes
7.3.Three industrial helium separation technologies: Cryogenic, PSA and membranes
7.4.Hollow fiber membranes are a popular choice for helium separation
7.5.Different types of hollow fiber membranes are available for helium separation
7.6.Generon's membranes + PSA technology can recover helium to >99.5% purity
7.7.Grasys develops and provides membrane technology for helium separation
7.8.Air Liquide's advanced separation technology uses membranes and PSA
7.9.Linde offers cryogenic, membrane, and PSA-based separation technologies
7.10.UGS offers fully skidded membrane-based helium separation systems
7.11.Membrane and PSA methods are more economical than cryogenic separation
7.12.Helium Market 2025-2035: Applications, Alternatives, and Reclamation
8.MARKET FORECASTS
8.1.Gas separation membrane market forecasts
8.1.1.Scope for IDTechEx gas separation membrane forecasts
8.1.2.Revenue from gas separation membranes: 2026-2036 (million US$)
8.1.3.Area of membrane material: 2026-2036 (million m2)
8.1.4.Gas separation membrane market forecasts discussion
8.2.Biomethane market forecasts
8.2.1.Global biomethane production forecast segmented by region: 2013-2036 (billion cubic meters)
8.2.2.Global biomethane production forecast discussion
8.2.3.% of biogas upgrading plants using membrane separation technologies: 2013-2036
8.2.4.Membrane biogas upgrading forecast: 2025-2036 (billion cubic meters of biomethane produced)
8.3.Natural gas market forecasts
8.3.1.Global natural gas production forecast: 1990-2036 (billion cubic meters)
8.3.2.% of natural gas processing plants using membrane separation technologies: 2000-2036
8.3.3.Membrane natural gas processing forecast: 2025-2036 (billion cubic meters of natural gas)
8.4.Membranes for post-combustion carbon capture market forecasts
8.4.1.Membrane post-combustion capture forecast: 2025-2036 (million tonnes per annum of CO2 captured)
8.4.2.Membrane post-combustion capture forecast discussion
8.5.Membranes for hydrogen production market forecasts (ammonia production, refining & petrochemical, methanol production, and blue hydrogen production)
8.5.1.Membrane hydrogen production forecast: 2024-2036 (million tonnes per annum of H2)
8.5.2.Membrane hydrogen production forecast discussion
9.COMPANY PROFILES
9.1.Links to company profiles on the IDTechEx portal
 

About IDTechEx reports

What are the qualifications of the people conducting IDTechEx research?

Content produced by IDTechEx is researched and written by our technical analysts, each with a PhD or master's degree in their specialist field, and all of whom are employees. All our analysts are well-connected in their fields, intensively covering their sectors, revealing hard-to-find information you can trust.

How does IDTechEx gather data for its reports?

By directly interviewing and profiling companies across the supply chain. IDTechEx analysts interview companies by engaging directly with senior management and technology development executives across the supply chain, leading to revealing insights that may otherwise be inaccessible.
 
Further, as a global team, we travel extensively to industry events and companies to conduct in-depth, face-to-face interviews. We also engage with industry associations and follow public company filings as secondary sources. We conduct patent analysis and track regulatory changes and incentives. We consistently build on our decades-long research of emerging technologies.
 
We assess emerging technologies against existing solutions, evaluate market demand and provide data-driven forecasts based on our models. This provides a clear, unbiased outlook on the future of each technology or industry that we cover.

What is your forecast methodology?

We take into account the following information and data points where relevant to create our forecasts:
  • Historic data, based on our own databases of products, companies' sales data, information from associations, company reports and validation of our prior market figures with companies in the industry.
  • Current and announced manufacturing capacities
  • Company production targets
  • Direct input from companies as we interview them as to their growth expectations, moderated by our analysts
  • Planned or active government incentives and regulations
  • Assessment of the capabilities and price of the technology based on our benchmarking over the forecast period, versus that of competitive solutions
  • Teardown data (e.g. to assess volume of materials used)
  • From a top-down view: the total addressable market
  • Forecasts can be based on an s-curve methodology where appropriate, taking into account the above factors
  • Key assumptions and discussion of what can impact the forecast are covered in the report.

How can I be confident about the quality of work in IDTechEx reports?

Based on our technical analysts and their research methodology, for over 25 years our work has regularly received superb feedback from our global clients. Our research business has grown year-on-year.
 
Recent customer feedback includes:
"It's my first go-to platform"
- Dr. Didi Xu, Head of Foresight - Future Technologies, Freudenberg Technology Innovation
 
"Their expertise allows us to make data-driven, strategic decisions and ensures we remain aligned with the latest trends and opportunities in the market."
- Ralf Hug, Global Head of Product Management & Marketing, Marquardt

What differentiates IDTechEx reports?

Our team of in-house technical analysts immerse themselves in industries over many years, building deep expertise and engaging directly with key industry players to uncover hard-to-find insights. We appraise technologies in the landscape of competitive solutions and then assess their market demand based on voice-of-the-customer feedback, all from an impartial point of view. This approach delivers exceptional value to our customers—providing high-quality independent content while saving customers time, resources, and money.

Why should we pick IDTechEx research over AI research?

A crucial value of IDTechEx research is that it provides information, assessments and forecasts based on interviews with key people in the industry, assessed by technical experts. AI is trained only on content publicly available on the web, which may not be reliable, in depth, nor contain the latest insights based on the experience of those actively involved in a technology or industry, despite the confident prose.

How can I justify the ROI of this report?

Consider the cost of the IDTechEx report versus the time and resources required to gather the same quality of insights yourself. IDTechEx analysts have built up an extensive contact network over many years; we invest in attending key events and interviewing companies around the world; and our analysts are trained in appraising technologies and markets.
 
Each report provides an independent, expert-led technical and market appraisal, giving you access to actionable information immediately, rather than you having to spend months or years on your own market research.

Can I speak to analysts about the report content?

All report purchases include up to 30 minutes of telephone time with an expert analyst who will help you link key findings in the report to the business issues you're addressing. This needs to be used within three months of purchasing the report.

What is the difference between a report and subscription?

A subscription from IDTechEx can include more reports, access to an online information platform with continuously updated information from our analysts, and access to analysts directly.

Before purchasing, I have some questions about the report, can I speak to someone?

Please email research@idtechex.com stating your location and we will quickly respond.

About IDTechEx

Who are IDTechEx's customers?

IDTechEx has served over 35,000 customers globally. These range from large corporations to ambitious start-ups, and from Governments to research centers. Our customers use our work to make informed decisions and save time and resources.

Where is IDTechEx established?

IDTechEx was established in 1999, and is headquartered in Cambridge, UK. Since then, the company has significantly expanded and operates globally, having served customers in over 80 countries. Subsidiary companies are based in the USA, Germany and Japan.

Questions about purchasing a report

How do I pay?

In most locations reports can be purchased by credit card, or else by direct bank payment.

How and when do I receive access to IDTechEx reports?

When paying successfully by credit card, reports can be accessed immediately. For new customers, when paying by bank transfer, reports will usually be released when the payment is received. Report access will be notified by email.

How do I assign additional users to the report?

Users can be assigned in the report ordering process, or at a later time by email.

Can I speak to someone about purchasing a report?

Please email research@idtechex.com stating your location and we will quickly respond.
 

価格および注文方法

ガス分離膜 2026-2036年:材料、市場、有力企業、予測

£$¥
電子版_PDF(ユーザー 1-5名)
£5,650.00
電子版_PDF(ユーザー 6-10名)
£8,050.00
電子版_PDFおよびハードコピー1部(ユーザー 1-5名)
£6,450.00
電子版_PDFおよびハードコピー1部(ユーザー 6-10名)
£8,850.00
電子版_PDF(ユーザー 1-5名)
€6,400.00
電子版_PDF(ユーザー 6-10名)
€9,100.00
電子版_PDFおよびハードコピー1部(ユーザー 1-5名)
€7,310.00
電子版_PDFおよびハードコピー1部(ユーザー 6-10名)
€10,010.00
電子版_PDF(ユーザー 1-5名)
$7,000.00
電子版_PDF(ユーザー 6-10名)
$10,000.00
電子版_PDFおよびハードコピー1部(ユーザー 1-5名)
$7,975.00
電子版_PDFおよびハードコピー1部(ユーザー 6-10名)
$10,975.00
電子版_PDF(ユーザー 1-5名)
元50,000.00
電子版_PDF(ユーザー 6-10名)
元72,000.00
電子版_PDFおよびハードコピー1部(ユーザー 1-5名)
元58,000.00
電子版_PDFおよびハードコピー1部(ユーザー 6-10名)
元80,000.00
電子版_PDF(ユーザー 1-5名)
¥990,000
電子版_PDF(ユーザー 6-10名)
¥1,406,000
電子版_PDFおよびハードコピー1部(ユーザー 1-5名)
¥1,140,000
電子版_PDFおよびハードコピー1部(ユーザー 6-10名)
¥1,556,000
電子版_PDF(ユーザー 1-5名)
₩0
電子版_PDF(ユーザー 6-10名)
₩0
電子版_PDFおよびハードコピー1部(ユーザー 1-5名)
₩0
電子版_PDFおよびハードコピー1部(ユーザー 6-10名)
₩0
Click here to enquire about additional licenses.
If you are a reseller/distributor please contact us before ordering.
お問合せ、見積および請求書が必要な方はm.murakoshi@idtechex.com までご連絡ください。
新しい脱炭素化用途のガス分離膜市場は17%の年平均成長率で2036年まで成長していく見通し
Buy now Get a quote Ask a question

レポート概要

スライド 231
フォーキャスト 2036
発行日 May 2025
 

コンテンツのプレビュー

pdf Document Sample pages
 

Customer Testimonial

quote graphic
"The resources produced by IDTechEx are a valuable tool... Their insights and analyses provide a strong foundation for making informed, evidence-based decisions. By using their expertise, we are better positioned to align our strategies with emerging opportunities."
Director of Market Strategy
Centre for Process Innovation (CPI)
 
 
 
ISBN: 9781835701249

Subscription Enquiry