全球甲醇市場（2026-2036 年）

甲醇是世界上生產和交易最廣泛的工業化學品之一，不僅在全球化工價值鏈中佔據基礎地位，而且在向清潔能源轉型中也發揮新的作用。甲醇主要由天然氣、煤炭、生質能或合成氣（綠色氫氣和回收二氧化碳的混合物）製成，是一種無色透明、易揮發的液體，既是常用化學品的原料，又作為能源載體，在尋求石化燃料替代品的行業中扮演著日益重要的戰略角色。

市場結構性張力體現在其既有角色與新興角色之間的矛盾之中。一方面，成熟的、以成本主導的大宗化學品市場依託中國、中東、俄羅斯和美洲的龐大產能，供應甲醇作為甲醛、乙酸、甲醇制烯烴（MTO）、甲基叔丁基醚（MTBE）以及各種工業溶劑和衍生物的原料。這些應用佔據了當前全球甲醇需求的絕大部分，並以與GDP、建設活動、包裝需求和石化產品生產相關的適度速度成長。另一方面，快速發展的能源應用（船用燃料、永續航空燃料、清潔烹飪用二甲醚和可再生氫載體）正以變革性的速度從小規模的基數成長，其驅動力並非來自大宗商品經濟，而是來自監管義務、企業脫碳努力以及國際海事組織（IMO）主導的航運業實現淨零排放的結構性要求。

市場的地理結構反映了數十年來對天然氣和煤化工基礎設施的投資。中國在生產方面保持主導地位，其煤製甲醇產業不僅供應其國家的甲醛和烯烴產業，也定期向全球海運貿易輸送甲醇。以沙烏地阿拉伯、伊朗和卡達主導的中東地區是全球天然氣製甲醇成本最低的生產地，也是全球海運甲醇出口的主導力量。該地區向歐洲、東北亞和南亞的進口市場供應甲醇，但在天然氣價格高漲的地區，其成本始終難以降低。憑藉頁岩氣的經濟優勢，美國已成為甲醇淨出口國，並在《通貨膨脹削減法案》稅額扣抵框架的支持下，正在擴大其藍甲醇和綠甲醇的供應鏈。

未來十年的一個顯著趨勢將是綠色甲醇的出現，這種利用再生能源和電解回收的二氧化碳生產的甲醇，將從示範技術轉變為可靠的商業產品。全球首個商業性綠色甲醇船用燃料供應鏈的運作，以及各大航運公司訂購數百艘可使用甲醇燃料的船舶，標誌著綠色甲醇從概念走向實際應用。降低綠色甲醇成本的進展、國際海事組織（IMO）監管談判的結果，以及中國工業碳政策的進展速度，將決定甲醇最終是僅僅作為一種大宗化學品，還是會成為全球清潔能源經濟的核心組成部分。

本報告對全球甲醇市場進行了深入分析，提供了有關原料和生產流程、貿易流和供應鏈動態、監管和政策環境以及到 2036 年的市場預測等資訊。

目錄

第1章執行摘要

• 2025 年基準：新的十年始於結構性緊張局勢
• 接下來的十年
• 主要預測與研究成果 - 2026–2036 年

第2章：市場定義、細分與價值鏈架構

• 市場定義
• 市場區隔
• 價值鏈架構

第3章：全球生產標準－2025年

• 中國
• 中東
• 俄羅斯和獨立國協
• 美國
• 歐洲
• 千里達和多巴哥以及加勒比海國家
• 其他地區

第4章 原料與生產流程

• 天然氣 - 蒸汽甲烷重整 (SMR)
• 煤製甲醇
• 綠色甲醇－可再生氫氣+二氧化碳（甲醇轉化電能）
• 生質能氣化製取的生物甲醇
• 碳強度：依生產路線

第5章：衍生性商品市場與最終需求

• 甲醛
• 醋酸
• 甲醇制烯烴轉化率（MTO）和甲醇制丙烯轉化率（MTP）
• 甲基第三丁基醚（MTBE）和燃料甲醇
• 船用燃料
• 二甲醚（DME）
• 甲醇制噴射燃料（MtJ）永續航空燃料
• 甲醇作為液體燃料生產的平台－MTG、MTA、MTD、合成燃料經濟學

第6章：全球貿易流動與供應鏈動態

• 全球海運甲醇貿易的結構
• 中國貿易的動態
• 東北亞進口市場
• 北美洲
• 拉丁美洲
• 印度
• 東南亞
• 非洲和中東生產力低的經濟體
• 歐洲進口市場
• 物流基礎設施

第7章 監理/政策環境

• 國際海事組織（IMO）－政策框架定義
• 歐盟 - FuelEU 海事與歐盟排放交易體系
• 中國—碳排放目標與煤化工轉型
• 美國——個人退休帳戶稅額扣抵和海事政策
• 中東—NEOM與綠氫能出口政策

第8章：技術與創新藍圖

• 改進甲醇合成工藝
• 電解技術－增加綠色甲醇成本的因素
• 直接空氣回收
• 藍色甲醇－符合碳捕獲與封存（CCS）標準的天然氣生產
• 甲醇燃料電池和氫載體的應用
• 甲醇制噴射燃料 (MtJ) - SAF 技術開發
• 甲醇生產和貿易領域的數位化創新
• 新型生產技術與下一代生產技術

第9章 市場展望與預測（2026-2036）

• 情境框架和關鍵前提條件
• 全球生產預測 - 所有情景
• 綠色甲醇成本趨同
• 運輸需求
• 衍生性商品市場預測
• 需求預測：按地區分類
• 拉丁美洲—生產和需求預測
• 甲醇價格展望（2026-2036 年）
• 全球綠色甲醇計劃管道
• 關鍵風險、脆弱性和情境觸發因素
• 三大甲醇市場（2036 年）

第10章 甲醇生產商概況

第11章：全球甲醇生產設施名錄

第12章 催化劑與製程技術供應商

第13章：生物甲醇生產商

第14章：綠色/電子甲醇開發商

第15章：新興和早期技術開發者

第16章 參考文獻

Methanol is among the most widely produced and traded industrial chemicals in the world, occupying a foundational position in the global chemical value chain and an emerging one in the clean energy transition. A clear, colourless, volatile liquid produced primarily from synthesis gas derived from natural gas, coal, biomass, or green hydrogen combined with captured carbon dioxide, methanol serves as both a commodity chemical feedstock and an increasingly strategic energy carrier for industries seeking alternatives to fossil fuels.

The market is defined by a structural tension between its established role and its evolving one. On one side sits a mature, cost-driven commodity business built around vast production capacity in China, the Middle East, Russia, and the Americas, supplying methanol as a feedstock for formaldehyde, acetic acid, methanol-to-olefins, MTBE, and a broad range of industrial solvents and derivatives. These applications account for the overwhelming majority of current global methanol demand and grow at modest, GDP-linked rates tied to construction activity, packaging demand, and petrochemical production. On the other side sits a rapidly developing energy application layer - maritime fuel, sustainable aviation fuel, dimethyl ether for clean cooking, and renewable hydrogen carrier - that is growing at transformational rates from a small base and is being driven not by commodity economics but by regulatory mandates, corporate decarbonisation commitments, and the structural requirements of shipping's IMO-driven net-zero pathway.

The geographic architecture of the market reflects decades of investment in natural gas and coal chemical infrastructure. China is dominant in production by a wide margin, with its coal-based methanol industry supplying both its own formaldehyde and olefins sectors and contributing periodically to global seaborne trade. The Middle East - led by Saudi Arabia, Iran, and Qatar - is the world's lowest-cost natural gas methanol production region and the dominant force in global seaborne methanol exports, supplying European, Northeast Asian, and South Asian import markets at costs that no high-gas-price region can consistently undercut. The United States has emerged as a net exporter on the back of shale gas economics and is developing a growing blue and green methanol pipeline underpinned by the Inflation Reduction Act's tax credit framework.

The defining dynamic of the coming decade is the emergence of green methanol - produced from renewable electricity and captured carbon dioxide via electrolysis - as a credible commercial product rather than a demonstration technology. The commissioning of the world's first commercial green methanol maritime bunkering supply chain and the ordering of hundreds of methanol-capable vessels by major shipping companies mark the transition point from aspiration to execution. The trajectory of green methanol cost reduction, the outcome of IMO regulatory negotiations, and the speed of China's industrial carbon policy will together determine whether methanol remains a commodity chemical or becomes a central molecule of the global clean energy economy.

The Global Methanol Market 2026-2036 is a comprehensive ten-year strategic intelligence report covering all dimensions of the global methanol industry at a moment of fundamental structural change. The report is designed for professionals across the methanol supply chain - producers, traders, investors, chemical consumers, maritime operators, technology developers, and policymakers - who require a rigorous, evidence-based framework for understanding how the market will evolve across the Bear, Base, and Bull scenarios that the report constructs and quantifies.

The report opens with an Executive Summary that frames the decade's central question: whether methanol completes the transition from its established role as a commodity chemical feedstock into a dual chemical-energy market, and on what timeline. It identifies three structural forces - maritime decarbonisation, the maturation of China's methanol-to-olefins complex, and green methanol's emergence as a hydrogen economy carrier - as the defining dynamics of the 2026-2036 period, and provides a Key Forecasts table covering global production, green methanol growth, maritime demand, regional demand by geography, and pricing across the full scenario range.

The report's analytical core is built across nine substantive chapters. The market definition and segmentation chapter maps methanol's end-use landscape across the full spectrum from formaldehyde through to emerging maritime and SAF applications, with a detailed five-stage value chain analysis covering feedstock economics, synthesis, logistics, derivatives, and end-use consumption. The global production baseline chapter profiles every significant producing region - with particular depth on China's coal-based complex, the Middle Eastern gas-advantaged producers, and the emerging green methanol project pipeline across Europe, the Americas, and the Middle East. Feedstocks and production processes are examined in detail, with cost-build tables comparing natural gas SMR, coal gasification, green methanol, and bio-methanol pathways across representative global locations and time periods.

Derivative markets, trade flows, the regulatory environment, and the technology innovation roadmap each receive dedicated chapters with quantified data tables rather than narrative overview alone. The market outlook chapter constructs a full scenario matrix across twelve assumption drivers, with regional production and demand forecasts to 2036 by country and sector, maritime demand modelling by vessel buildout scenario, green methanol cost convergence analysis, pricing trajectories by grade and region, and a risk and opportunity matrix with probability-weighted volume impacts.

The report concludes with detailed company profiles of the global methanol industry's principal actors across producers, green methanol developers, maritime operators, technology providers, and Korean market participants, alongside a comprehensive directory of all major global methanol production facilities and ninety references with active web links.

Contents include

• Executive Summary - 2025 baseline; three structural forces defining the decade; key forecasts and findings across Bear, Base, and Bull scenarios
• Market Definition, Segmentation & Value Chain Architecture - market definition; end-use segmentation across nine categories; five-stage value chain from feedstock to end-user
• Global Production Baseline 2025 - country-by-country production profiles covering China, Middle East, Russia, United States, Europe, Trinidad & Tobago, and Rest of World
• Feedstocks & Production Processes - natural gas SMR with production cost builds; coal-based methanol economics and carbon profile; green methanol (power-to-methanol) economics and cost scenarios; bio-methanol from biomass gasification; carbon intensity comparison by pathway
• Derivative Markets & End-Use Demand - formaldehyde; acetic acid; methanol-to-olefins (MTO/MTP); MTBE and fuel methanol including China's M15 programme; maritime fuel including vessel order book and demand modelling; dimethyl ether (DME); methanol-to-jet (MtJ) SAF
• Global Trade Flows & Supply Chain Dynamics - seaborne trade structure and origin-destination matrix; China trade dynamic; Northeast Asian import markets; North America (US, Canada, Mexico); Latin America (Brazil, Argentina, Chile); India; Southeast Asia and Singapore bunkering hub; Africa and Middle East non-producing economies; European import market and green methanol premium; logistics infrastructure
• Regulatory & Policy Environment - IMO GHG strategy, CII, EEXI, SEEMP, and the November 2026 NZF vote; EU FuelEU Maritime, EU ETS maritime inclusion, EU hydrogen policy, and CBAM; China dual carbon goals, national ETS, and fuel methanol policy; US IRA 45V and 45Q credits, Jones Act; Middle East NEOM and Saudi Vision 2030
• Technology & Innovation Roadmap - methanol synthesis process improvements; electrolysis technology and electrolyser cost trajectory; direct air capture; blue methanol and CCS; methanol fuel cells and hydrogen carrier applications; methanol-to-jet SAF process pathways and commercial pipeline; digital innovation including AI optimisation and blockchain certification
• Market Outlook & Forecasts 2026-2036 - scenario framework with twelve assumption drivers; global production forecast by region across all scenarios; green methanol cost convergence trajectory; maritime demand scenarios; derivative market forecasts by sector; regional demand forecasts (China, Europe, Japan, North America, Latin America, India, Southeast Asia); pricing outlook by grade and region; global green methanol project pipeline; risk and opportunity matrix; the three methanol markets of 2036
• Company Profiles - detailed profiles of major producers, technology providers, maritime operators, and regional market participants, with key facts tables. Companies profiled include A.P. Moller-Maersk, ACME Group, Advent Technologies, Air Liquide (Lurgi), Atlas Methanol Company, Baofeng Energy Group, Carbon Recycling International, Celanese Corporation, China Shenhua Energy, CMA CGM, Climeworks, EuroChem (Nevinnomyssky Azot), European Energy, ExxonMobil, Graforce, Hanwha Chemical, HIF Global, HMM (Hyundai Merchant Marine), Jiutai Energy Group, Johnson Matthey, Kaveh Methanol Company, Korea Methanol Association, Liquid Wind, Lotte Chemical, MAN Energy Solutions, Marjan Petrochemical, Metafrax Group, Methanex Corporation and more....
• Global Methanol Production Facility Directory - comprehensive listing of all major facilities of 500,000 tonnes per year or greater capacity globally

TABLE OF CONTENTS

1 EXECUTIVE SUMMARY

• 1.1 2025 Baseline: Entering the Decade from a Position of Structural Tension
• 1.2 The Decade Ahead
  • 1.2.1 The Decade's Largest Demand Catalyst
  • 1.2.2 Chemical Feedstock Evolution: China's MTO/MTP Plateau and the Green Derivatives Opportunity
  • 1.2.3 Green Methanol as a Hydrogen Economy Enabler
• 1.3 Key Forecasts & Findings - 2026-2036

2 MARKET DEFINITION, SEGMENTATION & VALUE CHAIN ARCHITECTURE

• 2.1 Market Definition
• 2.2 Market Segmentation
• 2.3 Value Chain Architecture

3 GLOBAL PRODUCTION BASELINE - 2025

• 3.1 China
  • 3.1.1 Production Infrastructure
  • 3.1.2 Coal-Based Production Economics
  • 3.1.3 Key Chinese Producers
  • 3.1.4 MTO/MTP Demand Base
  • 3.1.5 Green Methanol in China
• 3.2 Middle East
• 3.3 Russia & CIS
• 3.4 United States
• 3.5 Europe
  • 3.5.1 Green Methanol
• 3.6 Trinidad & Tobago and the Caribbean
• 3.7 Rest of World

4 FEEDSTOCKS & PRODUCTION PROCESSES

• 4.1 Natural Gas - Steam Methane Reforming (SMR)
  • 4.1.1 Scale Economics
• 4.2 Coal-Based Methanol
  • 4.2.1 Carbon Profile
  • 4.2.2 Coal Methanol Economics in 2025
• 4.3 Green Methanol - Renewable Hydrogen + CO2 (Power-to-Methanol)
  • 4.3.1 Green Methanol Production Economics (2025)
• 4.4 Bio-Methanol from Biomass Gasification
• 4.5 Carbon Intensity by Production Pathway

5 DERIVATIVE MARKETS & END-USE DEMAND

• 5.1 Formaldehyde
• 5.2 Acetic Acid
• 5.3 Methanol-to-Olefins (MTO) and Methanol-to-Propylene (MTP)
  • 5.3.1 Global MTO/MTP Demand
  • 5.3.2 The Maturity Plateau
• 5.4 Methyl Tertiary Butyl Ether (MTBE) and Fuel Methanol
  • 5.4.1 China Fuel Methanol Programme
• 5.5 Maritime Fuel
  • 5.5.1 The Vessel Order Book
  • 5.5.2 Methanol Demand Modelling for Maritim
  • 5.5.3 The Green Methanol Premium in Maritime
• 5.6 Dimethyl Ether (DME)
• 5.7 Methanol-to-Jet (MtJ) Sustainable Aviation Fuel
• 5.8 Methanol as a Platform for Liquid Fuel Production - MTG, MTA, MTD and the Synthetic Fuels Economy
  • 5.8.1 Methanol-to-Gasoline (MTG)
  • 5.8.2 Methanol-to-Aromatics (MTA)
  • 5.8.3 Methanol-to-Diesel via DME
  • 5.8.4 Implications for the Green Methanol Market

6 GLOBAL TRADE FLOWS & SUPPLY CHAIN DYNAMICS

• 6.1 The Structure of Global Seaborne Methanol Trade
• 6.2 The China Trade Dynamic
• 6.3 Northeast Asian Import Markets
• 6.4 North America
  • 6.4.1 United States - Production, Consumption and Export Architecture
  • 6.4.2 Blue Methanol Development Pipeline
  • 6.4.3 Canada
  • 6.4.4 Mexico
• 6.5 Latin America
  • 6.5.1 Brazil
  • 6.5.2 Argentina and Chile
• 6.6 India
  • 6.6.1 India's Import Supply Chain
• 6.7 Southeast Asia
  • 6.7.1 Singapore
• 6.8 Africa & Middle East Non-Producing Economies
• 6.9 European Import Market
  • 6.9.1 Green Methanol Import Premium
• 6.10 Logistics Infrastructure

7 REGULATORY & POLICY ENVIRONMENT

• 7.1 The International Maritime Organisation (IMO) - The Defining Policy Framework
  • 7.1.1 The 2023 IMO GHG Strategy
  • 7.1.2 Carbon Intensity Indicator (CII)
  • 7.1.3 The Energy Efficiency Existing Ship Index (EEXI) and Ship Energy Efficiency Management Plan (SEEMP)
  • 7.1.4 The IMO Net Zero Framework (NZF) - November 2026 Vote
  • 7.1.5 US Government
• 7.2 European Union - FuelEU Maritime and EU ETS
  • 7.2.1 FuelEU Maritime Regulation
  • 7.2.2 EU Emissions Trading System (ETS) - Maritime Inclusion
  • 7.2.3 EU Hydrogen and Green Methanol Policy
  • 7.2.4 Carbon Border Adjustment Mechanism (CBAM)
• 7.3 China - Dual Carbon Goals and Coal Chemical Transition
  • 7.3.1 China's National ETS and Methanol
  • 7.3.2 Green Methanol and Hydrogen Policy in China
  • 7.3.3 Fuel Methanol Policy
• 7.4 United States - IRA Tax Credits and Maritime Policy
  • 7.4.1 The Inflation Reduction Act - 45V Clean Hydrogen Production Tax Credit
  • 7.4.2 The One Big Beautiful Bill Act (2025)
  • 7.4.3 US Maritime Policy and the Jones Act
• 7.5 Middle East - NEOM and Green Hydrogen Export Policy
  • 7.5.1 Saudi Arabia's Vision 2030 and Chemical Diversification

8 TECHNOLOGY & INNOVATION ROADMAP

• 8.1 Methanol Synthesis Process Improvements
  • 8.1.1 Catalyst Innovation
  • 8.1.2 Direct CO2 Hydrogenation
• 8.2 Electrolysis Technology - The Green Methanol Cost Driver
  • 8.2.1 Electrolyser Technology Landscape
  • 8.2.2 Electrolyser Cost Trajectory
• 8.3 Direct Air Capture
  • 8.3.1 DAC Cost Trajectory
• 8.4 Blue Methanol - CCS-Enabled Natural Gas Production
  • 8.4.1 Blue Methanol Projects in 2025
• 8.5 Methanol Fuel Cells and Hydrogen Carrier Applications
  • 8.5.1 Direct Methanol Fuel Cells (DMFC)
  • 8.5.2 Methanol as Reformed Hydrogen Carrier
  • 8.5.3 Methanol as Bunker Fuel - Engine Technology
• 8.6 Methanol-to-Jet (MtJ) - SAF Technology Development
  • 8.6.1 MtJ Process Pathways
• 8.7 Digital Innovation in Methanol Production and Trading
  • 8.7.1 AI-Optimised Methanol Synthesis
  • 8.7.2 Blockchain-Based Green Methanol Certification
  • 8.7.3 Methanol Trading Platforms
• 8.8 Emerging and Next-Generation Production Technologies

9 MARKET OUTLOOK & FORECASTS 2026-2036

• 9.1 Scenario Framework & Key Assumptions
• 9.2 Global Production Forecast - All Scenarios
  • 9.2.1 Key observations from the production forecast
• 9.3 Green Methanol Cost Convergence
• 9.4 Maritime Demand
• 9.5 Derivative Market Forecasts
  • 9.5.1 Structural Demand Insights
• 9.6 Regional Demand Forecasts
  • 9.6.1 China
  • 9.6.2 Europe
  • 9.6.3 Japan
  • 9.6.4 North America
    • 9.6.4.1 United States
    • 9.6.4.2 US Domestic Demand Forecast
• 9.7 Latin America - Production and Demand Forecast
  • 9.7.1 India
  • 9.7.2 Southeast Asia
• 9.8 Methanol Pricing Outlook 2026-2036
  • 9.8.1 Key Pricing Dynamics
• 9.9 The Global Green Methanol Project Pipeline
• 9.10 Key Risks, Sensitivities & Scenario Triggers
• 9.11 The Three Methanol Markets of 2036

10 METHANOL PRODUCER PROFILES

11 GLOBAL METHANOL PRODUCTION FACILITY DIRECTORY

12 CATALYST & PROCESS TECHNOLOGY PROVIDERS

13 BIO-METHANOL PRODUCERS

14 GREEN / E-METHANOL DEVELOPERS

15 EMERGING & EARLY-STAGE TECHNOLOGY DEVELOPERS

16 REFERENCES

List of Tables

• Table 1. The global methanol market summary.
• Table 2. Key Forecasts & Findings - Global Methanol Market 2026-2036
• Table 3. Global Methanol Market Segmentation by End-Use Category
• Table 4. Global Methanol Production Baseline - 2025
• Table 5. Natural Gas-Based Methanol Production Cost Build - Representative Global Locations (2025)
• Table 6. Green Methanol Production Cost Scenarios - 2025 vs 2030 vs 2036
• Table 7. Methanol Carbon Intensity by Production Pathway - Lifecycle Assessment
• Table 8. Formaldehyde End-Use Breakdown and Methanol Demand 2025
• Table 9. Acetic Acid Derivative Chain - Methanol Demand and Market Dimensions
• Table 10. Maritime Methanol Demand Forecast - Vessel Buildout Scenarios
• Table 11. Methanol-to-Fuel Conversion Pathways - Overview
• Table 12. Global Methanol Trade Routes - Origin-Destination Matrix 2025
• Table 13. US Methanol Supply and Demand Balance 2023-2025
• Table 14. US Export Destinations (2025)
• Table 15. US Blue and Green Methanol Project Pipeline (2025-2030)
• Table 16. Canadian Methanol Market Overview 2025
• Table 17. Mexico Methanol Market Overview 2025
• Table 18. Latin America Methanol Demand Overview 2025
• Table 19. India Methanol Market 2023-2036 (kt)
• Table 20. Southeast Asia Methanol Demand by Country 2025
• Table 21. Singapore Methanol Bunkering Demand Forecast
• Table 22. IMO Regulatory Timeline and Methanol Market Implications
• Table 23. Methanol Production Technology Readiness and Cost Trajectory
• Table 24. Electrolyser Cost Trajectory
• Table 25. MtJ Commercial Development Pipeline
• Table 26. Emerging Methanol Production Technologies - Summary Assessment
• Table 27. Scenario Framework & Key Assumptions
• Table 28. Global Methanol Production Forecast by Region 2025-2036 (Million Tonnes)
• Table 29. Green Methanol Cost Convergence with Fossil Methanol - Base Case Trajectory
• Table 30. Maritime Methanol Demand Forecast - Scenario Analysis 2025-2036
• Table 31. Global Methanol Demand by End-Use Sector 2025-2036 (Million Tonnes)
• Table 32. China Methanol Demand by Sector 2025-2036 (Mt)
• Table 33. European Methanol Demand Forecast 2025-2036 (Mt)
• Table 34. US Methanol Production Forecast by Pathway 2025-2036 (Mt)
• Table 35. US Methanol Domestic Demand Forecast by Sector 2025-2036 (Mt)
• Table 36. US Methanol Net Trade Position 2025-2036 (Mt)
• Table 37. Trinidad & Tobago Methanol Production Forecast 2025-2036 (Mt)
• Table 38. Chile Methanol Production Forecast - Fossil to Green Transition 2025-2036 (Mt)
• Table 39. India M15 Fuel Methanol Programme - Implementation Scenarios
• Table 40. Southeast Asia Methanol Demand Forecast 2025-2036 (kt)
• Table 41. Methanol Pricing Outlook by Grade and Region 2025-2036
• Table 42. Selected Major Green and Blue Methanol Projects - Status March 2026
• Table 43. Risk and Opportunity Matrix - Global Methanol Market 2026-2036
• Table 44. Major Global Methanol Production Facilities - December 2025

List of Figures

• Figure 1. Stage 1 - Feedstock Production
• Figure 2. Stage 2 - Methanol Synthesis
• Figure 3. Stage 3 - Storage, Blending & Export
• Figure 4. Stage 4 - Derivative Manufacturing & Downstream Conversion.
• Figure 5. Stage 5 - End-User Consumption
• Figure 6. Electrolyser Cost Trajectory
• Figure 7. Global Methanol Production Forecast by Region 2025-2036 (Million Tonnes)
• Figure 8. China Methanol Demand by Sector 2025-2036 (Mt)
• Figure 9. European Methanol Demand Forecast 2025-2036 (Mt)
• Figure 10. US Methanol Production Forecast by Pathway 2025-2036 (Mt)
• Figure 11. US Methanol Domestic Demand Forecast by Sector 2025-2036 (Mt)
• Figure 12. Methanol Pricing Outlook by Grade and Region 2025-2036