电子甲醇市场评估：依能源（太阳能、水力、风能等）、应用（化学原料、船用燃料、发电等）、地区（2017-2031）划分的机会和预测

全球电子甲醇市场规模将从2023年的2.311亿美元成长到2031年的15.1877亿美元，预计2024-2031年期间复合年增长率为26.65%。

对电子甲醇的需求呈指数级增长。 日益增长的环境问题和对可持续燃料的持续需求正在推动对电子甲醇的需求。 此外，对电动车的需求不断增长，以及各行业对可持续能源取代旧化石燃料的需求正在推动市场成长。 2023年4月，全球最大的甲醇生产商Macetex预计，未来5年全球甲醇需求将增加1,400万吨以上。 这种成长轨迹得到了逐步过渡到再生甲醇的支持。 国际再生能源机构 (IRENA) 也表示，预计到 2050 年每年将生产 2.5 亿吨电子甲醇。

对再生和永续燃料的需求不断增长推动市场成长：

由于运输、化学生产和发电等许多行业对再生和永续燃料的需求不断增加，全球对电子甲醇的需求正在迅速增加。 再生能源技术的进步正在加速电子甲醇的扩张，利用风能、太阳能和水力发电进行水力发电进行水力发电解，以实现高效生产。 这种绿色燃料是一种多功能能源载体，可促进电网稳定、能源安全和转型为循环经济。

化学原料中电子甲醇的不断整合推动了市场扩张：

电子甲醇在化工原料中的使用不断增加，对电子甲醇业务产生了重大影响。 这种整合是由各行业对绿色碳原料的需求不断增长所推动的。 从二氧化碳和电解氢合成电解甲醇的转变正在受到关注，特别是在化学品製造、海运和空运以及甲醇衍生物生产等应用中。

政府措施支持市场成长：

政府政策对于加速电子甲醇市场的扩张至关重要。 政府机构和组织之间的合作旨在促进永续能源，同时透过鼓励电子甲醇的生产和使用来减少碳排放。 政府的举措正在推动市场成长，并透过引入再生能源项目、促进清洁燃料技术的研发以及製定有利的电子甲醇使用法规来转向更清洁和更永续的燃料来源。

本报告调查了全球电子甲醇市场，提供了市场定义和概述、市场规模趋势和预测、各个细分市场和地区的详细分析、行业结构以及影响市场成长的因素分析、案例研究、竞争格局。

目录

第一章研究方法

第 2 章专案范围与定义

第 3 章执行摘要

第四章全球电子甲醇市场展望

• 市场规模/预测
• 依能源来源
  • 太阳
  • 水电
  • 风力发电
  • 其他
• 应用
  • 化工原料
  • 船舶燃料
  • 发电
  • 其他
• 依地区
  • 北美
  • 欧洲
  • 亚太地区
  • 南美洲
  • 中东/非洲
• 各公司的市占率

第五章全球电子甲醇市场展望：依地区

• 北美
• 欧洲
• 亚太地区
• 南美洲
• 中东/非洲

第 6 章市场映射

• 依能源来源
• 依用途
• 依地区

第七章宏观环境与产业结构

• 需求与供给分析
• 汇入/汇出分析
• 价值链分析
• PESTEL 分析
• 波特五力分析

第 8 章市场动态

• 生长促进因素
• 抑製成长的因素（课题与限制）

第九章主要公司状况

• 前 5 名市场领导者的竞争矩阵
• 前 5 位市场领导者的市场收入分析
• 併购/合资企业（如果适用）
• SWOT 分析（5 家参与公司）
• 专利分析（如果适用）

第10章价格分析

第 11 章案例研究

第十二章主要公司展望

• Orsted A/S
• European Energy A/S
• Topsoe A/S
• Henan Shuncheng Group
• Elyse Energy
• Siemens Energy AG
• BASF SE
• Tractebel Engineering GmbH
• Carbon Recycling International
• Uniper SE

第 13 章策略建议

第14章关于我们公司/免责声明

The global e-methanol market is projected to witness a CAGR of 26.65% during the forecast period 2024-2031, growing from USD 231.10 million in 2023 to USD 1,518.77 million in 2031. The ongoing technological advancements and increased government support have ramped up e-methanol production facilities. The cost of hydrogen and carbon dioxide sources significantly regulate the production cost of e-methanol, which usually ranges between USD 800-2400/ton, depending on the process for carbon dioxide. For instance, the first commenced plant in Iceland utilizes renewable hydrogen and carbon dioxide from a geothermal plant to produce E-methanol.

E-methanol caters to a myriad number of advantages, such as its adaptability as a liquid fuel that can be readily stored and transported at room temperature at normal pressures, unlike hydrogen or LNG. E-methanol produced from renewable sources, such as biomass or green hydrogen, helps reduce carbon emissions, thereby making it a greener alternative to conventional fuels. The market drivers include the need to scale production, increasing demand for renewable and sustainable fuel, increasing integration of e-methanol in chemical feedstocks, rise in competition for feedstock, legislative assistance, a profound increase in demand rate, and economic viability. These qualities underline e-methanol's promise as a long-term and diverse fuel choice in the transition to greener energy.

The rate of demand for e-methanol is rising exponentially. The expanding environmental concerns and the continuous need for sustainable fuels have raised the requirement for e-methanol. Moreover, the growing demand for electric cars, as well as the necessity for sustainable energy sources to replace old fossil fuels in a variety of sectors, are driving the market growth. In April 2023, Methanex, the world's largest methanol producer, estimated that worldwide methanol demand will represent an increase of more than 14 million mt over the following five years. This development trajectory is supported by a gradual shift to renewable methanol. On the other hand, the International Renewable Energy Agency (IRENA) also stated that it expects an expected annual output of 250 million mt of e-methanol by 2050.

Increasing Demand for Renewable and Sustainable Fuel is Expediting the Market Growth

The continuous rise in the necessity of renewable and sustainable fuel in numerous industries, such as transportation, chemical production, and power generation, has increased the demand for e-methanol at an exponential rate worldwide. The progress of renewable energy technology, which allows for efficient manufacturing by water electrolysis utilizing sources like wind, solar, and hydroelectric power, is accelerating the expansion of e-methanol. This green fuel functions as a versatile energy carrier, promoting grid stability, energy security, and the shift to a circular economy.

For instance, in November 2023, SunGas Renewables announced that it had been selected by ABEL Energy, an Australian green hydrogen and ethanol project developer, to supply green methanol for a new USD 1.4 billion plant in Northern Tasmania. The ABEL Energy Bell Bay Power Fuels Project is intended to produce 300,000 tons of green methanol annually. This amount is 3 times Australia's current methanol usage and the shipping fuel equivalent of reducing 540,000 tons of CO2 from the environment each year.

Increasing Integration of E-Methanol in Chemical Feedstocks is Augmenting Market Expansion

The rising use of e-methanol in chemical feedstocks is having a substantial influence on the e-methanol business. This integration is being pushed by an increase in demand for green carbon feedstocks across the sectors. The move to e-methanol synthesis from CO2 and e-hydrogen is gaining traction, particularly in applications, such as chemical manufacturing, maritime and aircraft transportation, and methanol derivative generation.

For example, in January 2024, BASF Process Catalysts, a leading developer of innovative catalyst technology, announced a new collaboration with Envision Energy. The partnership intended to improve the conversion of green hydrogen and CO2 into e-methanol using an innovative, dynamic process architecture. With their respective skills, the two businesses are planning to optimize the process of manufacturing e-methanol from green hydrogen and CO2, opening the way for a more sustainable energy future. BASF will deliver SYNSPIRE catalyst technology that Envision Energy will incorporate into its energy management system.

Government Initiatives are Fuelling the Market Growth

Government measures are vital in accelerating the expansion of the e-methanol market. The collaboration of government entities with organizations aim to promote sustainable energy sources, while lowering carbon emissions by encouraging the production and use of e-methanol. The government initiatives are driving market growth and facilitating a shift towards cleaner and more sustainable fuel sources by introducing renewable energy projects, promoting research and development in clean fuel technologies, and establishing regulations that favour the use of e-methanol.

For instance, in December 2023, Idemitsu Kosan Co.Ltd. collaborated with Hydrologic Instrumentation Facility (HIF) USA to launch an e-methanol company, with a prominent emphasis on CO2 and renewable hydrogen fuel generation. This program intends to construct an e-methanol supply chain, expedite research on foreign procurement, develop maritime fuel uses, and boost Japanese e-fuel and synthetic chemical manufacturing to achieve a carbon-neutral society by 2050.

Europe Dominates the Market

Several factors have contributed to Europe's dominance in the e-methanol business. Firstly, the region's thriving chemical sector, especially in Germany, foresees the promise of green methanol as a sustainable feedstock, which drives innovation and sustainable practices. Secondly, Europe has launched considerable governmental steps to decarbonize marine transportation, promoting the use of green methanol. Furthermore, the continuous rising need for green fuels and chemicals in Europe is a significant driver of the e-methanol industry, with some firms looking at methanol as a decarbonization fuel.

For instance, in July 2023, P1 Fuels and Carbon Recycling International jointly agreed to provide an e-methanol manufacturing unit to Germany. This cooperation combines CRI's Emissions-to-Liquids technology with P1's methanol-to-gasoline technology to provide cost-effective e-fuels for internal combustion engine cars. The agreement, announced at COP28, represents a commitment to green technology and sustainable fuel solutions, with plans for a demonstration facility and industrial-scale operations in the future.

Future Market Outlook (2024 - 2031F)

Due to the growing need for e-methanol in industries, such as transportation and chemicals, governments are spending a substantial amount of money for its technological advancements. This trend is expected to provide several market expansion opportunities in the future.

Key industry participants are indulging in various collaborations to enrich the quality of their e-methanol solutions, thereby paving the way for significant long-term development opportunities.

The significant increase in demand for kerosene and gasoline is propelling total market expansion, creating several prospects for future success.

The continued attempts of organizations to reduce carbon emissions have a substantial influence on market growth, with e-methanol providing a 95% decrease in carbon emissions. This environmental focus is projected to lead to significant market growth prospects in the future.

Key Players Landscape and Outlook

Key participants in the e-methanol market include BASF SE., Henan Shuncheng Group, Orsted A/S, and European Energy A/S. The players are collaborating on various projects due to the growing need for e-methanol, the possibility for e-methanol to serve as a hydrogen transport carrier, and its role in facilitating the transition to green hydrogen. Furthermore, the rise in the need for sustainable energy solutions, the expansion of the chemical industry, which requires methanol feedstock, and the desire for cleaner energy alternatives all add to the appeal of e-methanol projects.

In July 2023, European Energy A/S announced that it is building the world's largest CO2-to-green methanol factory in Denmark, with an annual capacity of nearly 32,000 tons. The facility will use Clariant's Megamax catalyst for methanol synthesis, which is noted for its high activity and stability in CO2-to-methanol conversion. This endeavor is consistent with manufacturing green methanol to benefit industries such as marine transportation and chemical manufacturing.

In December 2023, Orsted's FlagshipONE E-Methanol Project gained significant support during COP28, with Breakthrough Energy Catalyst, taking a 15% ownership investment and giving a grant, subject to financial requirements. This support is likely to help Orsted secure long-term offtake agreements, transforming fuel procurement in the marine industry. Orsted expects additional funding from Horizon Europe grants and a quasi-equity investment from the European Investment Bank (EIB) via InvestEU to advance FlagshipONE's technology and scale green fuel production.

Table of Contents

1.Research Methodology

2.Project Scope and Definitions

3.Executive Summary

4.Global e-methanol Market Outlook, 2017-2031F

• 4.1.Market Size and Forecast
  • 4.1.1.By Value
  • 4.1.2.By Volume
• 4.2.By Energy Source
  • 4.2.1. Solar
  • 4.2.2. Hydro
  • 4.2.3. Wind
  • 4.2.4. Others
• 4.3.Application
  • 4.3.1. Chemical Feedstock
    • 4.3.1.1. Formaldehyde
    • 4.3.1.2. Acetic Acid
    • 4.3.1.3. Methyl tert-Butyl Ether (MTBE)
    • 4.3.1.4. Dimethyl Ether (DME)
    • 4.3.1.5. Kerosene
    • 4.3.1.6. Gasoline
    • 4.3.1.7. Solvents
    • 4.3.1.8.Others
  • 4.3.2. Marine Fuel
  • 4.3.3. Power Generation
  • 4.3.4. Others
• 4.4.By Region
  • 4.4.1.North America
  • 4.4.2.Europe
  • 4.4.3.Asia-Pacific
  • 4.4.4.South America
  • 4.4.5.Middle East and Africa
• 4.5.By Company Market Share (%), 2023

5.Global e-methanol Market Outlook, By Region, 2017-2031F

• 5.1.North America*
  • 5.1.1.Market Size and Forecast
    • 5.1.1.1.By Value
    • 5.1.1.2.By Volume
  • 5.1.2.By Energy Source
    • 5.1.2.1.Solar
    • 5.1.2.2.Hydro
    • 5.1.2.3.Wind
    • 5.1.2.4.Others
  • 5.1.3.By Application
    • 5.1.3.1.Chemical Feedstock
    • 5.1.3.1.1.Formaldehyde
    • 5.1.3.1.2.Acetic Acid
    • 5.1.3.1.3.Methyl tert-Butyl Ether (MTBE)
    • 5.1.3.1.4.Dimethyl Ether (DME)
    • 5.1.3.1.5.Kerosene
    • 5.1.3.1.6.Gasoline
    • 5.1.3.1.7.Solvents
    • 5.1.3.1.8.Others
    • 5.1.3.2.Marine Fuel
    • 5.1.3.3.Power Generation
    • 5.1.3.4.Others
  • 5.1.4.United States*
    • 5.1.4.1.Market Size and Forecast
    • 5.1.4.1.1. By Value
    • 5.1.4.1.2. By Volume
    • 5.1.4.2.By Energy Source
    • 5.1.4.2.1.Solar
    • 5.1.4.2.2.Hydro
    • 5.1.4.2.3.Wind
    • 5.1.4.2.4.Others
    • 5.1.4.3. By Application
    • 5.1.4.3.1.Chemical Feedstock
    • 5.1.4.3.1.1.Formaldehyde
    • 5.1.4.3.1.2.Acetic Acid
    • 5.1.4.3.1.3.Methyl tert-Butyl Ether (MTBE)
    • 5.1.4.3.1.4.Dimethyl Ether (DME)
    • 5.1.4.3.1.5.Kerosene
    • 5.1.4.3.1.6.Gasoline
    • 5.1.4.3.1.7.Solvents
    • 5.1.4.3.1.8.Others
    • 5.1.4.3.2.Marine Fuel
    • 5.1.4.3.3.Power Generation
    • 5.1.4.3.4.Others
  • 5.1.5.Canada
  • 5.1.6.Mexico

All segments will be provided for all regions and countries covered

• 5.2.Europe
  • 5.2.1.Germany
  • 5.2.2.France
  • 5.2.3.Italy
  • 5.2.4.United Kingdom
  • 5.2.5.Russia
  • 5.2.6.Netherlands
  • 5.2.7.Spain
  • 5.2.8.Turkey
  • 5.2.9.Poland
• 5.3.Asia-Pacific
  • 5.3.1.India
  • 5.3.2.China
  • 5.3.3.Japan
  • 5.3.4.Australia
  • 5.3.5.Vietnam
  • 5.3.6.South Korea
  • 5.3.7.Indonesia
  • 5.3.8.Philippines
• 5.4.South America
  • 5.4.1.Brazil
  • 5.4.2.Argentina
• 5.5.Middle East and Africa
  • 5.5.1.Saudi Arabia
  • 5.5.2.UAE
  • 5.5.3.South Africa

6.Market Mapping, 2023

• 6.1.By Energy Source
• 6.2.By Application
• 6.3.By Region

7.Macro Environment and Industry Structure

• 7.1.Demand Supply Analysis
• 7.2.Import Export Analysis
• 7.3.Value Chain Analysis
• 7.4.PESTEL Analysis
  • 7.4.1.Political Factors
  • 7.4.2.Economic System
  • 7.4.3.Social Implications
  • 7.4.4.Technological Advancements
  • 7.4.5.Environmental Impacts
  • 7.4.6.Legal Compliances and Regulatory Policies (Statutory Bodies Included)
• 7.5.Porter's Five Forces Analysis
  • 7.5.1.Supplier Power
  • 7.5.2.Buyer Power
  • 7.5.3.Substitution Threat
  • 7.5.4.Threat from New Entrant
  • 7.5.5.Competitive Rivalry

8.Market Dynamics

• 8.1.Growth Drivers
• 8.2.Growth Inhibitors (Challenges and Restraints)

9.Key Players Landscape

• 9.1.Competition Matrix of Top Five Market Leaders
• 9.2.Market Revenue Analysis of Top Five Market Leaders (in %, 2023)
• 9.3.Mergers and Acquisitions/Joint Ventures (If Applicable)
• 9.4.SWOT Analysis (For Five Market Players)
• 9.5.Patent Analysis (If Applicable)

10.Pricing Analysis

11.Case Studies

12.Key Players Outlook

• 12.1.Orsted A/S
  • 12.1.1.Company Details
  • 12.1.2.Key Management Personnel
  • 12.1.3.Products and Services
  • 12.1.4.Financials (As reported)
  • 12.1.5.Key Market Focus and Geographical Presence
  • 12.1.6.Recent Developments
• 12.2.European Energy A/S
• 12.3.Topsoe A/S
• 12.4.Henan Shuncheng Group
• 12.5.Elyse Energy
• 12.6.Siemens Energy AG
• 12.7.BASF SE
• 12.8.Tractebel Engineering GmbH
• 12.9.Carbon Recycling International
• 12.10.Uniper SE

Companies mentioned above DO NOT hold any order as per market share and can be changed as per information available during research work.

13.Strategic Recommendations

14.About Us and Disclaimer

List of Tables

• Table 01: Global E-methanol Market Size, By Energy Source, By Value, In USD Million, 2020-2031F
• Table 02: Global E-methanol Market Size, By Application, By Value, In USD Million, 2020-2031F
• Table 03: Global E-methanol Market Size, By Chemical Feedstock Su

List of Figures

• Figure 01: Respondents, By Region
• Figure 02: Respondents, By Application
• Figure 03: Respondents, By Company Size
• Figure 04: Purchase Decision Factors, By Characteristics of Solutions (%)
• Figure 05: Purchase Decision Factors, By Feedstock Capacity (%)
• Figure 06: Purchase Decision Factors, By Production Capacity (%)
• Figure 07: Purchase Decision Factors, By Technology Usage (%)
• Figure 08: Global E-methanol Market, By Value, In USD Million, 2020-2031F
• Figure 09: Global E-methanol Market, By Volume, In Kilotons, 2020-2031F
• Figure 10: North America E-methanol Market, By Value, In USD Million, 2020-2031F
• Figure 11: North America E-methanol Market, By Volume, In Kilotons, 2020-2031F
• Figure 12: Europe E-methanol Market, By Value, In USD Million, 2020-2031F
• Figure 13: Europe E-methanol Market, By Volume, In Kilotons, 2020-2031F
• Figure 14: South America E-methanol Market, By Value, In USD Million, 2020-2031F
• Figure 15: South America E-methanol Market, By Volume, In Kilotons, 2020-2031F
• Figure 16: Asia-Pacific E-methanol Market, By Value, In USD Million, 2020-2031F
• Figure 17: Asia-Pacific E-methanol Market, By Volume, In Kilotons, 2020-2031F
• Figure 18: Middle East and Africa E-methanol Market, By Value, In USD Million, 2020-2031F
• Figure 19: Middle East and Africa E-methanol Market, By Volume, In Million Tons, 2020-2031F
• Figure 20: By Energy Source Map-Market Size (USD Million) & Growth Rate (%), 2023
• Figure 21: By Application Map-Market Size (USD Million) & Growth Rate (%), 2023
• Figure 22: By Application (Chemical Feedstocks) Map-Market Size (USD Million) & Growth Rate (%), 2023
• Figure 23: By Region Map-Market Size (USD Million) & Growth Rate (%), 2023
• Figure 24: Market Share of Top Five Companies (In %, 2022)
• Figure 25: Number of Patents Issued (2021-2024)
• Figure 26: Number of Patents Issued by Country/Region (2021-2024)
• Figure 27: Number of Patents Assigned, by Company (2021-2024)
• Figure 28: Average Price of E-methanol in USD Per kg (2020-2031)
• Figure 29: BASF SE- Financials
• Figure 30: BASF SE Segmental Shares of Revenue
• Figure 31: BASF SE Regional Shares of Revenue

figure 32: Tractebel Engineering GMBH - Financials

figure 33: Tractebel Engineering GMBH Segmental Shares of Revenue

figure 34: Tractebel Engineering GMBH Regional Shares of Revenue

• Figure 35: UNIPER SE - Financials
• Figure 36: UNIPER SE- Segmental Shares of Revenue
• Figure 37: UNIPER SE- Regional Shares of Revenue
• Figure 38: Hydropower Electricity Capacity, Global, (GW), (2022-2027*)