绿色氨：价值创造和技术增长机会

随着减少生产工厂温室气体排放和减少对天然气进口依赖的需求日益增加，氨製造商正在推广采用绿色氨技术。

本报告对全球绿色氨市场进行研究和分析，并提供有关战略基本要求、增长机会分析、区域趋势和技术发展计划的信息。

目录

战略要求

• 推动绿色氨市场增长的战略要点 8 (TM)
• 战略要点 8 (TM)
• 三大战略要求对绿色合成氨行业的影响
• 增长机会推动增长管道引擎 (TM)
• 调查方法

分析范围和主要发现

• 调查目标和范围
• 主要调查结果

增长机会分析

• 世界氨生产概况
• 世界氨生产概况-讨论
• 对绿色氢气的绿色氨需求
• 利用清洁能源为绿色氨创造价值
• 为绿色氨创造价值的机会
• 化肥、化学品和燃料已被确定为绿色氨创造价值的主要机会领域。

增长机会分析-绿色氨作为燃料

• 为不同行业的绿色氨作为燃料创造价值
• 绿色氨气转化为燃料的关键技术
• 绿色氨燃烧技术提供了一种气候友好型替代燃料，可替代传统的石油或天然气燃料。
• 高能效正在推动用于海洋应用的绿色氨燃料电池技术的发展。
• 绿色氨分解技术可实现氢燃料的大规模生产。
• 交通领域各种燃料的物理属性比较
• 适用于绿色氨的燃料电池技术对比分析
• Green Ammonia 提供了一种气候友好型替代燃料，可替代传统的船用燃料。
• 影响采用绿色氨作为燃料的主要因素

成长机会分析-绿氨肥

• 为化肥行业的绿色氨创造价值
• 绿色氨转化为肥料的重要技术
• 绿色尿素生产比传统尿素生产排放更少的温室气体。
• 加强环境安全相关法规将促进采用绿色氨生产硝酸铵。
• 绿色磷酸铵克服了与土壤缺磷和水污染相关的挑战。
• 提出对因碱性土壤导致耕作失败的担忧支持施用硫酸铵。
• 尿素生产主要工艺对比
• 影响采用绿色氨作肥料的主要因素

成长机会分析-绿氨作为化工原料

• 以绿色氨作为化工原料创造价值
• 绿色氨转化为化工中间体的关键技术
• 为化工中间体联氨创造绿色氨的价值
• 为化工中间体苯胺创造绿色氨的价值
• 为化工中间体苯□创造绿色氨的价值
• 为化工中间体羟胺创造绿色氨的价值
• 为化工中间体甲□胺创造绿色氨的价值
• 为化工中间体氨基磺酸创造绿色氨的价值
• 为化工中间体乙□胺创造绿色氨的价值
• 影响采用绿色氨作为化工原料的主要因素

绿色氨生产的区域趋势和技术发展努力

• 绿色氨技术的发展得到了北美强大的工业和大学合作的支持。
• 北美氢氨价值创造行业倡议
• 有利的政府政策和激励措施正在支持亚太地区绿色氨技术的发展。
• 亚太地区氢制氨价值创造行业倡议
• 欧洲的目标是到 2050 年发展使用可再生能源的低碳肥料和船用燃料生产。
• 在欧洲利用氢气为氨创造价值的行业倡议
• 大量的公共和私营部门投资正在推动中东和非洲绿色氨技术的发展。
• 为中东和非洲的氢制氨创造价值的行业倡议
• 积极的脱碳目标推动了拉丁美洲的绿色氨技术发展。
• 拉丁美洲利用氢气创造氨价值的行业倡议
• 研究机构对氢到氨的价值转换的贡献
• 公共资金主要用于氨生产。
• 私人资金专注于开发有助于将氨作为船用燃料创造价值的技术。
• 用氢气生产氨的行业倡议

增长机会宇宙

• 增长机会一：绿色氨生产商与可再生能源公司结成战略联盟，共同开发新技术和扩大生产
• 增长机会2：新型绿色氨储运基础设施建设
• 增长机会 3：小规模绿色氨生产与远程可再生能源相结合
• 增长机会4：电化学和化学迴路工艺的整合绿色合成氨

附录

下一步

The Valorization of Green Ammonia Aids the Development of Sustainable Fertilizers, Chemicals, and Fuels.

Green ammonia is used to manufacture agricultural products, refrigerants, explosives, dyes, fuels, textiles, industrial chemicals, and pharmaceuticals. The growing need to decrease greenhouse gas emissions from production plants and reduce dependency on natural gas imports is driving green ammonia technology adoption among ammonia manufacturers.

Rising concerns about the environmental impact of conventional ammonia production and the implementation of zero-carbon policies by governments across the world are encouraging advancements in ammonia manufacturing from clean energy sources. The valorization of green ammonia from renewable energy sources can pave the way for the manufacture of safer agricultural products, act as an alternative to fossil fuels, and offer cleaner industrial chemical manufacturing.

Globally, about 80% of the ammonia produced is used as fertilizers for agricultural production due to ammonia's high nitrogen content. However, the conventional Haber-Bosch process of ammonia production is an energy-intensive process that releases a high amount of greenhouse gases. Owing to its zero-carbon content, green ammonia can be used to manufacture clean fertilizers and facilitate sustainable farming. The use of technology can substantially decarbonize refineries and the production of fertilizers. Green ammonia can be integrated into existing facilities involved in small-scale renewable generation for the production of urea, ammonium sulfate, ammonium phosphate, and ammonium nitrate.

Ammonia is used to produce key chemicals, including hydrazine, phenylhydrazine, hydroxylamine, aniline, formamide, sulfamic acid, and acetamide, which are used as intermediates in dyes, agrochemicals, pharmaceuticals, textiles, leather, paper, and plastic. Carbon dioxide emissions from high-value chemical production are expected to exceed 230 million metric tons by 2025. The replacement of conventional fossil fuel-based ammonia with renewable-based green ammonia holds massive potential to substantially decrease carbon emissions; however, significant developments are required to scale up existing green ammonia technologies to meet the growing demand from end-use industries.

Green ammonia holds a promising application outlook as a carbon-free fuel alternative due to its high hydrogen content. Higher energy density, lower ignition temperature, and ease of storage and transport when compared to other fuels drive the adoption of new valorization technologies to convert green ammonia into fuel. The marine sector accounts for approximately 14% of nitrogen and 5% of sulfur releases from all fuel combustion sources. Increasingly stringent marine regulations to limit emissions from marine diesel engines are driving technological advancements in proton exchange membrane fuel cells, alkaline fuel cells, and solid oxide fuel cells to power marine engines.

This Frost & Sullivan research service identifies and analyzes technology advancements focused on cost-effective and highly efficient production technologies; it examines the commercialization landscape of valorization technologies, the major application markets, and the potential application landscape. The technological advancements captured are dedicated to the valorization of green ammonia from hydrogen for fertilizers, chemical intermediates, and marine fuel. The study provides insight into the key focus areas of the technologies, their challenges, and adoption strategies for better utility.

Frost & Sullivan has identified key areas of technology development for green ammonia and categorized them into different domains, as follows:

• 1) Production methods, including hybrid plasma electrocatalytic processes, ionic liquid-based electrolytic technologies, mobile systems for on-site production, ceramic-based button-size reverse fuel cells, the green Haber-Bosch process, photochemical green ammonia synthesis, and chemical looping

• 2) Valorization technologies to convert green ammonia to chemical intermediates, including the Pechiney-Ugine-Kuhlmann process, direct amination or ammonolysis, aniline oxidation, the Raschig process, the carbonylation of ammonia, sulfamation, and the dehydration of ammonium acetate

• 3) Valorization technologies to convert green ammonia to fuels, including thermal and catalytic methods

• 4) Valorization technologies to convert green ammonia to fertilizers.

Ammonia manufacturers have increased R&D investments in the green Haber-Bosch process or decarbonized Haber-Bosch process. Owing to increasingly stringent regulatory guidelines, manufacturers are forming alliances with research universities to adopt sustainable production methods. Factors such as production efficiency, cost, the expansion of the renewable energy sector, and favorable government policies are driving the green ammonia technology landscape.

Key Points Discussed:

• Which emerging technologies support the production of green ammonia?

• What R&D efforts are being taken in terms of new production technologies for improved yield and low energy consumption?

• What are the new trends in green ammonia production technologies and valorization techniques for the conversion of green ammonia to fertilizers, chemical intermediates, and fuel?

• What are the growth opportunities for technology developers in the green ammonia industry?

Table of Contents

Strategic Imperatives

• The Strategic Imperative 8™Factors Creating Pressure on Growth in the Green Ammonia Market
• The Strategic Imperative 8™
• The Impact of the Top 3 Strategic Imperatives on the Green Ammonia Industry
• Growth Opportunities Fuel the Growth Pipeline Engine™
• Research Methodology

Scope of Analysis and Key Findings

• Research Coverage and Scope
• Key Findings

Growth Opportunity Analysis

• Global Ammonia Production Overview
• Global Ammonia Production Overview-Discussion
• Need for Green Ammonia from Green Hydrogen
• Valorization of Green Ammonia from Clean Energy Sources
• Green Ammonia Valorization Opportunities
• Fertilizers, Chemicals, and Fuels have been Identified as Key Opportunity Areas for Green Ammonia Valorization.

Growth Opportunities Analysis -Green Ammonia as Fuel

• Valorization of Green Ammonia as Fuel across Different Sectors
• Key Technologies to Convert Green Ammonia to Fuel
• Green Ammonia Combustion Technology Offers a Climate-friendly Alternative to Conventional Oil or Gas Fuel.
• High Energy Efficiency is Pushing the Development of Fuel Cell Technologies for Green Ammonia in Marine Applications.
• Green Ammonia Cracking Technology is Enabling the Large-scale Production of Hydrogen Fuel.
• Comparison of Physical Attributes of Different Fuels for the Transportation Sector
• Comparative Analysis of Fuel Cell Technologies Applicable for Green Ammonia
• Green Ammonia Offers a Climate-friendly Alternative to Conventional Marine Fuels.
• Key Factors Influencing Green Ammonia Adoption as Fuel

Growth Opportunities Analysis -Green Ammonia as Fertilizer

• Valorization of Green Ammonia in the Fertilizers Industry
• Key Technologies to Convert Green Ammonia into Fertilizers
• Green Urea Production Emits Lesser Greenhouse Gases than Conventional Urea Production.
• Increased Regulations Pertaining to Environmental Safety will Fuel the Adoption of Green Ammonia for Ammonium Nitrate Production.
• Green Ammonium Phosphate will Overcome the Challenges Associated with Soil Phosphorus Shortages and Water Pollution.
• Increasing Concerns Regarding Cultivation Failures due to Alkaline Soil Support the Application of Ammonium Sulfate.
• Comparison of Key Processes for Urea Production
• Key Factors Influencing Green Ammonia Adoption as Fertilizers

Growth Opportunities Analysis -Green Ammonia as Feedstock for Chemicals

• Valorization of Green Ammonia as Feedstock for Chemicals
• Key Technologies to Convert Green Ammonia into Chemical Intermediates
• Valorization of Green Ammonia into Chemical Intermediate Hydrazines
• Valorization of Green Ammonia into Chemical Intermediate Anilines
• Valorization of Green Ammonia into Chemical Intermediate Phenylhydrazines
• Valorization of Green Ammonia into Chemical Intermediate Hydroxylamines
• Valorization of Green Ammonia into Chemical Intermediate Formamides
• Valorization of Green Ammonia into Chemical Intermediate Sulfamic Acids
• Valorization of Green Ammonia into Chemical Intermediate Acetamides
• Key Factors Influencing Green Ammonia Adoption as Feedstock for Chemicals

Regional Trends and Technology Development Efforts for Green Ammonia Generation

• Green Ammonia Technology Development is Supported by Strong Industry and University Collaborations in North America.
• Industry Initiatives for the Valorization of Ammonia from Hydrogen in North America
• Favorable Government Policies and Incentives are Aiding the Development of Green Ammonia Technology in Asia-Pacific
• Industry Initiatives for the Valorization of Ammonia from Hydrogen in Asia-Pacific
• Europe Aims to Develop Low-carbon Fertilizer and Marine Fuel Production using Renewable Energy by 2050.
• Industry Initiatives for the Valorization of Ammonia from Hydrogen in Europe
• Industry Initiatives for the Valorization of Ammonia from Hydrogen in Europe (continued)
• Significant Public and Private Sector Investment is Driving Green Ammonia Technology Development in the Middle East and Africa.
• Industry Initiatives for the Valorization of Ammonia from Hydrogen in the Middle East and Africa
• Industry Initiatives for the Valorization of Ammonia from Hydrogen in the Middle East and Africa (continued)
• Latin America's Green Ammonia Technology Development is Driven by Aggressive Decarbonization Goals.
• Industry Initiatives for the Valorization of Ammonia from Hydrogen in Latin America
• Research Institutes' Contribution to the Valorization of Ammonia from Hydrogen
• Public Funding Focuses on Ammonia Production.
• Public Funding Focuses on Ammonia Production. (continued)
• Private Funding Focuses on the Development of Technologies that Support the Valorization of Ammonia into Marine Fuel.
• Industry Initiatives for Ammonia Generation from Hydrogen

Growth Opportunity Universe

• Growth Opportunity 1: Strategic Collaborations between Green Ammonia Manufacturers and Renewable Power Companies to Develop New Technologies and Scale up Production
• Growth Opportunity 1: Strategic Collaborations between Green Ammonia Manufacturers and Renewable Power Companies to Develop New Technologies and Scale up Production (continued)
• Growth Opportunity 2: Development of New Green Ammonia Storage and Transport Infrastructure
• Growth Opportunity 2: Development of New Green Ammonia Storage and Transport Infrastructure (continued)
• Growth Opportunity 3: Combining Small-scale Green Ammonia Production with Remote Renewable Generation
• Growth Opportunity 3: Combining Small-scale Green Ammonia Production with Remote Renewable Generation (continued)
• Growth Opportunity 4: Integration of Electrochemical and Chemical Looping Processes for Green Ammonia Synthesis
• Growth Opportunity 4: Integration of Electrochemical and Chemical Looping Processes for Green Ammonia Synthesis (continued)

Appendix

• Technology Readiness Levels (TRL): Explanation
• Partial List of Acronyms and Abbreviations Used in the Study

Next Steps

• Your Next Steps
• Why Frost, Why Now?
• Legal Disclaimer