フッ化水素の市場規模：用途別、エンドユーザー産業別、地域別、2024年～2031年

フッ化水素市場の評価、2024年～2031年

フッ化水素（HF）の需要は、様々な産業用途におけるその重要性から増加しています。フッ化水素の主な用途は、冷凍、空調、焦げ付きにくい調理器具の製造に必要なフルオロカーボンやフルオロポリマーの合成で、その市場は大幅に拡大しています。さらに、半導体分野では、電子機器の絶え間ない進歩と普及のため、エッチングと洗浄工程にフッ化水素が広く利用されています。ハイテク用途でのフッ化水素への依存の高まりは、2023年に28億8,000万米ドルの売上高を突破し、2031年には約43億1,000万米ドルの評価額に達することを可能にし、その重要性を強調しています。

さらに、フッ化水素は石油精製、特に高オクタン価ガソリンを生産するアルキル化プロセスにおいて不可欠です。世界のエネルギー需要の増加に伴い、製油所は操業を拡大し、フッ化水素の使用量を増やしています。製薬業界も、多くの治療に不可欠なフッ素系化学物質を生成するため、HFの恩恵を受けています。これらの異なる用途が融合した結果、フッ化水素市場の需要は増加しており、2024年から2031年までのフッ化水素市場のCAGRは5.1%で成長する見込みです。

フッ化水素市場の定義/概要

フッ化水素は化学式HFで表される無色の腐食性気体または液体です。水に溶解するとフッ化水素酸と呼ばれる水溶液を形成します。ガラスを含む多くのマテリアルを溶解する可能性があるため、フッ化水素は非常に反応性が高く、取り扱いには注意が必要です。

フッ化水素は多くの分野で幅広い用途があります。化学工業では、冷凍、空調、焦げ付きにくい調理器具の製造に使用されるフルオロカーボンやフルオロポリマーを含む多くの重要な化合物の重要な前駆体です。半導体産業では、シリコンウエハーの洗浄やエッチングにHFが多用されています。HFは石油精製、特に高オクタン価ガソリンを製造するアルキル化プロセスでも重要な役割を果たしています。製薬業界では、最新の医薬品に必要なさまざまなフッ素化有機分子を合成するためにHFが使用されています。

フッ化水素の将来の見通しは、その中核的用途と革新的技術に対する需要の高まりから明るいです。エレクトロニクス・セクターの拡大、特に半導体製造の進歩は、フッ化水素の需要を高め続けると思われます。さらに、より環境に優しいエネルギーと、より効率的な燃料生産の推進により、石油精製への需要が継続します。医薬品と材料科学の革新、特にフッ素化新薬品の開発は、フッ化水素の世界市場における重要性をさらに高めると思われます。

半導体産業の急成長はフッ化水素市場をどう牽引するか？

成長する半導体産業は、フッ化水素世界市場の主要促進要因です。フッ化水素は、半導体や電子部品の製造に欠かせないエッチング・洗浄剤です。韓国、台湾、中国などのアジア太平洋諸国は半導体製造の主要拠点です。この地域の市場力学はフッ化水素の世界的需要に大きく寄与しており、この地域の製造力と技術進歩が実証されています。

アジア太平洋に加えて、高度な技術部門を持つ米国と欧州の一部でも、フッ化水素に対する強いニーズがあります。家電、通信、情報技術セクターの著しい台頭は、半導体の需要を増大させました。この急増は高純度フッ化水素の需要を即座に押し上げます。これらの分野は、技術革新を支えるフッ化水素の重要な役割を浮き彫りにし、業界を前進させ続けています。

技術の向上と先端電子機器への需要の高まりが市場拡大の原動力となっています。より小型で効率的な半導体チップには、非常に純粋なフッ化水素が必要です。半導体デバイスが高度化・小型化するにつれて、精密かつ効率的な製造手順への要求が高まり、フッ化水素の重要性がさらに高まっています。この動向は、半導体産業におけるフッ化水素の重要性の高まりと、将来の技術進歩におけるフッ化水素の重要な役割を強調しています。

環境・衛生規制はフッ化水素市場をどのように阻害するか？

環境・衛生法はフッ化水素市場を大きく制限し、市場力学と利害関係者の意思決定に影響を与えます。高い毒性と腐食性で知られるフッ化水素は、呼吸障害、皮膚の火傷、極端な場合には死に至るなど、環境と健康に重大な危険をもたらします。こうした危険を軽減するため、フッ化水素はその製造、取り扱い、貯蔵、輸送、廃棄を規定する厳しい規制の対象となります。

これらの規制の厳しさと影響は地域によって異なります。欧州連合（EU）と北米は、フッ化水素を含む危険化合物の取り扱いに関して極めて厳格な規則を定めています。これらの地域では、フッ化水素メーカーにとって市場参入や拡大の障壁となりうる環境要件への厳格な遵守が求められます。厳格な基準は、安全設備、訓練、コンプライアンス手法への大規模な投資を必要とし、運営経費を上昇させる可能性があります。

これとは対照的に、規制がそれほど厳しくない新興国市場の一部では、フッ化水素に関連する危険性は依然として懸念事項であるが、市場への規制の影響は小さいかもしれないです。しかし、公衆衛生と環境を保護するための厳しい要件を含むフッ化水素に関する広範な規制状況は、製造業者と供給業者の経営コストを引き上げています。こうした規則を遵守するためには、安全基準や廃棄システムに大規模な投資を行う必要があり、フッ化水素のコストを引き上げ、その結果、市場価格と需要に影響を与えます。

目次

第1章 イントロダクション

• 市場の定義
• 市場セグメンテーション
• 調査手法

第2章 エグゼクティブサマリー

• 主な調査結果
• 市場概要
• 市場ハイライト

第3章 市場概要

• 市場規模と成長の可能性
• 市場動向
• 市場促進要因
• 市場抑制要因
• 市場機会
• ポーターのファイブフォース分析

第4章 フッ化水素市場：用途別

• 工業用フッ化水素
• 電子グレードのフッ化水素
• フルオロカーボン製造
• フッ素誘導体製造
• アルミニウム製造

第5章 フッ化水素市場：最終用途産業別

• 化学産業
• 電子・半導体産業
• 自動車産業
• 医薬品産業
• 航空宇宙産業

第6章 地域分析

• 北米
• 米国
• カナダ
• メキシコ
• 欧州
• 英国
• ドイツ
• フランス
• イタリア
• アジア太平洋
• 中国
• 日本
• インド
• オーストラリア
• ラテンアメリカ
• ブラジル
• アルゼンチン
• チリ
• 中東・アフリカ
• 南アフリカ
• サウジアラビア
• アラブ首長国連邦

第7章 市場力学

• 市場促進要因
• 市場抑制要因
• 市場機会
• COVID-19の市場への影響

第8章 競合情勢

• 主要企業
• 市場シェア分析

第9章 企業プロファイル

• Arkema SA
• Solvay SA
• Honeywell International Inc.
• Chemours Company
• Ineos Group Ltd.
• Dongyue Group Corporation
• Jiangsu Aiju Chemical Co. Ltd.
• Xinhecheng Co. Ltd.
• Shandong Dongyue Group Co. Ltd.
• Everlon Fluoroproducts Ltd.

第10章 市場の展望と機会

• 新興技術
• 今後の市場動向
• 投資機会

第11章 付録

• 略語リスト
• 出典と参考文献

Hydrogen Fluoride Market Valuation - 2024-2031

The demand for hydrogen fluoride (HF) is increasing due to its critical significance in a variety of industrial applications. Its principal application in the synthesis of fluorocarbons and fluoropolymers which are required for refrigeration, air conditioning and the creation of nonstick cookware has considerably expanded its market. Furthermore, the semiconductor sector relies extensively on hydrogen fluoride for etching and cleaning processes owing to the continuous advancement and proliferation of electronic devices. The growing reliance on HF for high-tech applications emphasizes its importance by enabling the market to surpass a revenue of USD 2.88 Billion valued in 2023 and reach a valuation of around USD 4.31 Billion by 2031.

Furthermore, hydrogen fluoride is essential in petroleum refining, particularly in the alkylation process that yields high-octane gasoline. As global energy demands rise, refineries ramp up operations increasing HF usage. The pharmaceutical industry also benefits from HF because it generates fluorinated chemicals which are essential for many treatments. As a result of the convergence of these different uses, the market's demand for hydrogen fluoride is increasing by enabling the market to grow at aCAGR of 5.1% from 2024 to 2031.

Hydrogen Fluoride Market Definition/ Overview

Hydrogen fluoride is a colorless, corrosive gas or liquid with the chemical formula HF. When dissolved in water, it forms an aqueous solution called hydrofluoric acid. Because of its potential to dissolve numerous materials including glass, HF is very reactive and should be handled with caution.

Hydrogen fluoride has a wide range of uses in many sectors. In the chemical industry, it is a significant precursor to many important compounds including fluorocarbons and fluoropolymers which are used in refrigeration, air conditioning and nonstick cookware manufacturing. The semiconductor industry extensively uses HF to clean and etch silicon wafers. HF also plays an important role in petroleum refining particularly in the alkylation process that produces high-octane gasoline. In the pharmaceutical industry, HF is used to synthesize a variety of fluorinated organic molecules required for modern pharmaceuticals.

Hydrogen fluoride's future prospects look positive because of rising demand for its core applications and innovative technologies. The electronics sector's expansion particularly advancements in semiconductor fabrication will continue to raise demand for HF. Furthermore, the push for greener energy and more efficient fuel production will continue to demand petroleum refining. Pharmaceutical and materials science innovations, notably the development of new fluorinated chemicals will further add to hydrogen fluoride's growing importance in the global market.

How Will Rapid Growth in the Semiconductor Industry Drive the Hydrogen Fluoride Market?

The growing semiconductor industry is a major driver of the worldwide hydrogen fluoride market. Hydrogen fluoride is a vital etching and cleaning agent used in the production of semiconductors and electronic components. Asia-Pacific countries such as South Korea, Taiwan and China are major semiconductor manufacturing hubs. This regional market dynamic significantly contributes to worldwide demand for hydrogen fluoride demonstrating the region's manufacturing strength and technical progress.

In addition to the Asia-Pacific, the United States and parts of Europe with their advanced technological sectors have a strong need for hydrogen fluoride. The tremendous rise of the consumer electronics, telecommunications and information technology sectors has increased the demand for semiconductors. This surge immediately boosts demand for high-purity hydrogen fluoride particularly in countries with a strong electronics manufacturing base. These areas continue to propel the industry ahead highlighting the compound's important role in sustaining technological innovation.

Technological improvements and rising demand for advanced electronic devices drive market expansion. Smaller and more efficient semiconductor chips require very pure hydrogen fluoride. As semiconductor devices become more sophisticated and smaller, the demand for precise and efficient production procedures increases making hydrogen fluoride even more important. This trend emphasizes the compound's growing importance in the semiconductor industry and its critical role in future technological advances.

How Will Environmental and Health Regulations Hamper the Hydrogen Fluoride Market?

Environmental and health laws greatly limit the hydrogen fluoride market affecting market dynamics and stakeholder decisions. Recognized for its high toxicity and corrosive nature, HF causes significant environmental and health dangers including breathing problems, skin burns and even death in extreme circumstances. To mitigate these dangers, hydrogen fluoride is subject to severe regulations around the world which govern its manufacture, handling, storage, transportation and disposal.

The severity and impact of these rules vary by geography. The European Union and North America have extremely rigorous rules regarding the handling of hazardous compounds including HF. These regions require strict compliance with environmental requirements which might be a barrier to market entry or expansion for hydrogen fluoride producers. The strict standards require large investments in safety equipment, training and compliance methods which can raise operational expenses.

In contrast, in some developing areas with less severe regulations, the hazards associated with HF remain a concern but the regulatory impact on the market may be smaller. However, the broad regulatory landscape for hydrogen fluoride which includes severe requirements to protect public health and the environment raises operational costs for producers and suppliers. Compliance with these rules necessitates major investment in safety standards and disposal systems raising the cost of hydrogen fluoride and hence influencing its market price and demand.

Category-Wise Acumens

How Will the Widespread Use of Fluorocarbon-Based Refrigerants Drive the Application Segment?

Fluorocarbon production is the dominant application in the hydrogen fluoride market. The majority of hydrogen fluoride demand comes from fluorocarbons which are used in refrigeration, air conditioning and foam insulation as blowing agents. This sector's dominance is due to the widespread use of fluorocarbon-based refrigerants and their importance in modern cooling technology.

Fluorocarbons are essential for the production of hydrofluorocarbons (HFCs) and hydrofluoroolefins (HFOs) which are frequently used as alternatives to ozone-depleting compounds such as chlorofluorocarbons (CFCs) and hydrochlorofluorocarbons (HCFCs). The switch to more ecologically friendly options has increased demand for hydrogen fluoride. The global push for energy efficiency and environmental sustainability drives the use of fluorocarbons ensuring HF's continued rise in this application.

Furthermore, strict regulatory regimes targeting greenhouse gas emissions have sped the transition to HFOs which have a lower global warming potential (GWP) than their predecessors. This regulatory structure encourages innovation and growth in the fluorocarbons business reinforcing hydrogen fluoride's dominant position. As businesses prioritize environmentally friendly refrigerants and insulating materials, demand for HF in fluorocarbon manufacturing is projected to stay strong cementing its market dominance.

Will the Critical Role in the Production of Diverse Chemical Substances Drive the End-Use Industry Segment?

The chemical industry is the market's dominant end-use sector for hydrogen fluoride. This sector consumes the most HF due to its critical role in the production of a diverse range of chemical substances including fluorocarbons, fluoropolymers and fluorinated derivatives. These chemicals are crucial in a variety of applications including refrigeration and air conditioning, nonstick cookware and pharmaceuticals resulting in a high demand for hydrogen fluoride.

Fluorocarbons, including hydrofluorocarbons (HFCs) and hydrofluoroolefins (HFOs) are widely used in the chemical industry to produce refrigerants and insulating foams. The transition to ecologically friendly refrigerants with lower global warming potential (GWP) has boosted demand for HF. Furthermore, fluoropolymers made from hydrogen fluoride are essential for developing high-performance materials with remarkable chemical resistance and stability which are widely employed in industrial and consumer applications.

The chemical industry's broad and diverse applications maintain a consistent need for hydrogen fluoride. Regulatory requirements to minimize ozone-depleting chemicals and greenhouse gas emissions have spurred advances in HF-based chemical processes. As industries around the world focus on sustainability and efficiency, the chemical sector's reliance on hydrogen fluoride to produce key compounds cements its position as the dominant end-use industry in the HF market.

Country/Region-wise Acumens

How Will the Rapid Growth of Chemical Industries Across the Region Drive the Market in Asia Pacific?

Asia Pacific dominates the global hydrogen fluoride market due to significant growth in its chemical industries. The regions booming consumer goods sectors such as electronics and automobiles are driving demand for fluorine chemicals. These chemicals are required for metal extraction, metallurgical uses and the manufacture of a variety of consumer products reflecting Asia Pacific's rapid industrialization.

China, a major player in the region, is the world's largest producer of acid-grade fluorspar, the principal raw material for anhydrous hydrogen fluoride manufacturing. The abundance of this raw material supports the region's dominant position in the hydrogen fluoride market. Furthermore, the increased demand for fluorine compounds which are used in industrial applications such as refrigeration, air conditioning and the production of fluoropolymers and fluorogases strengthens Asia Pacific's market leadership.

China's substantial fluorspar mining operations have helped it emerge as a major refrigerant maker. This has resulted in an increase in refrigeration and air-conditioning equipment production driven by low-cost feedstocks. These characteristics together with solid industrial expansion, abundant raw material availability and expanding demand across a wide range of industrial applications lead to Asia Pacific's prominent position in the worldwide hydrogen fluoride market.

Will the Region's Advanced Technology Sectors Boost the North American Region?

North America is the fastest-growing market for hydrogen fluoride. This expansion is mostly driven by the region's advanced technology sectors such as electronics, semiconductors and medicines. The growing need for high-purity hydrogen fluoride in these industries which is required for etching and cleaning semiconductor wafers and synthesizing fluorinated medicinal chemicals highlights the market's growth.

The chemical industry's recovery in North America particularly in the United States significantly increases the need for hydrogen fluoride. The region's significant emphasis on research and development encourages innovation in chemical processes and materials science which drives the demand for HF. Furthermore, the North American automotive industry which focuses on production and technological improvements drives the market. The creation of lightweight materials and high-performance polymers based on HF is particularly significant.

Furthermore, strict environmental restrictions in North America which aim to minimize greenhouse gas emissions and encourage sustainable practices have resulted in a greater use of hydrogen fluoride in the production of eco-friendly refrigerants and other fluorinated chemicals. This legislative push for greener alternatives fuels the region's rapid market expansion establishing North America as a prominent and rapidly expanding player in the worldwide hydrogen fluoride market.

Competitive Landscape

The Hydrogen Fluoride Market is a dynamic and competitive space, characterized by a diverse range of players vying for market share. These players are on the run for solidifying their presence through the adoption of strategic plans such as collaborations, mergers, acquisitions and political support. The organizations focus on innovating their product line to serve the vast population in diverse regions.

Some of the prominent players operating in the hydrogen fluoride market include:

Arkema SA

Solvay SA

Honeywell International Inc.

Chemours Company

Ineos Group Ltd.

Dongyue Group Corporation

Jiangsu Aiju Chemical Co. Ltd.

Xinhecheng Co. Ltd.

Shandong Dongyue Group Co. Ltd.

Everlon Fluoroproducts Ltd.

Latest Developments

In April 2021, EcoGraf has announced the acquisition of a contract to develop a battery anode materials factory for spherical graphite production. Importantly, this facility is located outside of China and uses an environmentally benign alternative to typical hydrofluoric acid purification methods.

In April 2021, Renascor Resources investigated green financing options for its Savior Battery Anode Material Project in South Australia. This project aims to facilitate the production of materials for electric vehicle manufacturing facilities by utilizing vertical integration methodologies.

TABLE OF CONTENTS

1. Introduction

• Market Definition
• Market Segmentation
• Research Methodology

2. Executive Summary

• Key Findings
• Market Overview
• Market Highlights

3. Market Overview

• Market Size and Growth Potential
• Market Trends
• Market Drivers
• Market Restraints
• Market Opportunities
• Porter's Five Forces Analysis

4. Hydrogen Fluoride Market, By Application

• Industrial Hydrogen Fluoride
• Electronic Grade Hydrogen Fluoride
• Fluorocarbons Production
• Fluorinated Derivatives Manufacturing
• Aluminum Production

5. Hydrogen Fluoride Market, By End-Use Industry

• Chemical Industry
• Electronics and Semiconductor Industry
• Automotive Industry
• Pharmaceutical Industry
• Aerospace Industry

6. Regional Analysis

• North America
• United States
• Canada
• Mexico
• Europe
• United Kingdom
• Germany
• France
• Italy
• Asia-Pacific
• China
• Japan
• India
• Australia
• Latin America
• Brazil
• Argentina
• Chile
• Middle East and Africa
• South Africa
• Saudi Arabia
• UAE

7. Market Dynamics

• Market Drivers
• Market Restraints
• Market Opportunities
• Impact of COVID-19 on the Market

8. Competitive Landscape

• Key Players
• Market Share Analysis

9. Company Profiles

• Arkema SA
• Solvay SA
• Honeywell International Inc.
• Chemours Company
• Ineos Group Ltd.
• Dongyue Group Corporation
• Jiangsu Aiju Chemical Co. Ltd.
• Xinhecheng Co. Ltd.
• Shandong Dongyue Group Co. Ltd.
• Everlon Fluoroproducts Ltd.

10. Market Outlook and Opportunities

• Emerging Technologies
• Future Market Trends
• Investment Opportunities

11. Appendix

• List of Abbreviations
• Sources and References