量子コンピューティング市場レポート：動向、予測、競合分析 (2031年まで)

世界の量子コンピューティング市場の将来は、最適化、シミュレーション、機械学習アプリケーションにおける機会で有望視されています。世界の量子コンピューティング市場は、2025年から2031年までのCAGRが36.8%で、2031年までに推定106億米ドルに達すると予想されています。この市場の主な促進要因は、高性能コンピューティングに対するニーズの高まりと、様々な産業からの量子コンピューティングソリューションに対する需要の高まりです。

• Lucintelの予測によると、デプロイメントカテゴリーでは、クラウドはその柔軟性と強力なシステムにより、ユーザー間での利用が増加しているため、予測期間中に高い成長が見込まれます。
• アプリケーション・カテゴリーでは、量子アルゴリズムが問題を最適化し、より迅速かつ効率的に解決するために使用されるようになっているため、最適化が最大のセグメントであり続けると予測しています。
• 地域別では、防衛、医療、製薬、エネルギー・電力などさまざまな分野で量子コンピューティングが広く応用されていることから、予測期間中もAPACが最大地域であり続けると思われます。

量子コンピューティング市場の戦略的成長機会

量子コンピューティング市場には、さまざまな応用分野にまたがる戦略的成長機会がいくつか存在します。量子技術の進歩に伴い、成長と進化が必要な分野が数多く存在します。これらのギャップに対処することは、市場を拡大するだけでなく、量子コンピューティングの可能性を実現することにもつながります。

• 最適化とサプライチェーン管理：量子コンピューティングの利用は、最適化とサプライチェーンマネジメントにおける戦略的成長機会をもたらします。量子アルゴリズムは、経路計画や在庫管理といった複雑な最適化タスクを効率的に解くことができ、古典的な手法を凌駕します。様々な業界の多くの企業が、サプライチェーンを改善し、損失を削減するために量子コンピューティングを利用しています。ロジスティクスの最適化に量子技術を応用することで、より優れた効率を生み出し、市場競争を強化し、この分野の成長を促進することができます。
• 創薬と材料科学：量子コンピューティングは、医薬品開発と材料科学に変革をもたらす可能性があります。量子コンピュータは分子間の相互作用や化学反応のシミュレーションを可能にし、新薬や新素材の開発を促進します。製薬会社や研究機関は、創薬の改善やより優れた材料の設計のために量子コンピューティングを導入しています。量子テクノロジーは科学技術の進歩の機会を生み出すため、この分野は大きな成長の可能性を秘めています。
• 金融サービスとリスク分析：金融サービス分野では、特にリスク分析や金融モデリングなどの分野で量子コンピューティングの恩恵が期待されています。量子アルゴリズムは、膨大な量のデータを処理し、複雑な計算を従来の方法よりも効率的に行うことができます。その他のアプリケーションとしては、ポートフォリオの最適化、リスク評価、不正検知などがあります。金融セクターは競争力を高め、意思決定を改善するために量子コンピューティングを模索しており、このビジネス分野における成長機会を生み出しています。
• 暗号とデータ・セキュリティ：量子コンピューティングは、暗号とデータ・セキュリティの分野に課題と機会の両方をもたらします。量子テクノロジーは、現在の暗号化手法を陳腐化させることが予想される一方で、量子技術を利用した攻撃に耐性を持ち、データを安全に暗号化する新たな方法を提供します。その結果、組織や政府は機密情報を保護するため、量子セキュア暗号に投資しています。量子通信と暗号化の研究開発、そして新たなセキュリティ課題への応用は、大きな成長機会となります。
• 人工知能と機械学習：量子コンピューティングと人工知能（AI）および機械学習（ML）の融合は、大きな成長の可能性を秘めています。量子アルゴリズムはAIやML技術を強化し、データ処理やパターン認識を向上させることができます。各組織は、トレーニングモデルのパフォーマンスやアルゴリズムの最適化など、量子コンピューティングが機械学習にどのような影響を与えるかを研究しています。この分野には大きな成長の可能性があり、量子コンピューティングとAI技術の開発を促進すると思われます。

量子コンピューティング市場における戦略的成長機会は、最適化、医薬品開拓、金融サービス、暗号技術、AIを網羅し、量子技術の多様な応用を浮き彫りにしています。このような機会があれば、機関や企業はイノベーションを起こし、能力を強化し、拡大する量子コンピューティング市場から利益を得ることができます。

量子コンピューティング市場促進要因・課題

量子コンピューティング市場は、その拡大と進化を形作る様々な促進要因・課題の影響を受けています。これらの要因には、新興技術、各地域の経済環境、業界を管理する規制などが含まれます。量子コンピューティング市場とそのダイナミクスを評価するには、これらの促進要因・課題を理解することが不可欠です。

量子コンピューティング市場を牽引する要因は以下の通りである：

• 量子ハードウェアの技術進歩：量子ハードウェアの技術進歩：量子ビットのコヒーレンスやエラー率におけるブレークスルーを含む量子ハードウェアの技術進歩は、量子コンピューティング市場の重要な促進要因です。これらの改良により、量子コンピュータはより高い信頼性、拡張性、性能で動作するようになり、市場の成長につながります。
• より優れた計算能力への需要の高まり：複雑な問題に対処するため、より優れた計算能力への需要が高まっています。量子コンピューティングは、製薬、航空宇宙、ロジスティクスなどの産業における問題解決策を提示し、その普及を後押ししています。産業界がその能力を高める方法を模索する中、量子コンピューティングの需要は高まり続けています。
• 政府の資金援助と支援の増加：量子研究開発に対する政府の資金援助と支援は、量子コンピューティング市場の成長を促進する重要な要因です。米国の国家量子イニシアティブ法やEUの量子フラッグシップ・プログラムなどのイニシアチブは、量子技術の開発を加速するための財政的支援とリソースを提供しています。

一方、量子コンピューティング市場が直面する課題には以下のようなものがある：

• 高いコストとインフラ要件：量子コンピューティング技術の開発には、研究開発への多額の投資と高額なインフラの構築が必要です。量子コンピューティング・システムの構築や、極低温チャンバーなどの必要な設備の維持にかかる費用は、同市場における課題となっています。
• 量子アルゴリズムの複雑さ：量子アルゴリズムは依然として複雑な研究分野であり、多くのアルゴリズムがまだ開発の初期段階にあります。既存のアルゴリズムの多くは商業利用には限界があるため、より効率的でスケーラブルな量子アルゴリズムが求められています。このことは、量子コンピューティングを普及させるという点で、市場に課題を提示しています。
• 人材不足：熟練した人材の不足も、量子コンピューティング業界が直面する重要な課題です。量子システムやアルゴリズムの開発には高度に専門的な知識が必要であり、この分野で熟練した専門家の需要が高まっています。この人材不足は、量子コンピューティング産業の発展を遅らせ、成長を制限する可能性があります。

量子コンピューティング市場の促進要因としては、技術の進歩、計算能力に対する需要の増加、政府の支援などが挙げられます。しかし、市場が潜在能力をフルに発揮するためには、高コスト、複雑性、人材不足といった課題を克服しなければならないです。量子コンピューティングが継続的に発展し、産業界に広く普及するためには、これらの課題に対処することが不可欠です。

目次

第1章 エグゼクティブサマリー

第2章 世界の量子コンピューティング市場：市場力学

• イントロダクション、背景、分類
• サプライチェーン
• 業界の促進要因と課題

第3章 2019年から2031年までの市場動向と予測分析

• マクロ経済動向（2019-2024年）と予測（2025-2031年）
• 世界の量子コンピューティング市場の動向（2019～2024年）と予測（2025～2031年）
• 導入別世界量子コンピューティング市場
  • オンプレミス
  • クラウド
• 技術別世界量子コンピューティング市場
  • 閉じ込められたイオン
  • 量子アニーリング
  • 超伝導量子ビット
  • その他
• 用途別世界量子コンピューティング市場
  • 最適化
  • シミュレーション
  • 機械学習
  • その他
• 最終用途別世界量子コンピューティング市場
  • 宇宙と防衛
  • 運輸・物流
  • ヘルスケア・医薬品
  • 化学薬品
  • 銀行・金融
  • エネルギーと電力
  • 学術界
  • 政府
  • その他

第4章 2019年から2031年までの地域別市場動向と予測分析

• 地域別世界量子コンピューティング市場
• 北米の量子コンピューティング市場
• 欧州の量子コンピューティング市場
• アジア太平洋量子コンピューティング市場
• その他地域量子コンピューティング市場

第5章 競合分析

• 製品ポートフォリオ分析
• 運用統合
• ポーターのファイブフォース分析

第6章 成長機会と戦略分析

• 成長機会分析
  • 世界の量子コンピューティング市場における展開別の成長機会
  • 技術別世界の量子コンピューティング市場の成長機会
  • 用途別の世界の量子コンピューティング市場の成長機会
  • エンドユーザー別の世界の量子コンピューティング市場の成長機会
  • 地域別の世界の量子コンピューティング市場の成長機会
• 世界の量子コンピューティング市場の新たな動向
• 戦略分析
  • 新製品開発
  • 世界の量子コンピューティング市場の容量拡大
  • 世界の量子コンピューティング市場における合併、買収、合弁事業
  • 認証とライセンシング

第7章 主要企業の企業プロファイル

• IBM
• D-Wave Quantum
• Microsoft
• Amazon Web Services
• Rigetti Computing
• Fujitsu
• Hitachi

The future of the global quantum computing market looks promising with opportunities in the optimization, simulation, and machine learning applications. The global quantum computing market is expected to reach an estimated $10.6 billion by 2031 with a CAGR of 36.8% from 2025 to 2031. The major drivers for this market are the growing need for high-performance computing and the rising demand for quantum computing solutions from various industries.

• Lucintel forecasts that, within the deployment category, the cloud is expected to witness higher growth over the forecast period due to its increasing usage among users, owing to its flexibility and powerful systems.
• Within the application category, optimization will remain the largest segment due to the growing use of quantum algorithms to optimize problems and solve them in a faster and more efficient manner.
• In terms of regions, APAC will remain the largest region over the forecast period due to the widespread applications of quantum computing across various sectors, such as defense, medical care, pharmaceuticals, and energy & power in the region.

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Emerging Trends in the Quantum Computing Market

The market of quantum computing is undergoing a number of trends that reflect advancements in technology and changing market dynamics that can be regarded as emergent. These trends impact both how quantum computing is made and applied, resulting in enhanced and new innovations and investments. Understanding these trends indicates the general direction in which the quantum computing industry will develop and identifies the opportunities and constraints that will influence market growth.

• More Investment and Funding: Growth in expenditure and funding is propelling the quantum computing market. Extensive quantum research and development has been initiated by both governments and private companies, as well as venture capitalists. For example, the National Quantum Initiative Act of the U.S. government and the large amounts of money the Chinese government allocates for research in quantum computing are clear indications of this trend. Investments are geared toward improving quantum hardware, software, and algorithms, thus speeding up the development of usable quantum computing systems and applications. This trend enhances the development and establishment of infrastructure and human capital for quantum computing, which consequently boosts innovation and market competitiveness.
• Quantum Hardware Development at a Glance: Quantum hardware development is one of the essential developments in the quantum computing market. The qubit technologies, including superconducting qubits and trapped ions, are aiding the enhancement and expansion capabilities of quantum computers. IBM and Google are also making improvements in qubit coherence and error correction that have resulted in the development of never-before-seen quantum hardware. These improvements are essential in the quest for bigger and more powerful quantum systems that contribute to the vision of practical applications for quantum computing, as well as improving the quantum technology landscape.
• Quantum Algorithms Evolution: The evolution of quantum algorithms is one of the major trends concerning the development of the quantum computing market. New efficient algorithms targeting problems that cannot be solved efficiently with classical computers are being developed. Some of these include quantum algorithms for optimization, cryptography, and simulation. Algorithm development focuses on the potential of quantum computing to provide solutions to some of the biggest challenges in the modern world for both companies and research institutions. As such, this trend is critical in facilitating the everyday use of quantum computing technologies in most sectors.
• Interfacing Quantum Computing with AI and Machine Learning: Hybrid approaches that combine quantum computing and machine learning or artificial intelligence (AI) are also starting to gain traction in the industry. AI and ML models, in particular, could be improved with the help of quantum algorithms by introducing novel methods for data and pattern analysis. The purpose of this integration is to make use of quantum computing power in a more effective and concentrated manner in AI and ML applications. Organizations are exploring how these same properties of quantum computing can be utilized in speeding up certain machine learning processes or fine-tuning AI algorithms, thus contributing to the progress of these technologies.
• Emergence of Quantum Communication and Security: An increasing emphasis on quantum communication and security is evident in the trends of quantum computing technology. There are initiatives toward developing quantum key distribution (QKD) and quantum encryption methods, which aim to ensure data protection and anonymity. Quantum communication technology development has become a strategic national security interest for countries like China and companies such as IBM, which seek to safeguard sensitive data from quantum-enabled intrusion. This trend indicates that the secure and reliable exchange of information is an issue of concern, and quantum technology is the solution to the problem of cybersecurity.

In the quantum computing market, trends such as increased investment, development of quantum hardware, advancement of quantum algorithms, integration with artificial intelligence, and major concerns regarding quantum communication and security are redefining the market. These trends spur development and offer new avenues for quantum computing usage, which, in turn, will impact the policies and strategies for the market's growth and development.

Recent Developments in the Quantum Computing Market

The quantum computing market has been an area of notable development over the past few years as more business and non-business stakeholders have continued to invest in the technology, reflecting both the investments made and the developments achieved. These developments are changing the world as far as quantum computing is concerned. Some of the main developments are those related to hardware, software, and application improvements that are leading to growth in the field of quantum technology.

• The Quantum System One by IBM: One of the notable developments in quantum computing hardware is IBM's Quantum System One. This one-piece computer encases superconducting qubits and includes the latest cryogenic capabilities for quantum computing. This milestone represents an important step in the commercialization of quantum computers. The subsequent upgrades and modifications of IBM's quantum systems are pushing the limits of quantum computing performance and dependability, raising expectations for the market's development.
• Google Attains an Achievement in Quantum Supremacy: Google's achievement of quantum supremacy, made possible with its Sycamore processor, is a breakthrough in the realm of quantum computing. This milestone marks the introduction of quantum computing systems that surpass classical computing in terms of capabilities. Google's ongoing research and development in this field aim to improve quantum computers and explore their potential applications, thus propelling the market forward.
• China's Satellite for Quantum Communication: China's establishment of Micius, the first satellite for quantum communication, represents a revolution in the field of quantum communication. Micius has achieved quantum key distribution (QKD) over long distances, connecting satellites with ground stations. This achievement illustrates China's position as a leading nation in the field of quantum communication and highlights the potential of quantum technologies to enhance data security. Micius's success paves the way for further developments in communication networks based on quantum technologies.
• European Initiatives in Quantum Computing: Europe has made significant progress in quantum computing by sponsoring and participating in various activities and cooperation programs. The European Union's Quantum Flagship program, launched in 2018, aims to promote activities related to quantum technology research and development. Additionally, intra-European collaborations, such as the partnership between IBM and the Fraunhofer Society, are advancing innovations in quantum hardware and software. These initiatives aim to make Europe a key player in the rapidly growing quantum computing market.
• National Quantum Mission of India: The National Quantum Mission of India, launched in 2020, is a mission-oriented program focused on promoting quantum research. The mission seeks to establish a quantum computing ecosystem that includes quantum hardware, computational algorithms, and applications. Major players such as the Indian Institute of Science (IISc) and the National Institute of Technology (NIT) are also involved in this mission. As India develops its quantum research capabilities and forms collaborations with other countries, it is positioning itself as a key player in this field.

Recent developments in the quantum computing market encompass significant milestones in technology and research, such as IBM's Quantum System One, Google's quantum supremacy breakthrough, China's quantum communication satellite, European efforts, and the National Quantum Mission of India. These developments are pushing the field forward, opening new horizons, and shaping the future of quantum computing.

Strategic Growth Opportunities for Quantum Computing Market

There are several strategic growth opportunities within the quantum computing market across various application areas. As quantum technology advances, there are numerous areas for growth and evolution. Addressing these gaps will not only help expand the market but also help realize the potential of quantum computing.

• Optimization and Supply Chain Management: The use of quantum computing presents a strategic growth opportunity in optimization and supply chain management. Quantum algorithms can efficiently solve complex optimization tasks, such as route planning and inventory control, surpassing classical techniques. Many companies in various industries are using quantum computing to improve their supply chains and reduce losses. The application of quantum technology to optimize logistics can produce better efficiencies and enhance market competition, driving growth in this sector.
• Drug Discovery and Materials Science: Quantum computing can have a transformative impact on drug development and materials science. Quantum computations allow simulations of molecular interactions and chemical reactions, facilitating the development of novel drugs or materials. Pharmaceutical companies and research institutions are adopting quantum computing to improve drug discovery and design better materials. This area holds significant growth potential, as quantum technology creates opportunities for advances in science and technology.
• Financial Services and Risk Analysis: The financial services sector is expected to benefit from quantum computing, particularly in areas such as risk analysis and financial modeling. Quantum algorithms can process vast amounts of data and perform complex calculations more efficiently than traditional methods. Other applications include portfolio optimization, risk assessment, and fraud detection. The financial sector is exploring quantum computing to gain a competitive edge and improve decision-making, creating opportunities for growth in this business area.
• Cryptography and Data Security: Quantum computing poses both challenges and opportunities in the fields of cryptography and data security. Quantum technology is expected to render current encryption methods obsolete, but it also offers new ways to encrypt data securely, resistant to quantum-enabled attacks. As a result, organizations and governments are investing in quantum-secure encryption to protect sensitive information. Research and development in quantum communication and encryption, and its application to emerging security challenges, represent significant growth opportunities.
• Artificial Intelligence and Machine Learning: The fusion of quantum computing with artificial intelligence (AI) and machine learning (ML) presents enormous growth potential. Quantum algorithms can enhance AI and ML techniques, improving data processing and pattern recognition. Organizations are exploring how quantum computing can impact machine learning, including training model performance and algorithm optimization. This area has significant growth potential, which will drive the development of quantum computing and AI technologies.

Strategic growth opportunities in the quantum computing market, encompassing optimization, drug development, financial services, cryptography, and AI, highlight the diverse applications of quantum technology. With these opportunities, institutions and companies can innovate, enhance their capabilities, and position themselves to benefit from the expanding quantum computing market.

Quantum Computing Market Driver and Challenges

The quantum computing market is influenced by a range of drivers and challenges that shape its expansion and evolution. These factors include emerging technologies, the economic environment of different regions, and the regulations governing the industry. Understanding these drivers and challenges is essential for assessing the quantum computing market and its dynamics.

The factors driving the quantum computing market include:

• Technological Advancement of Quantum Hardware: Technological advances in quantum hardware, including breakthroughs in qubit coherence and error rates, are significant drivers of the quantum computing market. These improvements enable quantum computers to operate with higher reliability, scalability, and performance, leading to market growth.
• Increasing Demand for Better Computational Power: There is a growing demand for better computational power to address complex problems. Quantum computing presents a solution to problems in industries such as pharmaceuticals, aerospace, and logistics, thus driving its adoption. As industries look for ways to enhance their capabilities, the demand for quantum computing continues to rise.
• Increased Government Funding and Support: Government funding and support for quantum research and development are critical drivers of growth in the quantum computing market. Initiatives such as the National Quantum Initiative Act in the United States and the EU Quantum Flagship Program provide financial backing and resources to accelerate the development of quantum technologies.

On the other hand, challenges facing the quantum computing market include:

• High Costs and Infrastructure Requirements: The development of quantum computing technology requires substantial investment in research and development, along with the establishment of costly infrastructure. The expense of building quantum computing systems and maintaining the required equipment, such as cryogenic chambers, represents a challenge in the market.
• Complexity of Quantum Algorithms: Quantum algorithms remain a complex area of research, with many algorithms still in the early stages of development. There is a need for more efficient and scalable quantum algorithms, as many existing algorithms are too limited for commercial use. This presents a challenge for the market in terms of making quantum computing viable for widespread applications.
• Talent Shortage: A shortage of skilled talent is another key challenge facing the quantum computing industry. Developing quantum systems and algorithms requires highly specialized knowledge, and there is a growing demand for skilled professionals in the field. This talent shortage could slow the progress of the quantum computing industry and limit its growth.

The drivers of the quantum computing market include technological advances, increasing demand for computational power, and governmental support. However, challenges such as high costs, complexity, and talent shortages must be overcome for the market to reach its full potential. Addressing these challenges will be essential for the continued development of quantum computing and its wide adoption across industries.

List of Quantum Computing Companies

Companies in the market compete on the basis of product quality offered. Major players in this market focus on expanding their manufacturing facilities, R&D investments, infrastructural development, and leverage integration opportunities across the value chain. With these strategies quantum computing companies cater increasing demand, ensure competitive effectiveness, develop innovative products & technologies, reduce production costs, and expand their customer base. Some of the quantum computing companies profiled in this report include-

• IBM
• D-Wave Quantum
• Microsoft
• Amazon Web Services
• Rigetti Computing
• Fujitsu
• Hitachi

Quantum Computing by Segment

The study includes a forecast for the global quantum computing market by deployment, technology, application, end use, and region.

Quantum Computing Market by Deployment [Analysis by Value from 2019 to 2031]:

• On-Premises
• Cloud

Quantum Computing Market by Technology [Analysis by Value from 2019 to 2031]:

• Trapped Ions
• Quantum Annealing
• Superconducting Qubits
• Others

Quantum Computing Market by Application [Analysis by Value from 2019 to 2031]:

• Optimization
• Simulation
• Machine Learning
• Others

Quantum Computing Market by End Use [Analysis by Value from 2019 to 2031]:

• Space & Defense
• Transportation & Logistics
• Healthcare & Pharmaceuticals
• Chemicals
• Banking & Finance
• Energy & Power
• Academia
• Government
• Others

Quantum Computing Market by Region [Analysis by Value from 2019 to 2031]:

• North America
• Europe
• Asia Pacific
• The Rest of the World

Country Wise Outlook for the Quantum Computing Market

The quantum computing market has seen significant activity due to domestic investments, government research and development, technological progress, and growing interest from both the public and private sectors. Quantum computing holds the promise of solving many problems across various industries that traditional computational methods cannot address. However, as the United States, China, Germany, India, and Japan explore the frontiers of quantum technology, each is making unique contributions to this rapidly changing industry. These developments are not only influencing the future of computing but also shaping national policies and international relations.

• US: The United States remains far ahead of other countries in the field of quantum computing, due to substantial government and private sector support. Companies such as IBM, Google, and Microsoft continue to develop their quantum technologies. IBM's Quantum System One, the first commercial quantum computer in the world, is being improved, while Google's Sycamore processor has achieved quantum supremacy by performing tasks that classical computers cannot accomplish. Furthermore, the U.S. government has pledged significant funding for quantum science under initiatives like the National Quantum Initiative Act to help build quantum infrastructure and capacity.
• China: China has made significant strides in quantum computing technology, supported by funding and continuous backing from the government and other organizations. The 13th Five-Year Plan of the Chinese government allocates substantial funds to quantum research, and private companies such as Alibaba and Baidu are advancing world-class technologies. Alibaba's DAMO Academy has developed a 9-qubit quantum processor, while Baidu's Quantum Computing Institute focuses on quantum algorithms and hardware development. Additionally, China has achieved notable successes in quantum communication and quantum key distribution, positioning itself as a leader and key competitor in the quantum computing arena.
• Germany: Germany is also making substantial progress in quantum computing, particularly on the empirical side. Major organizations involved in quantum research include the Max Planck Institute and the Fraunhofer Society. Notably, IBM and the German company IQM are collaborating to develop superconducting processing units, which are essential for quantum computation. Germany's emphasis also extends to building a quantum computing ecosystem that integrates basic science, industry, and support from the national government. The country is also advancing in communication-based quantum technologies and developing quantum-enhanced sensors, which are expected to further strengthen its position in the quantum computing field.
• India: India is rapidly growing in the quantum computing market, driven by various government and institutional efforts. The National Mission on Quantum Technologies and Applications is a key initiative aimed at promoting quantum technologies and applications in India. Institutions such as the Indian Institute of Science (IISc) and the National Institute of Technology (NIT) are actively engaged in research on quantum algorithms and hardware development. Cryptography and materials science are also part of India's focus on developing quantum computational technologies. Increased cooperation between Indian institutions and foreign organizations is positioning India as a strong player in the global quantum computing race.
• Japan: Japan has made significant progress and investment in quantum computing, with both government and corporate involvement. Major companies such as NEC and Toshiba are developing quantum technologies, with specific focuses on superconducting qubits for NEC and quantum key derivation for Toshiba. Additionally, the Japanese government has outlined plans to encourage the development of quantum sciences, including providing resources for public-private partnerships. Japan's strategy also seeks to extend the scope of quantum computing to applications in Artificial Intelligence, secure communication, and solving optimization problems, to become a key player in the global quantum computing market.

Features of the Global Quantum Computing Market

Market Size Estimates: Quantum computing market size estimation in terms of value ($B).

Trend and Forecast Analysis: Market trends (2019 to 2024) and forecast (2025 to 2031) by various segments and regions.

Segmentation Analysis: Quantum computing market size by various segments, such as by deployment, technology, application, end use, and region in terms of value ($B).

Regional Analysis: Quantum computing market breakdown by North America, Europe, Asia Pacific, and Rest of the World.

Growth Opportunities: Analysis of growth opportunities in different deployments, technologies, applications, end uses, and regions for the quantum computing market.

Strategic Analysis: This includes M&A, new product development, and competitive landscape of the quantum computing market.

Analysis of competitive intensity of the industry based on Porter's Five Forces model.

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This report answers following 11 key questions:

• Q.1. What are some of the most promising, high-growth opportunities for the quantum computing market by deployment (on-premises and cloud), technology (trapped ions, quantum annealing, superconducting qubits, and others), application (optimization, simulation, machine learning, and others), end use (space & defense, transportation & logistics, healthcare & pharmaceuticals, chemicals, banking & finance, energy & power, academia, government, and others), and region (North America, Europe, Asia Pacific, and the Rest of the World)?
• Q.2. Which segments will grow at a faster pace and why?
• Q.3. Which region will grow at a faster pace and why?
• Q.4. What are the key factors affecting market dynamics? What are the key challenges and business risks in this market?
• Q.5. What are the business risks and competitive threats in this market?
• Q.6. What are the emerging trends in this market and the reasons behind them?
• Q.7. What are some of the changing demands of customers in the market?
• Q.8. What are the new developments in the market? Which companies are leading these developments?
• Q.9. Who are the major players in this market? What strategic initiatives are key players pursuing for business growth?
• Q.10. What are some of the competing products in this market and how big of a threat do they pose for loss of market share by material or product substitution?
• Q.11. What M&A activity has occurred in the last 5 years and what has its impact been on the industry?

Table of Contents

1. Executive Summary

2. Global Quantum Computing Market : Market Dynamics

• 2.1: Introduction, Background, and Classifications
• 2.2: Supply Chain
• 2.3: Industry Drivers and Challenges

3. Market Trends and Forecast Analysis from 2019 to 2031

• 3.1. Macroeconomic Trends (2019-2024) and Forecast (2025-2031)
• 3.2. Global Quantum Computing Market Trends (2019-2024) and Forecast (2025-2031)
• 3.3: Global Quantum Computing Market by Deployment
  • 3.3.1: On-Premises
  • 3.3.2: Cloud
• 3.4: Global Quantum Computing Market by Technology
  • 3.4.1: Trapped Ions
  • 3.4.2: Quantum Annealing
  • 3.4.3: Superconducting Qubits
  • 3.4.4: Others
• 3.5: Global Quantum Computing Market by Application
  • 3.5.1: Optimization
  • 3.5.2: Simulation
  • 3.5.3: Machine Learning
  • 3.5.4: Others
• 3.6: Global Quantum Computing Market by End Use
  • 3.6.1: Space & Defense
  • 3.6.2: Transportation & Logistics
  • 3.6.3: Healthcare & Pharmaceuticals
  • 3.6.4: Chemicals
  • 3.6.5: Banking & Finance
  • 3.6.6: Energy & Power
  • 3.6.7: Academia
  • 3.6.8: Government
  • 3.6.9: Others

4. Market Trends and Forecast Analysis by Region from 2019 to 2031

• 4.1: Global Quantum Computing Market by Region
• 4.2: North American Quantum Computing Market
  • 4.2.1: North American Market by Deployment: On-Premises and Cloud
  • 4.2.2: North American Market by Application: Optimization, Simulation, Machine Learning, and Others
• 4.3: European Quantum Computing Market
  • 4.3.1: European Market by Deployment: On-Premises and Cloud
  • 4.3.2: European Market by Application: Optimization, Simulation, Machine Learning, and Others
• 4.4: APAC Quantum Computing Market
  • 4.4.1: APAC Market by Deployment: On-Premises and Cloud
  • 4.4.2: APAC Market by Application: Optimization, Simulation, Machine Learning, and Others
• 4.5: ROW Quantum Computing Market
  • 4.5.1: ROW Market by Deployment: On-Premises and Cloud
  • 4.5.2: ROW Market by Application: Optimization, Simulation, Machine Learning, and Others

5. Competitor Analysis

• 5.1: Product Portfolio Analysis
• 5.2: Operational Integration
• 5.3: Porter's Five Forces Analysis

6. Growth Opportunities and Strategic Analysis

• 6.1: Growth Opportunity Analysis
  • 6.1.1: Growth Opportunities for the Global Quantum Computing Market by Deployment
  • 6.1.2: Growth Opportunities for the Global Quantum Computing Market by Technology
  • 6.1.3: Growth Opportunities for the Global Quantum Computing Market by Application
  • 6.1.4: Growth Opportunities for the Global Quantum Computing Market by End Use
  • 6.1.5: Growth Opportunities for the Global Quantum Computing Market by Region
• 6.2: Emerging Trends in the Global Quantum Computing Market
• 6.3: Strategic Analysis
  • 6.3.1: New Product Development
  • 6.3.2: Capacity Expansion of the Global Quantum Computing Market
  • 6.3.3: Mergers, Acquisitions, and Joint Ventures in the Global Quantum Computing Market
  • 6.3.4: Certification and Licensing

7. Company Profiles of Leading Players

• 7.1: IBM
• 7.2: D-Wave Quantum
• 7.3: Microsoft
• 7.4: Amazon Web Services
• 7.5: Rigetti Computing
• 7.6: Fujitsu
• 7.7: Hitachi