全球量子運算市場規模：按產業、按應用、按量子計算模型、按地區、範圍和預測

量子計算市場規模及預測

2023 年量子計算市場規模為 10.604 億美元，預計到 2030 年將達到 42.513 億美元，在 2024-2030 年預測期間複合年增長率為 19.8%。

量子運算的全球市場推動因素

量子計算市場的市場推動因素可能受到多種因素的影響。

量子技術的發展

量子位元、糾錯方法和量子演算法的發展只是推動量子運算市場的量子技術發展的一部分。隨著科學家和公司致力於開發更穩定的量子位元和更有效的演算法，量子計算的潛在應用和可擴展性正在擴大。

擴大資金和投資

公共機構、企業和風險投資增加的資金和投資正在推動量子計算的研究和開發。這些支出旨在開發硬體和軟體以及建造量子運算基礎設施。

對處理能力的需求不斷增長

機器學習、藥物開發、密碼學和優化等領域的運算問題日益複雜，推動了對更強大運算解決方案的需求。量子電腦處理問題的速度比傳統電腦快 10 倍，這使得它們對於需要大量處理能力的應用程式具有吸引力。

跨產業的能力顛覆

量子電腦具有解決複雜問題和最佳化流程的能力，銀行、醫療保健、物流和材料科學等產業正在探索這一潛力。密碼學是量子運算有可能徹底變革的領域之一，因為正在開發抗量子技術來保護資料免受量子攻擊。

夥伴關係與協作

量子計算研究和開發活動是由政府、產業和學術機構之間的合作所推動的。量子運算生態系統的創新是由科技公司、大學和研究機構之間的合作所推動的。這種夥伴關係有利於資訊交流、人才保留和資源彈性。

改善知識和教育

隨著研究人員、企業和公眾對量子運算的瞭解不斷增加，人們對研究其可能的用途和影響越來越感興趣。我們正在培訓下一代量子科學家和工程師，並透過教育計畫、研討會和會議進一步推進量子運算領域。

全球量子計算市場的阻礙因素

有幾個因素可能會成為量子計算市場的限製或課題。這是一個例子：

技術課題

量子計算面臨的技術課題很多，包括量子位元穩定性、糾錯和可擴展性。這些技術仍處於開發的早期階段。如果需要大量的研究和開發來克服這些障礙，那麼進展可能需要時間。

開發和基礎設施成本

建造和維護量子電腦需要昂貴的設備和專用機械。此外，推進量子電腦技術的研發成本高昂，限制了能夠在該領域競爭的公司數量。

有用的應用有限

量子運算在藥物發現、最佳化和密碼學等多種應用中具有巨大潛力，但許多有用的應用目前仍處於理論階段或處於開發的早期階段。缺乏具體、現實的用例可能會阻礙企業的採用和投資。

缺乏熟練勞動力

量子電腦需要高等數學、電腦科學和量子物理知識。缺乏具備設計、程式設計和操作量子電腦知識的專家可能會阻礙該領域的進展。

環境問題

量子電腦需要非常低的溫度和特定的環境才能運作。維持這些條件所需的冷卻系統和其他基礎設施可能會消耗大量能源，引發人們對擴大量子運算流程對環境影響的擔憂。

安全和隱私課題

量子運算有可能徹底改變網路安全和密碼學，但也存在安全問題。目前的加密標準可能會被量子電腦破壞，使敏感資料和對話容易受到攻擊。

監管和道德問題

隨著量子電腦的發展，其應用將受到新的倫理和監管問題的影響，特別是在國家安全、資料隱私和智慧財產權方面。不明確的道德標準和法律框架可能會阻礙招聘和投資。

目錄

第1章簡介

• 市場定義
• 市場細分
• 調查方法

第 2 章執行摘要

• 主要發現
• 市場概況
• 市集亮點

第3章市場概況

• 市場規模和成長潛力
• 市場趨勢
• 市場驅動力
• 市場制約因素
• 市場機會
• 波特五力分析

第4章量子計算市場：依產業分類

• 金融
• 製藥/醫療保健
• 航空航天與國防
• 能源與公用事業
• IT/通訊

第5章量子計算市場：依應用分類

• 最優化問題
• 人工智慧和機器學習
• 密碼學與安全
• 模擬和建模
• 資料庫和資料管理

第6章 量子計算市場：以量子計算模型

• 通用量子計算機
• 量子退火爐
• 量子模擬器
• 混合量子系統

第7章 區域分析

• 北美
• 美國
• 加拿大
• 墨西哥
• 歐洲
• 英國
• 德國
• 法國
• 義大利
• 亞太地區
• 中國
• 日本
• 印度
• 澳洲
• 拉丁美洲
• 巴西
• 阿根廷
• 智利
• 中東/非洲
• 南非
• 沙烏地阿拉伯
• 阿拉伯聯合酋長國

第8章 競爭格局

• 市場佔有率分析
• 主要策略

第9章 公司簡介

• IBM（US）
• D-Wave Systems Inc.（Canada）
• Microsoft（US）
• Amazon Web Services（US）
• Rigetti Computing（US）
• QC Ware（US）
• Toshiba（Japan）
• Google（US）
• Intel（US）
• Quantinuum（US）

第10章市場前景與機遇

• 新興技術
• 未來市場趨勢
• 投資機會

第11章市場展望附錄

• 縮寫表
• 來源和參考文獻

Quantum Computing Market Size And Forecast

Quantum Computing Market size was valued at USD 1,060.4 Million in 2023 and is projected to reach USD 4,251.3 Million by 2030 , growing at a CAGR of 19.8% during the forecast period 2024-2030.

Global Quantum Computing Market Drivers

The market drivers for the Quantum Computing Market can be influenced by various factors. These may include: Advancements in Quantum Technology

: Improvements in qubits, error correction methods, and quantum algorithms are just a few of the ongoing developments in quantum technology that are propelling the market for quantum computing. The potential uses and scalability of quantum computing grow as scientists and businesses make strides toward creating more stable qubits and effective algorithms.

Growing Funding and Investments

: Research and development in quantum computing is being fueled by rising funding and investments from public and corporate entities as well as venture capitalists. The development of hardware and software as well as the construction of infrastructure for quantum computing are the goals of these expenditures.

Growing Need for Processing Power

: The need for more potent computing solutions is being driven by the growing complexity of computational issues in a variety of domains, including machine learning, drug development, cryptography, and optimization. Applications needing a lot of processing power are drawn to quantum computers because they can potentially handle some problems tenfold quicker than traditional computers.

ability Disruption Across Industries

: Quantum computing has the ability to solve complicated issues and optimize processes, and industries like banking, healthcare, logistics, and materials science are investigating this possibility. Cryptography is one area where quantum computing has the potential to completely transform since quantum-resistant techniques are being developed to protect data from quantum attacks.

Partnerships and Collaborations

: Research and development activities in quantum computing are being expedited by collaborations across government, industry, and academic institutions. Innovation in the quantum computing ecosystem is being propelled by partnerships across technology businesses, universities, and research institutes. These partnerships facilitate information exchange, talent recruiting, and resource pooling.

Increasing Knowledge and Education

: There is a growing interest in investigating the possible uses and ramifications of quantum computing as knowledge of it among researchers, businesses, and the general public rises. The next generation of quantum scientists and engineers are being trained and the field of quantum computing is being furthered through educational programs, workshops, and conferences.

Global Quantum Computing Market Restraints

Several factors can act as restraints or challenges for the Quantum Computing Market. These may include:

Technical Challenges

: The technological challenges facing quantum computing are numerous and include qubit stability, error correction, and scalability. These technologies are still in their early stages of development. It may take longer for advancement to occur if significant research and development is needed to overcome these obstacles.

Cost of Development and Infrastructure

: The construction and upkeep of quantum computers necessitate expensive facilities and specialized machinery. Furthermore, the amount of money required for research and development in order to advance quantum computing technology is significant, which restricts the number of businesses that may compete in this field.

Restricted Useful Applications

: Although quantum computing has enormous potential for some uses, such as drug discovery, optimization, and cryptography, many useful uses are currently theoretical or in the early phases of development. Enterprise adoption and investment may be discouraged by the absence of concrete, real-world use cases.

Absence of Skilled Workers

: Knowledge of sophisticated mathematics, computer science, and quantum physics are necessary for quantum computing. Progress in this subject may be hampered by the existing lack of experts with the know-how to design, program, and run quantum computers.

Environmental Concerns

: In order to function, quantum computers need very low temperatures and certain surroundings. Concerns over the environmental effects of scaling up quantum computing processes are raised by the fact that cooling systems and other infrastructure required to sustain these conditions might consume large amounts of energy.

Challenges with Security and Privacy

: Although quantum computing has great promise for transforming cybersecurity and encryption, there are security concerns associated with it as well. Current encryption standards may be broken by quantum computers, leaving sensitive data and conversations vulnerable.

Regulatory and Ethical Issues

: As quantum computing develops, its application will be subject to new ethical and regulatory issues, especially in relation to national security, data privacy, and intellectual property rights. Uncertainty over ethical standards and legal frameworks could impede adoption and investment.

Global Quantum Computing Market Segmentation Analysis

The Global Quantum Computing Market is Segmented on the basis of Industry Vertical, Application, Model of Quantum Computing, and Geography.

By Industry Vertical

Finance

: For risk analysis, portfolio optimization, and fraud detection, this includes banks, hedge funds, and other financial institutions.

Pharmaceuticals & Healthcare

: For customized medicine, molecular modeling, and drug discovery.

Aerospace & Defense

: Applications such as cryptography, secure communications, and optimization issues are covered under the aerospace and defense domain.

Energy and Utilities

: This includes material simulation for renewable energy, energy storage, and grid optimization.

IT & Telecommunications

: For algorithm development, network optimization, and cybersecurity.

By Application

Optimization Problems

: Logistics, supply chain management, and resource allocation are examples of optimization problems.

AI and machine learning

: For data analysis, predictive modeling, and pattern identification.

Cryptography & Security

: Creating secure communication protocols and quantum-resistant encryption methods is the field of cryptography and security.

Simulation & Modeling

: Simulating intricate physical systems, chemical interactions, and materials science is known as simulation and modeling.

Database & Data Management

: Quantum databases and data processing techniques are included in database and data management.

By Model of Quantum Computing

Universal Quantum Computers

: Wide-ranging quantum algorithms can be executed by universal quantum computers.

Quantum Annealers

: Quantum annealers are experts at determining a system's lowest energy state in order to solve optimization challenges.

Quantum Simulators

: Quantum simulators are tools used to model and study the behavior and characteristics of quantum systems.

Hybrid Quantum Systems

: combining components of quantum and traditional computers for particular uses.

By Geography

North America:

Market conditions and demand in the United States, Canada, and Mexico.

Europe:

Analysis of the Quantum Computing Market in European countries.

Asia-Pacific:

Focusing on countries like China, India, Japan, South Korea, and others.

Middle East and Africa:

Examining market dynamics in the Middle East and African regions.

Latin America:

Covering market trends and developments in countries across Latin America.

Key Players

The major players in the Quantum Computing Market are:

IBM (US)

D-Wave Systems Inc. (Canada)

Microsoft (US)

Amazon Web Services (US)

Rigetti Computing (US)

QC Ware (US)

Toshiba (Japan)

Google (US)

Intel (US)

Quantinuum (US)

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. Quantum Computing Market, By Industry Vertical

• Finance
• Pharmaceuticals & Healthcare
• Aerospace & Defense
• Energy and Utilities
• IT & Telecommunications

5. Quantum Computing Market, By Application

• Optimization Problems
• AI and machine learning
• Cryptography & Security
• Simulation & Modeling
• Database & Data Management

6. Quantum Computing Market, By Model of Quantum Computing

• Universal Quantum Computers
• Quantum Annealers
• Quantum Simulators
• Hybrid Quantum Systems

7. 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

8. Competitive Landscape

• Market Share Analysis
• Key Strategies

9. Company Profiles

• IBM (US)
• D-Wave Systems Inc. (Canada)
• Microsoft (US)
• Amazon Web Services (US)
• Rigetti Computing (US)
• QC Ware (US)
• Toshiba (Japan)
• Google (US)
• Intel (US)
• Quantinuum (US)

10. Market Outlook and Opportunities

• Emerging Technologies
• Future Market Trends
• Investment Opportunities

11. Appendix

• List of Abbreviations
• Sources and References