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市场调查报告书
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1702384

全球量子材料市场 - 2025-2032

Global Quantum Materials Market - 2025-2032
出版日期: | 出版商: DataM Intelligence | 英文 180 Pages | 商品交期: 最快1-2个工作天内

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简介目录

2024 年全球量子材料市场规模达到 104.2 亿美元,预计到 2032 年将达到 969 亿美元,在 2025-2032 年预测期内的复合年增长率为 32.15%。

全球量子材料产业正在发展,更加重视永续性和环境责任。超导体、拓朴绝缘体和量子点等量子材料在节能技术方面发挥重要作用,但它们的製造和应用带来了环境问题。

领先的公司和研究机构正在逐步投资永续量子材料开发,预计将推动市场发展。 IBM、微软和谷歌等公司正尝试减少量子运算设备对环境的影响。各国政府也正在资助绿色量子研究,例如欧盟的量子旗舰计划,该计划旨在推广永续材料和节能量子设备。

市场动态

量子运算和先进技术的投资不断增加

量子计算、奈米技术和先进半导体应用的投资增加推动了市场的发展。世界各国政府、科技公司和研究机构正在增加对拓朴绝缘体、超导体和二维材料(如石墨烯、过渡金属二硫属化物)等量子材料的研发投入,以提高运算能力、能源效率和材料性能。

例如,美国的《国家量子计画法案》和欧洲的《量子旗舰计画》已拨款数十亿美元用于量子技术研发,影响了对量子材料的需求。随着银行、医疗保健、航太和网路安全等产业探索量子运算应用,对高效能量子材料的需求可能会大幅扩大。

生产成本高

全球量子材料市场面临的最大障碍之一是这些先进材料所需的高生产成本和复杂的製造程序。拓朴绝缘体、超导体和量子点等量子材料需要严格规范的生产环境、专门的设备和精确的条件来维持其独特的特性。

例如,量子计算中使用的超导材料需要极低的温度(接近绝对零度)才能正常运行,这增加了运营和维护成本。同样,石墨烯和其他二维材料需要复杂且昂贵的合成程序,例如化学气相沉积(CVD)和分子束外延(MBE),这使得大规模生产在经济上变得困难。

市场区隔分析

全球量子材料市场根据材料、应用、最终用户和地区进行细分。

预计全球市场的拓朴绝缘体将推动市场发展。

2024年,拓朴绝缘体将占据全球量子材料市场的最大份额。对节能设备和新一代电脑系统日益增长的需求正在推动拓扑绝缘体 (TI) 的全球使用。拓朴绝缘体具有独特的电学特性,使其能够在表面导电,同时保持内部绝缘。这一特性使它们成为低功率、高性能电气设备的绝佳选择。

TI 最有趣的用途之一是量子运算。 Google、IBM 和微软等公司正在积极研究 TI 在容错量子电脑中的潜在应用,它们可以帮助形成马约拉纳费米子,这对于无错误量子运算至关重要。此外,拓扑绝缘体正在整合到自旋电子装置中,从而能够以更低的能量损失实现更高效的资料处理,从而提高其在现代计算系统中的接受度。

市场地理占有率

北美政府和私部门的强劲投资

在政府和私营部门对量子技术的大力投资的推动下,北美量子材料市场正在经历显着成长。美国和加拿大处于量子研究的前沿,并得到了联邦机构和主要科技企业的大力支持。例如,2018年通过的美国国家量子计画法案拨出数十亿美元用于开发量子材料、电脑和通讯技术。

美国能源部 (DOE)、美国国家科学基金会 (NSF) 和美国国防高级研究计划局 (DARPA) 都在积极资助超导体、拓扑绝缘体和二维材料等量子材料的研究,这些研究对于量子计算和下一代电子技术的进步至关重要。 IBM、Google和微软正在大力投资量子电脑研究,增加了对高品质量子材料的需求。例如,IBM 的量子网路与多所大学合作,利用复杂的超导材料创建量子处理器。

可持续性分析

量子材料的主要永续优势之一是其降低能源消耗的能力。例如,超导材料可以实现零电阻能量传输,从而有可能提高电网、资料中心和量子计算系统的效率。这可以减少碳排放,符合全球脱碳目标。

量子材料使得下一代太阳能电池、节能电晶体和先进电池技术的创造成为可能。量子点太阳能电池的创新有可能提高太阳能转换效率并减少对化石燃料的依赖。同样,量子材料正在被研究用于低功耗计算,这有助于减少科技业的全球能源需求。

全球主要参与者

市场的主要全球参与者包括 IBM 公司、英特尔公司、IonQ Inc.、Silicon Quantum Computing、华为技术有限公司、Alphabet Inc.、Rigetti & Co, LLC、微软公司、D-Wave Quantum Inc 和 Zapata Computing Inc.

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2024年目标受众

製造商/买家

产业投资者/投资银行家

研究专业人员

新兴公司

目录

第一章:方法论和范围

第 2 章:定义与概述

第三章:执行摘要

第四章:动态

  • 影响因素
    • 驱动程式
      • 量子运算和先进技术的投资不断增加
    • 限制
      • 生产成本高
    • 机会
    • 影响分析

第五章:产业分析

  • 波特五力分析
  • 供应链分析
  • 定价分析
  • 监管分析
  • 可持续性分析
  • DMI 意见

第六章:依材质

  • 拓朴绝缘体
  • 石墨烯和二维材料
  • 韦尔半金属
  • 量子点
  • 高温超导体
  • 光子量子材料
  • 其他的

第七章:按应用

  • 量子计算
  • 量子感测与计量
  • 光电子
  • 医疗与生命科学
  • 其他的

第 8 章:按最终用户

  • 资讯科技和电信
  • 医疗保健与生命科学
  • 航太与国防
  • 汽车与运输
  • 电子与半导体
  • 能源与电力
  • 其他的

第九章:按地区

  • 北美洲
    • 我们
    • 加拿大
    • 墨西哥
  • 欧洲
    • 德国
    • 英国
    • 法国
    • 义大利
    • 西班牙
    • 欧洲其他地区
  • 南美洲
    • 巴西
    • 阿根廷
    • 南美洲其他地区
  • 亚太
    • 中国
    • 印度
    • 日本
    • 澳洲
    • 亚太其他地区
  • 中东和非洲

第十章:竞争格局

  • 竞争格局
  • 市场定位/份额分析
  • 併购分析

第 11 章:公司简介

  • IBM Corporation
    • 公司概况
    • 产品组合和描述
    • 财务概览
    • 关键进展
  • Intel Corporation
  • IonQ Inc.
  • Silicon Quantum Computing
  • Huawei Technologies Co. Ltd
  • Alphabet Inc.
  • Rigetti & Co, LLC
  • Microsoft Corporation
  • D-Wave Quantum Inc
  • Zapata Computing Inc.

第 12 章:附录

简介目录
Product Code: ICT9449

Global Quantum Materials Market reached US$ 10.42 billion in 2024 and is expected to reach US$ 96.9 billion by 2032, growing with a CAGR of 32.15% during the forecast period 2025-2032.

The global quantum materials industry is developing, with a greater emphasis on sustainability and environmental responsibility. Quantum materials, such as superconductors, topological insulators and quantum dots, play an important role in allowing energy-efficient technology, but their manufacturing and application create environmental issues.

Leading firms and research organizations are progressively investing in sustainable quantum material development, which is projected to drive the market. Companies including IBM, Microsoft and Google are attempting to reduce the environmental impact of quantum computing gear. Governments are also sponsoring green quantum research, like the European Union's Quantum Flagship Initiative, which promotes sustainable materials and energy-efficient quantum devices.

Market Dynamics

Rising Investments in Quantum Computing and Advanced Technologies

The market is being driven by increased investment in quantum computing, nanotechnology and advanced semiconductor applications. Governments, technology companies and research institutions around the world are increasing funding for the creation of quantum materials that include topological insulators, superconductors and 2D materials (e.g., graphene, transition metal dichalcogenides) to improve computing power, energy efficiency and material properties.

For example, the National Quantum Initiative Act in US and Europe's Quantum Flagship Program have allocated billions of dollars to quantum technology research and development, thereby impacting demand for quantum materials. As industries such as banking, healthcare, aerospace and cybersecurity explore quantum computing applications, the need for high-performance quantum materials is likely to expand considerably.

High Production Costs

One of the most significant hurdles in the global quantum materials market is the high production costs and complex manufacturing procedures required for these advanced materials. Quantum materials, such as topological insulators, superconductors and quantum dots, require highly regulated production settings, specialized equipment and precise conditions to maintain their distinct features.

For example, superconducting materials used in quantum computing require extremely low temperatures (near absolute zero) to perform properly, increasing operational and maintenance costs. Similarly, graphene and other 2D materials need complex and expensive synthesis procedures, such as chemical vapor deposition (CVD) and molecular beam epitaxy (MBE), making large-scale manufacture economically hard.

Market Segment Analysis

The global quantum materials market is segmented based on material, application, end-user and region.

Topological Insulators in the global market is expected to drive the market.

In 2024, the topological insulators segment accounted for the largest percentage of global quantum materials market. The growing demand for energy-efficient devices and next-generation computer systems is driving global usage of topological insulators (TIs). Topological insulators have distinct electrical properties that allow them to conduct electricity on their surfaces while staying insulating in bulk. This property makes them an excellent choice for low-power, high-performance electrical equipment.

One of the most intriguing uses for TIs is quantum computing. Companies such as Google, IBM and Microsoft are aggressively researching TIs for their potential application in fault-tolerant quantum computers, where they can aid in the formation of Majorana fermions, which are critical for error-free quantum computing. Furthermore, topological insulators are being integrated into spintronic devices, enabling more efficient data processing with low energy loss, increasing their acceptance in modern computing systems.

Market Geographical Share

Strong Government and Private Sector Investments in North America

The North American quantum materials market is witnessing significant growth, driven by strong government and private sector investments in quantum technologies. US and Canada are at the forefront of quantum research, receiving significant support from both federal agencies and major technology businesses. For example, US National Quantum Initiative Act, passed in 2018, set aside billions of dollars for the development of quantum materials, computers and communications technology.

The Department of Energy (DOE), the National Science Foundation (NSF) and DARPA are all actively sponsoring research into quantum materials such as superconductors, topological insulators and 2D materials, which are crucial for advances in quantum computing and next-generation electronics. IBM, Google and Microsoft are heavily investing in quantum computer research, increasing demand for high-quality quantum materials. IBM's Quantum Network, for example, works with several academic universities to create quantum processors with sophisticated superconducting materials.

Sustainability Analysis

One of the primary sustainability advantages of quantum materials is their ability to reduce energy consumption. For example, superconducting materials enable zero-resistance energy transmission, potentially improving the efficiency of power grids, data centers and quantum computing systems. This can result in decreased carbon emissions, which aligns with worldwide decarbonization targets.

Quantum materials enable the creation of next-generation solar cells, energy-efficient transistors and advanced battery technologies. Innovations in quantum dot solar cells have the potential to increase solar energy conversion efficiency and reduce reliance on fossil fuels. Similarly, quantum materials are being investigated for low-power computing, which can assist reduce global energy demand in the technology industry.

Major Global Players

The major global players in the market include IBM Corporation, Intel Corporation, IonQ Inc., Silicon Quantum Computing, Huawei Technologies Co. Ltd, Alphabet Inc., Rigetti & Co, LLC, Microsoft Corporation, D-Wave Quantum Inc and Zapata Computing Inc.

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Target Audience 2024

Manufacturers/ Buyers

Industry Investors/Investment Bankers

Research Professionals

Emerging Companies

Table of Contents

1. Methodology and Scope

  • 1.1. Research Methodology
  • 1.2. Research Objective and Scope of the Report

2. Definition and Overview

3. Executive Summary

  • 3.1. Snippet by Material
  • 3.2. Snippet by Application
  • 3.3. Snippet by End-User
  • 3.4. Snippet by Region

4. Dynamics

  • 4.1. Impacting Factors
    • 4.1.1. Drivers
      • 4.1.1.1. Rising Investments in Quantum Computing and Advanced Technologies
    • 4.1.2. Restraints
      • 4.1.2.1. High Production Costs
    • 4.1.3. Opportunity
    • 4.1.4. Impact Analysis

5. Industry Analysis

  • 5.1. Porter's Five Force Analysis
  • 5.2. Supply Chain Analysis
  • 5.3. Pricing Analysis
  • 5.4. Regulatory Analysis
  • 5.5. Sustainability Analysis
  • 5.6. DMI Opinion

6. By Material

  • 6.1. Introduction
    • 6.1.1. Market Size Analysis and Y-o-Y Growth Analysis (%), By Material
    • 6.1.2. Market Attractiveness Index, By Material
  • 6.2. Topological Insulators*
    • 6.2.1. Introduction
    • 6.2.2. Market Size Analysis and Y-o-Y Growth Analysis (%)
  • 6.3. Graphene and 2D Materials
  • 6.4. Weyl Semimetals
  • 6.5. Quantum Dots
  • 6.6. High-Temperature Superconductors
  • 6.7. Photonic Quantum Materials
  • 6.8. Others

7. By Application

  • 7.1. Introduction
    • 7.1.1. Market Size Analysis and Y-o-Y Growth Analysis (%), By Application
    • 7.1.2. Market Attractiveness Index, By Application
  • 7.2. Quantum Computing*
    • 7.2.1. Introduction
    • 7.2.2. Market Size Analysis and Y-o-Y Growth Analysis (%)
  • 7.3. Quantum Sensing & Metrology
  • 7.4. Optoelectronics
  • 7.5. Medical & Life Sciences
  • 7.6. Others

8. By End-User

  • 8.1. Introduction
    • 8.1.1. Market Size Analysis and Y-o-Y Growth Analysis (%), By End-User
    • 8.1.2. Market Attractiveness Index, By End-User
  • 8.2. IT & Telecommunications*
    • 8.2.1. Introduction
    • 8.2.2. Market Size Analysis and Y-o-Y Growth Analysis (%)
  • 8.3. Healthcare & Life Sciences
  • 8.4. Aerospace & Defense
  • 8.5. Automotive & Transportation
  • 8.6. Electronics & Semiconductors
  • 8.7. Energy & Power
  • 8.8. Others

9. By Region

  • 9.1. Introduction
    • 9.1.1. Market Size Analysis and Y-o-Y Growth Analysis (%), By Region
    • 9.1.2. Market Attractiveness Index, By Region
  • 9.2. North America
    • 9.2.1. Introduction
    • 9.2.2. Key Region-Specific Dynamics
    • 9.2.3. Market Size Analysis and Y-o-Y Growth Analysis (%), By Material
    • 9.2.4. Market Size Analysis and Y-o-Y Growth Analysis (%), By Application
    • 9.2.5. Market Size Analysis and Y-o-Y Growth Analysis (%), By End-User
    • 9.2.6. Market Size Analysis and Y-o-Y Growth Analysis (%), By Country
      • 9.2.6.1. US
      • 9.2.6.2. Canada
      • 9.2.6.3. Mexico
  • 9.3. Europe
    • 9.3.1. Introduction
    • 9.3.2. Key Region-Specific Dynamics
    • 9.3.3. Market Size Analysis and Y-o-Y Growth Analysis (%), By Material
    • 9.3.4. Market Size Analysis and Y-o-Y Growth Analysis (%), By Application
    • 9.3.5. Market Size Analysis and Y-o-Y Growth Analysis (%), By End-User
    • 9.3.6. Market Size Analysis and Y-o-Y Growth Analysis (%), By Country
      • 9.3.6.1. Germany
      • 9.3.6.2. UK
      • 9.3.6.3. France
      • 9.3.6.4. Italy
      • 9.3.6.5. Spain
      • 9.3.6.6. Rest of Europe
  • 9.4. South America
    • 9.4.1. Introduction
    • 9.4.2. Key Region-Specific Dynamics
    • 9.4.3. Market Size Analysis and Y-o-Y Growth Analysis (%), By Material
    • 9.4.4. Market Size Analysis and Y-o-Y Growth Analysis (%), By Application
    • 9.4.5. Market Size Analysis and Y-o-Y Growth Analysis (%), By End-User
    • 9.4.6. Market Size Analysis and Y-o-Y Growth Analysis (%), By Country
      • 9.4.6.1. Brazil
      • 9.4.6.2. Argentina
      • 9.4.6.3. Rest of South America
  • 9.5. Asia-Pacific
    • 9.5.1. Introduction
    • 9.5.2. Key Region-Specific Dynamics
    • 9.5.3. Market Size Analysis and Y-o-Y Growth Analysis (%), By Material
    • 9.5.4. Market Size Analysis and Y-o-Y Growth Analysis (%), By Application
    • 9.5.5. Market Size Analysis and Y-o-Y Growth Analysis (%), By End-User
    • 9.5.6. Market Size Analysis and Y-o-Y Growth Analysis (%), By Country
      • 9.5.6.1. China
      • 9.5.6.2. India
      • 9.5.6.3. Japan
      • 9.5.6.4. Australia
      • 9.5.6.5. Rest of Asia-Pacific
  • 9.6. Middle East and Africa
    • 9.6.1. Introduction
    • 9.6.2. Key Region-Specific Dynamics
    • 9.6.3. Market Size Analysis and Y-o-Y Growth Analysis (%), By Material
    • 9.6.4. Market Size Analysis and Y-o-Y Growth Analysis (%), By Application
    • 9.6.5. Market Size Analysis and Y-o-Y Growth Analysis (%), By End-User

10. Competitive Landscape

  • 10.1. Competitive Scenario
  • 10.2. Market Positioning/Share Analysis
  • 10.3. Mergers and Acquisitions Analysis

11. Company Profiles

  • 11.1. IBM Corporation*
    • 11.1.1. Company Overview
    • 11.1.2. Product Portfolio and Description
    • 11.1.3. Financial Overview
    • 11.1.4. Key Developments
  • 11.2. Intel Corporation
  • 11.3. IonQ Inc.
  • 11.4. Silicon Quantum Computing
  • 11.5. Huawei Technologies Co. Ltd
  • 11.6. Alphabet Inc.
  • 11.7. Rigetti & Co, LLC
  • 11.8. Microsoft Corporation
  • 11.9. D-Wave Quantum Inc
  • 11.10. Zapata Computing Inc.

LIST NOT EXHAUSTIVE

12. Appendix

  • 12.1. About Us and Services
  • 12.2. Contact Us