시장보고서

상품코드

1806567

고체 배터리 시장 : 배터리 유형, 전해질 유형, 용량, 용도별 - 세계 전망(2025-2030년)

Solid State Battery Market by Battery Type, Electrolyte Type, Capacity, Application - Global Forecast 2025-2030

발행일: 2025년 08월 | 리서치사:

360iResearch | 페이지 정보: 영문 182 Pages | 배송안내 : 1-2일 (영업일 기준)

■ 보고서에 따라 최신 정보로 업데이트하여 보내드립니다. 배송일정은 문의해 주시기 바랍니다.

샘플 요청 목록에 추가

고체 배터리 시장은 2024년에 17억 4,000만 달러로 평가되었습니다. 2025년에는 20억 3,000만 달러에 이르고, CAGR 17.40%로 성장하여 2030년에는 45억 6,000만 달러에 달할 전망입니다.

주요 시장 통계
기준 연도 : 2024년	17억 4,000만 달러
추정 연도 : 2025년	20억 3,000만 달러
예측 연도 : 2030년	45억 6,000만 달러
CAGR(%)	17.40%

가속화되는 전기화 수요 속에서 고체 배터리 프런티어를 형성하는 최첨단 혁신과 전략적 중요성을 탐구합니다.

지난 10년간 에너지 저장의 상황은 급격한 변화보다는 점진적인 개선이 특징이었습니다. 고체 배터리는 현재 현저하게 높은 에너지 밀도, 향상된 안전 프로파일, 더 긴 수명주기 성능을 제공함으로써 이 궤도를 뒤바꿀 것을 약속하고 있습니다. 전 세계적으로 전동화에 대한 노력이 강화되는 가운데, 의사결정권자들은 차세대 배터리가 다양한 응용 분야에서 어떤 변화를 가져올 수 있는지 주목하고 있습니다.

전례 없는 기술 혁신과 공급망 혁신으로 세계 고체 배터리 생태계와 밸류체인을 재정의하는 전례 없는 기술 혁신과 공급망 변화

최근 세라믹 및 유리 기반 전해질의 획기적인 발전은 이온 전도도 및 기계적 안정성과 관련된 오랜 장벽을 크게 완화시켰으며, 주요 자동차 및 가전제품 제조업체들 사이에서 파일럿 프로그램이 속속 등장하고 있습니다. 동시에 고분자 복합재료의 혁신은 딱딱한 모듈에 국한되지 않는 유연한 폼팩터를 실현하여 웨어러블 기기 및 휴대용 기기의 설계 가능성을 넓히고 있습니다.

2025년 미국 관세 정책이 재료 조달 공급망과 세계 고체 배터리 개발에 미치는 종합적인 영향 평가

2025년 배터리 부품 및 전구체 화학물질에 대한 광범위한 관세 조치가 도입됨에 따라 공급망은 빠르게 재편되고 있습니다. 고순도 리튬, 황화화합물 등 주요 원소들의 재료비 변동이 심해지면서 각 제조업체들은 대체 조달을 검토하거나 전략적 비축을 하고 있습니다. 이에 따라 연구개발 투자 패턴도 영향을 받아 징벌적 관세의 영향을 덜 받는 화학물질이 선호되고 있습니다.

배터리 유형과 전해질 화학의 용량 계층 및 최종 사용의 수직적 방향이 어떻게 시장을 형성하고 있는지에 대한 세분화 역학에 대한 심층적인 통찰력을 제공합니다.

시장 세분화를 자세히 분석하면, 고체 배터리는 대용량 용도에 최적화된 벌크 설계, 컨포멀 전자장치에 적합한 유연한 형식, 성능 스태킹을 위해 설계된 다층 어셈블리, 소형 디바이스에 적합한 박막형 등 다양한 배터리 구성으로 평가되고 있음을 알 수 있습니다. 이러한 구조적 차이를 보완하기 위해 전해질에는 열적 탄성이 평가되는 산화물계 매트릭스, 기계적 유연성이 평가되는 고분자계 복합재료, 우수한 이온 전도성이 평가되는 황화물계 배합물 등이 있습니다.

북미, 중동 및 아프리카, 아시아태평양의 고체 배터리 시장 성장 촉진요인, 혁신 패턴, 채택 동향 분석

북미와 남미에서는 기존 자동차 산업과 항공우주 산업이 채용 활동을 주도하고 있으며, 미국 제조업체들이 전략적 파트너십을 맺고 파일럿 생산 시설의 규모를 확대하여 실제 작동 조건에서 고체 배터리의 성능을 검증하는 파일럿 프로그램을 진행하고 있습니다. 동시에 캐나다와 브라질의 연구기관이 전해질 배합 및 연구 프로세스 혁신에 기여하여 북미와 남미에 걸친 시너지 효과를 창출하고 있습니다. 이러한 협력적 생태계는 제조 인프라와 공급망 복원력에 대한 투자를 촉진하고 있습니다.

차세대 에너지 저장 추진을 위한 주요 고체 배터리 제조업체의 전략적 움직임 연구 협력 및 기술 로드맵 발표

고체전지 분야의 주요 기업들은 합작투자, 라이선스 계약, 자체 기술 개발 등 전략적인 동향을 체스판처럼 지휘하고 있습니다. 세계 자동차 OEM은 전문 스타트업과 연구 협력 관계를 맺고 대량 생산 전문 지식과 틈새 재료 과학 역량을 결합하여 독자적인 고체 전해질 배합 및 첨단 셀 구조를 공동 개발하고 있습니다. 한편, 기술 주도형 혁신가들은 시리즈 A 및 B 자금 조달 라운드를 확보하여 파일럿 라인 시운전 및 고처리량 테스트 체제를 가속화하고 있습니다.

고체전지 산업의 상용화와 지속 가능한 성장을 가속화하기 위해 경영진의 의사결정을 이끌 수 있는 실행 가능한 전략적 과제

업계 리더들은 셀 설계를 빠르게 반복할 수 있는 엔드 투 엔드 파일럿 생산 시설을 구축하는 한편, 스케일업 전략에 도움이 되는 운영 데이터를 수집하는 것을 우선시해야 합니다. 고급 분석과 디지털 트윈 기술을 생산 공정 초기에 통합함으로써 조직은 제조 병목현상을 미리 파악하고 처리 효율성을 최적화할 수 있습니다. 기술적 불확실성을 더욱 완화하기 위해, 학제 간 연구 컨소시엄을 구성하고, 재료 과학자, 공정 엔지니어, 최종 시장 전문가 간의 지식 이전을 촉진해야 합니다.

전문가별 1차 조사 2차 데이터 분석과 삼각측량으로 고체 배터리 시장 인사이트 검증을 통합한 종합적인 조사 방법론

본 보고서는 1차 조사와 2차 조사 프레임워크을 결합한 엄격한 조사방법을 바탕으로 작성되었습니다. 2차 분석에서는 고체 배터리 기술의 진화를 매핑하기 위해 동료평가 출판물, 특허 데이터베이스, 정부 및 업계 백서, 기업의 재무 공개를 철저히 검토했습니다. 2차 데이터는 일관성, 타당성, 현재 시장 환경과의 관련성을 보장하기 위해 비판적으로 평가하고 교차 검증을 거쳤습니다.

고체 배터리의 진화에 대한 결론적 관점은 기술적 잠재력과 시장의 복잡성을 강조하고 업계 이해 관계자들에게 전략적 경로를 제시합니다.

고체 배터리 기술이 실험실의 호기심에서 상업적 경쟁으로 전환됨에 따라 업계는 매우 중요한 교차로에 서 있습니다. 전해질 배합과 셀 아키텍처의 기술적 혁신은 자동차, 가전제품, 그리드 스케일 에너지 저장 용도를 재정의할 수 있는 성능의 한계점을 돌파하고 있습니다. 동시에 정책적 프레임워크와 지정학적 고려사항이 공급망 구성과 비용 구조에 큰 영향을 미치고 있습니다.

시장 점유율 분석, 2024
FPNV 포지셔닝 매트릭스, 2024
경쟁 분석
- Beijing WeLion New Energy Technology Co., Ltd.
- Ganfeng Lithium Group Co., Ltd
- Kanadevia Corporation
- Honda Motor Co., Ltd.
- LG Energy Solution Co., Ltd.
- Maxell, Ltd.
- Murata Manufacturing Co., Ltd.
- Nissan Motor Co., Ltd.
- Panasonic Holdings Corporation
- ProLogium Technology Co., Ltd.
- Samsung SDI Co., Ltd.
- SK Inc.
- STMicroelectronics N.V.
- TDK Corportation
- Toyota Motor Corporation

제16장 리서치 AI

제17장 리서치 통계

제18장 리서치 컨택트

제19장 리서치 기사

제20장 부록

LSH

The Solid State Battery Market was valued at USD 1.74 billion in 2024 and is projected to grow to USD 2.03 billion in 2025, with a CAGR of 17.40%, reaching USD 4.56 billion by 2030.

KEY MARKET STATISTICS
Base Year [2024]	USD 1.74 billion
Estimated Year [2025]	USD 2.03 billion
Forecast Year [2030]	USD 4.56 billion
CAGR (%)	17.40%

Exploring the Cutting-Edge Innovations and Strategic Imperatives Shaping the Solid State Battery Frontier Amidst Accelerating Electrification Demands

Over the last decade, the energy storage landscape has been marked by incremental improvements rather than radical shifts. Solid state batteries now promise to upend this trajectory by offering markedly higher energy density, enhanced safety profiles, and longer lifecycle performance. As global electrification efforts intensify, decision makers are closely monitoring how these next-generation cells can deliver transformative benefits across a range of applications.

The maturation of materials science has catalyzed significant advances in solid electrolytes, enabling the stabilization of lithium metal anodes and reducing the risk of thermal runaway. Innovation in electrode architecture is further propelling capacity and charge rate improvements, positioning solid state technologies at the forefront of energy storage research. Consequently, industry participants are reevaluating roadmaps, partnerships, and capital allocations to capture emerging opportunities in battery design, manufacturing, and supply chains.

Looking ahead, strategic imperatives revolve around balancing rapid prototype development with the rigors of scalability, cost optimization, and regulatory compliance. From laboratory validation to pilot production lines, stakeholders must navigate complex certification pathways while forging alliances across the materials, automotive, and electronics sectors. In this evolving milieu, a clear understanding of technological capabilities and market dynamics will be essential for securing competitive advantage in the solid state battery frontier.

Moreover, the interplay between raw material sourcing, environmental sustainability, and geopolitical stability has become increasingly apparent. Establishing vertically integrated supply chains and securing critical mineral reserves are as vital as optimizing cell chemistry. With new entrants challenging incumbents and cross-sector collaborations proliferating, the solid state battery domain is poised for an unprecedented phase of growth and disruption.

Unprecedented Technological Breakthroughs and Supply Chain Transformations Redefining the Global Solid State Battery Ecosystem and Value Chains

Recent breakthroughs in ceramic and glass-based electrolytes have significantly mitigated longstanding barriers related to ionic conductivity and mechanical stability, triggering a wave of pilot programs among leading automotive and consumer electronics manufacturers. Simultaneously, innovations in polymer composites are unlocking flexible form factors that extend beyond rigid modules, expanding design possibilities for wearables and portable devices.

These technological leaps are intersecting with supply chain recalibrations, as raw material suppliers and cell producers reorganize to accommodate novel chemistries. Strategic partnerships between catalyst developers and battery assemblers are facilitating faster iteration cycles, while government incentives and research grants are accelerating commercialization timelines. As a result, ecosystem stakeholders are witnessing a shift from conventional lithium-ion paradigms toward hybrid architectures that blend the strengths of existing platforms with solid state enhancements.

In parallel, manufacturing methodologies are evolving to embrace scalable thin-film deposition and roll-to-roll production techniques that promise cost efficiencies at volume. Automation and digital twin modeling are being deployed to optimize assembly processes, reduce defect rates, and forecast maintenance requirements. Together, these disruptive shifts are redefining competitive positioning, compelling legacy battery firms and startups alike to revisit their value propositions and operational blueprints.

Looking forward, integration of real-time analytics and AI-driven process control is expected to further refine throughput and yield, cementing solid state batteries as a critical pillar in the future of energy storage across diverse sectors.

Assessing the Comprehensive Effects of 2025 United States Tariff Policies on Materials Procurement Supply Chains and Global Solid State Battery Development

With the introduction of sweeping tariff measures on battery components and precursor chemicals in 2025, supply chains are undergoing rapid realignment. Material costs for key elements such as high-purity lithium and sulfide compounds have seen pronounced volatility, prompting manufacturers to explore alternative sourcing arrangements and strategic stockpiling. In turn, this has influenced R&D investment patterns, favoring chemistries less exposed to punitive duties.

The tariff regime has also incentivized regionalization of production footprints, as cell producers evaluate the merits of localizing upstream processes within tariff-advantaged territories. Such moves are reshaping logistics networks, increasing demand for domestic processing facilities, and fostering closer collaboration between governments and private entities. Consequently, the interplay between trade policy and technology innovation has become a decisive factor in defining competitive landscapes.

Amid these developments, stakeholders are renegotiating joint venture agreements to distribute risk and capital expenditure more effectively. Financial projections are being adjusted to reflect potential headwinds in the cost-of-goods sold, while strategic roadmaps now incorporate flexible sourcing clauses and adaptive manufacturing strategies. Ultimately, the cumulative impact of these policy changes underscores the necessity for agile planning and continuous monitoring of geopolitical trends to safeguard supply continuity and profitability.

Furthermore, the tariff environment has spurred increased attention to circular economy initiatives, driving investment into material recovery and recycling processes that can mitigate exposure to imported inputs and enhance sustainability credentials.

Deep Insights Into Segmentation Dynamics Revealing How Battery Type Electrolyte Chemistry Capacity Tiers and End Use Verticals Are Shaping the Market

An in-depth analysis of market segments reveals that solid state batteries are being evaluated across distinct battery configurations including bulk designs optimized for high capacity applications, flexible formats tailored for conformable electronics, multi-layer assemblies engineered for performance stacking, and thin-film variants suited to miniaturized devices. Complementing these structural distinctions, the electrolyte landscape spans oxide-based matrices prized for thermal resilience, polymer-based composites valued for mechanical flexibility, and sulfide-based formulations recognized for superior ionic conductivity.

Capacity segmentation further illustrates how applications diverge, with cells rated below 20 mAh finding niche roles in microelectromechanical systems and sensor networks, mid-range cells from 20 mAh to 500 mAh powering next-generation wearables and portable medical devices, and larger formats above 500 mAh driving advancements in electric mobility and grid-level energy storage. Equally critical, end-use classification spans sectors as diverse as aerospace and defense, consumer electronics wherein laptops, tablets, smartphones, and wearable devices demand ultra-thin form factors, electric vehicles encompassing both commercial fleets and passenger cars, energy storage systems deployed in commercial and residential contexts, industrial machinery requiring robust performance under harsh conditions, and medical equipment that prioritizes safety and reliability.

These multidimensional segmentation insights highlight the nuanced requirements across market niches, guiding product development roadmaps and commercialization strategies while enabling stakeholders to target resources toward segments with the highest strategic relevance and growth potential.

Examining Distinct Growth Drivers Innovation Patterns and Adoption Trends Across Americas Europe Middle East Africa and Asia-Pacific Solid State Battery Markets

In the Americas, established automotive and aerospace industries are leading adoption efforts, with U.S. manufacturers forging strategic partnerships to scale pilot production facilities and pilot programs to validate the performance of solid state cells under real-world operating conditions. Simultaneously, Canadian and Brazilian research institutions are contributing innovations in electrolyte formulations and recycling processes, creating synergies that extend across North and South America. This cooperative ecosystem is fostering investments in manufacturing infrastructure and supply chain resilience.

Meanwhile, Europe, Middle East & Africa are distinguished by strong policy support for decarbonization and advanced R&D networks. Germany, France, and the United Kingdom are hosting flagship development centers focused on high-volume roll-to-roll production and advanced testing protocols, while Middle Eastern entities are investing in raw material processing to secure feedstocks. African initiatives, though in earlier stages, are beginning to explore strategic mining partnerships and downstream value-add opportunities, positioning the region as a future hub for critical materials.

Across Asia-Pacific, the convergence of government incentives, large-scale manufacturing capacity, and technology giants has created a formidable growth engine. Japan and South Korea continue to pioneer solid electrolyte research, while China's integrated supply chains enable rapid scaling from laboratory breakthroughs to commercial gigafactories. Southeast Asian nations are emerging as competitive assembly bases, leveraging lower operational costs and favorable trade policies to participate in global battery value chains. Together, these regional dynamics map out a complex yet opportunity-rich landscape for stakeholders seeking to optimize market entry and expansion strategies.

Illuminating Strategic Moves Research Collaborations and Technology Roadmaps of Leading Solid State Battery Manufacturers Driving Next-Generation Energy Storage

Leading companies in the solid state battery arena are orchestrating a chessboard of strategic moves encompassing joint ventures, licensing agreements, and in-house technology development. Global automotive OEMs have entered into research collaborations with specialist startups to co-develop proprietary solid electrolyte formulations and advanced cell architectures, blending mass production expertise with niche material science competencies. Meanwhile, technology-driven innovators are securing series A and B funding rounds to accelerate pilot line commissioning and high-throughput testing regimes.

Concurrently, vertically integrated supply chain players are forging long-term offtake agreements for high-purity precursor chemicals and investment partnerships to underwrite next-generation manufacturing equipment. This convergence of capital and expertise is enabling rapid scaling from proof-of-concept cells to commercial prototypes within compressed development cycles. Moreover, cross-sector alliances are emerging as a critical enabler; semiconductor foundries and electronics conglomerates are collaborating with battery firms to integrate solid state cells into heterogeneous systems, optimizing form factors and performance benchmarks.

As companies navigate competitive differentiation, intellectual property portfolios have become a focal point, with patent filings reflecting a surge in electrolyte mixtures, interface engineering techniques, and protective coating innovations. Strategic acquisitions of smaller research teams serve both to absorb novel IP and to expand talent pipelines. These corporate maneuvers collectively underscore an intensifying race to establish technological leadership and secure market share in the nascent solid state battery domain.

Actionable Strategic Imperatives Guiding Executive Decision Making to Accelerate Commercialization and Sustainable Growth in Solid State Battery Industry

Industry leaders should prioritize the establishment of end-to-end pilot production facilities that enable rapid iteration of cell designs while gathering operational data to inform scale-up strategies. By embedding advanced analytics and digital twin technologies early in the production process, organizations can preempt manufacturing bottlenecks and optimize throughput efficiency. To further mitigate technical uncertainty, cross-disciplinary research consortia should be formed, fostering knowledge transfer between material scientists, process engineers, and end-market experts.

Simultaneously, executives must cultivate diversified supplier networks, spanning both traditional cathode and anode materials as well as innovative solid electrolyte precursors. By executing dual-sourcing strategies and securing volume discounts through long-term contracts, companies can buffer against supply chain disruptions and tariff-induced cost fluctuations. Equally important is the pursuit of strategic alliances with original equipment manufacturers and systems integrators to accelerate application-specific validation and qualify cells for stringent industry standards.

Furthermore, decision makers are advised to engage proactively with regulatory bodies and standards organizations to contribute to the development of safety protocols and performance benchmarks that will underpin market acceptance. Investment in circular economy initiatives-such as in-line recycling and material reclamation pilots-can deliver both environmental benefits and cost offsets. Finally, executive teams should implement dynamic roadmapping exercises, regularly revisiting technology maturation timelines and adjusting capital allocation to ensure alignment with evolving market conditions and policy landscapes.

Comprehensive Research Methodology Integrating Primary Expert Interviews Secondary Data Analysis and Triangulation to Validate Solid State Battery Market Insights

This report is grounded in a rigorous methodology combining both primary and secondary research frameworks. Secondary analysis involved an exhaustive review of peer-reviewed publications, patent databases, government and industry white papers, and corporate financial disclosures to map the evolution of solid state battery technologies. Secondary data was critically evaluated and cross-checked to ensure consistency, validity, and relevance to the current market environment.

Primary research was conducted through structured interviews and in-depth discussions with key stakeholders, including cell developers, materials suppliers, systems integrators, and regulatory authorities. These qualitative interactions provided firsthand insights into technology roadmaps, commercialization challenges, and strategic priorities. Quantitative surveys were administered to a broad spectrum of participants to capture measurable data on production capacities, investment flows, and adoption timelines.

Data triangulation was employed to reconcile findings across multiple sources, enhancing the reliability of conclusions and recommendations. Advanced analytical techniques, such as regression analysis and scenario modeling, were used to dissect the interplay between technological variables, policy interventions, and market dynamics. In addition, expert workshops facilitated validation of emerging trends and identification of critical success factors. This comprehensive approach ensures that the report's insights are both robust and actionable for strategic decision making.

Conclusive Perspectives on Solid State Battery Evolution Highlighting Technological Promise Market Complexities and Strategic Pathways for Industry Stakeholders

As solid state battery technologies transition from laboratory curiosities to commercial contenders, the industry stands at a pivotal juncture. Technological breakthroughs in electrolyte formulations and cell architecture are unlocking performance thresholds that could redefine energy storage applications across automotive, consumer electronics, and grid-scale sectors. At the same time, policy frameworks and geopolitical considerations are exerting significant influence on supply chain configurations and cost structures.

Stakeholders equipped with a deep understanding of segmentation nuances, regional dynamics, and the strategic playbooks of leading companies will be best positioned to navigate this rapidly evolving landscape. Proactive engagement in pilot production, strategic partnerships, and supply chain diversification will serve as key enablers of sustainable growth. Moreover, alignment with emerging standards and circular economy principles will reinforce both competitive differentiation and environmental responsibility.

In sum, the trajectory of solid state batteries will be shaped by the interplay of innovation velocity, manufacturing scalability, and regulatory evolution. By integrating the insights and recommendations articulated in this report, industry participants can chart a deliberate path toward technological leadership and long-term value creation.

As market conditions and technological capabilities continue to evolve, ongoing vigilance and adaptive strategies will be essential. Stakeholders should continuously monitor advancements, reassess investment priorities, and remain agile in the face of emerging opportunities and challenges.

1. Preface

1.1. Objectives of the Study
1.2. Market Segmentation & Coverage
1.3. Years Considered for the Study
1.4. Currency & Pricing
1.5. Language
1.6. Stakeholders

2. Research Methodology

2.1. Define: Research Objective
2.2. Determine: Research Design
2.3. Prepare: Research Instrument
2.4. Collect: Data Source
2.5. Analyze: Data Interpretation
2.6. Formulate: Data Verification
2.7. Publish: Research Report
2.8. Repeat: Report Update

3. Executive Summary

4. Market Overview

4.1. Introduction
4.2. Market Sizing & Forecasting

5. Market Dynamics

5.1. Surging integration of flexible and lightweight batteries in wearable devices globally
5.2. Strategic collaborations among automotive OEMs and technology startups in solid state battery R&D
5.3. Advances in lithium metal anode stabilization techniques to extend cycle life of solid state cells
5.4. Innovations in recycling and end of life management for next generation solid state battery materials
5.5. Commercial scale production challenges for solid electrolyte materials in battery manufacturing
5.6. Emerging roll to roll manufacturing processes for scalable production of solid state battery cells
5.7. Evolution of global regulatory frameworks for certification and safety of solid state batteries
5.8. Integration of ceramic composite electrolytes for improved mechanical stability in battery architecture
5.9. Breakthrough developments in sulfide based solid electrolytes enhancing ionic conductivity and safety
5.10. Performance optimization of solid state batteries in extreme temperature conditions for automotive applications

6. Market Insights

6.1. Porter's Five Forces Analysis
6.2. PESTLE Analysis

7. Cumulative Impact of United States Tariffs 2025

8. Solid State Battery Market, by Battery Type

8.1. Introduction
8.2. Bulk Batteries
8.3. Flexible Batteries
8.4. Multi-layer Batteries
8.5. Thin-film Batteries

9. Solid State Battery Market, by Electrolyte Type

9.1. Introduction
9.2. Oxide-Based Solid-State Electrolytes
9.3. Polymer-Based Solid-State Electrolytes
9.4. Sulfide-Based Solid-State Electrolytes

10. Solid State Battery Market, by Capacity

10.1. Introduction
10.2. 20 mAh to 500 mAh
10.3. Above 500 mAh
10.4. Less than 20 mAh

11. Solid State Battery Market, by Application

11.1. Introduction
11.2. Aerospace & Defense
11.3. Consumer Electronics
- 11.3.1. Laptops/Tablets
- 11.3.2. Smartphones
- 11.3.3. Wearables
11.4. Electric Vehicles (EVs)
- 11.4.1. Commercial EVs
- 11.4.2. Passenger EVs
11.5. Energy Storage Systems
- 11.5.1. Commercial
- 11.5.2. Residential
11.6. Industrial Equipment
11.7. Medical Devices

12. Americas Solid State Battery Market

12.1. Introduction
12.2. United States
12.3. Canada
12.4. Mexico
12.5. Brazil
12.6. Argentina

13. Europe, Middle East & Africa Solid State Battery Market

13.1. Introduction
13.2. United Kingdom
13.3. Germany
13.4. France
13.5. Russia
13.6. Italy
13.7. Spain
13.8. United Arab Emirates
13.9. Saudi Arabia
13.10. South Africa
13.11. Denmark
13.12. Netherlands
13.13. Qatar
13.14. Finland
13.15. Sweden
13.16. Nigeria
13.17. Egypt
13.18. Turkey
13.19. Israel
13.20. Norway
13.21. Poland
13.22. Switzerland

14. Asia-Pacific Solid State Battery Market

14.1. Introduction
14.2. China
14.3. India
14.4. Japan
14.5. Australia
14.6. South Korea
14.7. Indonesia
14.8. Thailand
14.9. Philippines
14.10. Malaysia
14.11. Singapore
14.12. Vietnam
14.13. Taiwan

15. Competitive Landscape

15.1. Market Share Analysis, 2024
15.2. FPNV Positioning Matrix, 2024
15.3. Competitive Analysis
- 15.3.1. Beijing WeLion New Energy Technology Co., Ltd.
- 15.3.2. Ganfeng Lithium Group Co., Ltd
- 15.3.3. Kanadevia Corporation
- 15.3.4. Honda Motor Co., Ltd.
- 15.3.5. LG Energy Solution Co., Ltd.
- 15.3.6. Maxell, Ltd.
- 15.3.7. Murata Manufacturing Co., Ltd.
- 15.3.8. Nissan Motor Co., Ltd.
- 15.3.9. Panasonic Holdings Corporation
- 15.3.10. ProLogium Technology Co., Ltd.
- 15.3.11. Samsung SDI Co., Ltd.
- 15.3.12. SK Inc.
- 15.3.13. STMicroelectronics N.V.
- 15.3.14. TDK Corportation
- 15.3.15. Toyota Motor Corporation

고체 배터리 시장 : 배터리 유형, 전해질 유형, 용량, 용도별 - 세계 전망(2025-2030년)

Solid State Battery Market by Battery Type, Electrolyte Type, Capacity, Application - Global Forecast 2025-2030

가속화되는 전기화 수요 속에서 고체 배터리 프런티어를 형성하는 최첨단 혁신과 전략적 중요성을 탐구합니다.

전례 없는 기술 혁신과 공급망 혁신으로 세계 고체 배터리 생태계와 밸류체인을 재정의하는 전례 없는 기술 혁신과 공급망 변화

2025년 미국 관세 정책이 재료 조달 공급망과 세계 고체 배터리 개발에 미치는 종합적인 영향 평가

배터리 유형과 전해질 화학의 용량 계층 및 최종 사용의 수직적 방향이 어떻게 시장을 형성하고 있는지에 대한 세분화 역학에 대한 심층적인 통찰력을 제공합니다.

북미, 중동 및 아프리카, 아시아태평양의 고체 배터리 시장 성장 촉진요인, 혁신 패턴, 채택 동향 분석

차세대 에너지 저장 추진을 위한 주요 고체 배터리 제조업체의 전략적 움직임 연구 협력 및 기술 로드맵 발표

고체전지 산업의 상용화와 지속 가능한 성장을 가속화하기 위해 경영진의 의사결정을 이끌 수 있는 실행 가능한 전략적 과제

전문가별 1차 조사 2차 데이터 분석과 삼각측량으로 고체 배터리 시장 인사이트 검증을 통합한 종합적인 조사 방법론

고체 배터리의 진화에 대한 결론적 관점은 기술적 잠재력과 시장의 복잡성을 강조하고 업계 이해 관계자들에게 전략적 경로를 제시합니다.

목차

제1장 서문

제2장 조사 방법

제3장 주요 요약

제4장 시장 개요

제5장 시장 역학

제6장 시장 인사이트

제7장 미국 관세의 누적 영향 2025

제8장 고체 배터리 시장 : 배터리 유형별

제9장 고체 배터리 시장 전해질 유형별

제10장 고체 배터리 시장 : 용량별

제11장 고체 배터리 시장 : 용도별

제12장 아메리카의 고체 배터리 시장

제13장 유럽, 중동 및 아프리카의 고체 배터리 시장

제14장 아시아태평양의 고체 배터리 시장

제15장 경쟁 구도