Report Description Table of Contents Industry Report and Statistics (Facts & Figures) - Sales Volume, ASP & Demand by End-User & Application The global 3D printed battery market is projected to grow with a CAGR of 19.53 % throughout the forecasted period of 2020-2030. Based on Region, North America constitutes the highest 3d printed battery market share in terms of revenue. Electronic devices rely on energy storage, and there is a constant desire for smaller yet even more powerful batteries. International Renewable Energy Agency (IRENA) reported that the global market requires roughly 150 GW of battery storage to fulfill the IRENA's intended aim of nearly 45 % renewable energy generation by 2030. In recent years, studies have been performed to investigate new electrode materials, electrolytes, cell architectures, and novel fabrication techniques to improve the electrochemical properties of batteries, reduce production costs, and expand their application. Simultaneously, 3D printing is transforming our society, and technology is rapidly improving. It is becoming the foundation for next-generation futuristic 3D printed energy systems, in which batteries and supercapacitors may be printed in nearly any shape using techniques like direct ink writing, wet or dry etching, fused deposition modeling, inkjet printing, and stereolithography. 3D printing is an advanced production technology that uses digitally controlled layering of phase change and reactive materials (nanowires, nanorods, nanoporous monoliths) and solvent-based inks to produce complex 3D structures. This kind of fabrication usually commences by creating a 3D virtual model that is then cut into many 2D horizontal cross-sections with the use of specific software. A cohesive 3D object can be produced by successively printing fresh 2D layers on top of prior levels. 3D printing offers several major benefits over traditional battery fabrication methods for batteries. It enables the fabrication of desired complex architectures (miniaturization, customization) while precisely controlling the shape and thickness of the electrodes. Moreover, 3D printing reduces the steps of assembly and packing via direct integration, and the whole operation is safe, low cost, and environment friendly. 3D printed battery market trends suggest that the increasing desire for portable and flexible energy sources, rapid growth along with rising demand for electronic gadgets and wearable technologies are driving the growth rate of the global 3D printed battery market. Market Dynamics: Market Drivers: - (Sustainability, Increasing demand for Lightweight, Compact, and Portable Batteries) Sustainability is a significant market driver for the 3D printed battery market due to its ability to optimize resource usage, enable lightweight structures, localize production, promote recycling and circular economy practices, support renewable energy integration, and foster research and development. This aligns with the broader sustainability goals and provides economic and environmental advantages, making 3D-printed batteries an attractive option for various industries and applications. By minimizing material waste, enabling design freedom, and promoting lightweight structures, 3D-printed batteries contribute to sustainable practices. 3D printing allows manufacturers to shape and size their products, potentially saving on raw materials and rare earth minerals like lithium, cobalt, and manganese. This method produces virtually no waste, with material left over reclaimed and recycled for future prints. Blackstone Technology, a 3D-printed battery start-up, claims its approach to be more sustainable than traditional methods, as it saves battery metals and uses 25% less energy. The company's Thick Layer Technology, based on 3D screen printing, is 30% cheaper than conventional battery manufacturing & can be used for liquid-electrolyte & solid-state batteries. Blackstone is talking with Volkswagen about incorporating its batteries into e-cars and plans to mine and source materials from ethical sources, such as rare earth mining operations in Canada and Norway. The growing demand for lightweight, compact & portable batteries is a significant market driver for 3D-printed batteries. This demand originates from various industries and applications that require energy storage solutions with optimized weight and size characteristics. Portable electronics, electric vehicles, drones, wearable devices, consumer electronics, and space-constrained applications require lightweight and compact batteries. 3D printed batteries offer design flexibility and customization options, enabling the creation of batteries with optimized energy density and reduced weight. These batteries cater to the growing demand for portable electronics, EVs, drones, robotics, wearable devices, consumer electronics, and space-constrained applications. The customization options offered by 3D printing technology enable the production of batteries optimized for weight, size and meeting the specific needs of these applications. As the demand for smaller, lighter & more efficient energy storage solutions continues to grow, the 3DP batteries market is expected to expand. Market Restraints: - (Sensitivity to high temperature, lack of regulatory bodies, high equipment costs) High equipment costs, lack of international associations to regulate the producers, and sensitivity to high temperatures (that leads to sputtering, electrodeposition, chemical vapour deposition, atomic layer deposition) are hindering the growth of the 3D printed battery market. Opportunities: - (Solid State Batteries, rising demand for electric vehicles) Solid-state batteries & 3DP technologies have the potential to revolutionize the battery market by offering new opportunities for innovation & efficiency. Solid-state batteries use solid electrolytes, offering higher energy density, improved safety, longer lifespan, and faster charging capabilities. 3DP enables the creation of complex and customized objects using computer-aided design (CAD) models. This technology has been widely adopted in various industries due to its flexibility, cost-effectiveness & ability to produce intricate designs with minimum material waste. Both solid-state batteries and 3D printing complement each other, offering customized battery designs, enhanced performance, simplified manufacturing processes, material advancements, and rapid prototyping for research and development. Combining solid-state batteries and 3D printing presents exciting opportunities for innovation and efficient energy storage solutions for various applications. Silicon Valley startup Sakuu has developed a 3D-printing platform called the Kavian platform, which can mass produce solid-state batteries in any shape and size. The platform has the capability to print ceramic, glass, metals, and polymer materials simultaneously within a single layer. This unique feature facilitates the creation of streamlined models, resulting in significant energy, cost, labour, materials, and time savings. Moreover, this process enhancement also improves the printed objects' quality and reliability. In comparison with leading Li-ion batteries, Sakuu says its solid-state batteries are 50% smaller & 40% lighter. The EV market is rapidly growing in the face of climate catastrophe and government measures to minimize national carbon footprints. But these EVs, because of the traditional battery pack, weights two to three tonnes which in turn reduces their range. The EU plans to have 30 million zero-emission vehicles on its roads by 2030, while the UK declared in October that it would phase out gasoline and diesel vehicles by that year. Photocentric group claims that its photopolymer 3D printing technology can match the desired battery design principles for markets like these and the high volumes required. Global 3D Printed Battery Market: - Analysis of different Segmentations: The Global 3D Printed Battery Market segmentation analysis is based on Architectural Process, Application, End Users, and Region. Based on Application Wearables Smartphones Others Based on Architectural Process Graphene-based PLA filaments Graphene-based Li-ion Anodes Platinum-based Electrodes Others Based on End-User Energy Storage Devices Electronics Others Based on Region North America The US. Canada Europe Germany The UK France Spain Italy Rest of Europe Asia Pacific China Japan India South Korea Southeast Asia Rest of Asia Pacific Latin America Brazil Mexico Rest of Latin America Middle East & Africa GCC South Africa Rest of the Middle East & Africa Based on the application, the 3D-printed battery is applicable into wearables, smartphones & others. The wearables segment dominates the 3D printed battery market with a constant CAGR during the forecasted period. The wearables segment is a growing market for 3D printed batteries due to their compact form factors, lightweight construction, customization, and rapid prototyping capabilities. These batteries are ideal for wearable devices like smartwatches, fitness trackers & AR glasses, as they require lightweight and compact batteries that fit comfortably. 3D printing enables the production of custom shapes, sizes, and geometries, allowing for seamless integration into wearable devices. The lightweight construction enhances comfort and usability, while customization and personalization capabilities ensure optimal performance, improved battery life, and enhanced user experience. Rapid prototyping and iterative design enable manufacturers to experiment with different battery designs and introduce innovative features more efficiently. Based on the architectural process, PLA filaments based on graphene are the most popular, as they are widely utilized in 3D printing. They are nanocomposite materials that can be conductive and more robust than non-specialized filaments when infused with graphene. Based on the end-user, The 3D-printed battery market is categorized into Energy Storage Devices, Electronics & Others. The energy storage devices segment dominates the 3D-printed battery market. The demand for efficient and reliable energy storage solutions is increasing rapidly across various industries, including renewable energy integration, grid stabilization, and backup power applications. 3D printed batteries offer unique advantages in customization, design flexibility, and performance optimization, making them well-suited for energy storage applications. Customized designs and form factors allow for optimized integration into energy storage systems, providing greater efficiency and compactness than traditional battery technologies. Advanced materials & manufacturing techniques, such as additive manufacturing techniques, enable precise control over material composition, microstructures, and electrode designs, enhancing the overall performance & efficiency of 3D-printed batteries. Based on the region, North America dominates the 3D printed battery market with a revenue share of 40%, growing with a CAGR of 24.12%, poised to reach $280 Mn by 2030. North America dominates the 3D printed battery market due to its technological innovation and advanced manufacturing sectors. North America's robust ecosystem of research institutions, universities, and private companies fosters innovation and breakthroughs in battery technology. The country's well-developed industrial base, including a vast network of manufacturers, suppliers, and engineering expertise, supports the scaling and commercialization of emerging technologies like 3D printing. The established battery industry in North America, with numerous companies involved in battery manufacturing and energy storage systems, facilitates the integration of 3D printing technology into battery production processes. Government support and policies in North America often support technological innovation and a favourable business environment for emerging industries. Report Attribute Details Forecast Period 2020 - 2030 Growth rate CAGR of 19.53 % The base year for estimation 2020 Historical data 2015 – 2019 Unit USD Billion, CAGR (2020 - 2030) Segmentation By Application, By Architectural Process, By End User, By Region By Application Wearables, Smartphones, Others By Architectural Process Graphene-based PLA filaments, Graphene-based Li-ion Anodes, Platinum-based Electrodes, Others By End-User Energy Storage Devices, Electronics, Others By Region North America, Middle East & Africa, Asia Pacific, Europe, and Latin America Country Scope US, Mexico, Canada, Germany, UK, France, China, Japan, India etc. Company Usability Profiles KeraCel, Neware, Solvay AG, Stratasys Ltd, Materialize NV, 3D Systems, EOS GmbH, GE Additive, SLM Solutions, EXOne, Voxeljet Pricing and purchase options Customized buying options are available to meet your exact research needs. Global 3D Printed Battery Market: Competitive Landscape Analysis The competitive landscape analysis gives an overview of some prominent players operating in the market. Product innovation and continued R&D operations to create sophisticated technologies have assisted the market's growth. In the target market, there are many significant companies, and some of the 3D printed battery market leaders are: KeraCel Neware Solvay AG Stratasys Ltd Materialize NV 3D Systems EOS GmbH GE Additive SLM Solutions EXOne Voxeljet HP Company Envision Tec Blackstone Resources AG Global 3D Printed Battery Market: Recent Developments: On February 2023, Silicon Valley startup Sakuu developed a 3D-printing platform called the Kavian platform, which can mass produce solid-state batteries in any shape and size. The Kavian platform uses 3DP to assemble materials needed for Li-ion, Li-metal, and solid-state designs in 1 layer, a process called "SwiftPrint." This streamlined model saves energy, cost, labor, materials, and time while increasing quality and reliability. Sakuu's solid-state batteries are 50% smaller and 40% lighter than leading lithium-ion batteries, and the Kavian platform is 44% smaller than the equipment traditionally used to manufacture lithium-ion batteries. The platform allows manufacturers to produce batteries in custom shapes and sizes, allowing them to design batteries that fit their devices. Sakuu plans to sell its Kavian platform directly to various customers, including battery manufacturers, automakers, aerospace developers & renewable energy companies. The company plans to open gigafactories with partners around the globe, and by 2030, it hopes to be manufacturing 200 GWh of battery capacity annually. On January 2023, TOP.E invented a 3D printed battery using its own printers & 3DP technology. The company claims to produce 3D electrodes that are two or three times thicker than traditional coating technology, reducing energy consumption and posing fewer risks of self-ignition. This technology can reduce manufacturing costs by 30% and capital spending on production lines by 40%. TOP.E's 3DP technology can also be used to create solid-state batteries. The company has invented efficient multiheaded 3D printers compatible with all available electrode materials. On March 2023, Researchers at the University of Texas at El Paso & Youngstown State University are collaborating with NASA to develop 3DP batteries for future lunar astronauts. The $2.5 million project aims to create a new method that allows astronauts to build batteries from their lunar bases. The project is a significant step toward utilizing 3D printing technology for space exploration and terrestrial applications of batteries. The researchers are investigating two 3D printing methods: material extrusion and vat photopolymerization (VPP). NASA is also considering sodium-ion battery technology for future lunar missions, as lithium is scarce on the Moon and Mars. The UTEP research team will study sodium-ion battery chemistry and potential printing solutions. The project aims to build batteries in the required shape for various applications, including habitats and modules that can withstand harsh space conditions. On November 2022, Chinese researchers developed a new lithium metal battery using 3D printing technology, enhancing its lifespan and energy density. The battery, expected to be the next-generation high-energy battery, has faced bottlenecks like lithium dendrite growth and low Coulombic efficiency. The researchers used titanium carbide-based scaffolds to deposit lithium metal as the cathode, achieving an outstanding areal capacity of 30 milliampere hrs per cm2 and a cycle lifespan of over 4,800 hrs without producing lithium dendrite. The 3D-printed anode was made from porous LiFePO4 lattices, improving electrochemical performance. This approach offers a viable strategy for developing batteries with long lifespans and high energy density. Frequently Asked Question About This Report What is the 3d printed battery markets growth? The 3d printed battery markets growth is 19.53%. Which region accounted for the largest 3d printed battery market share? North America holds the largest 3D printed battery market share. Mention the key players in the 3D printed battery market. The key players are: KeraCel, Neware, Solvay AG, Stratasys Ltd, Materialize NV, 3D Systems, EOS GmbH, GE Additive, SLM Solutions, EXOne, Voxeljet What are the factors driving the 3D printed battery market? The increasing desire for portable and flexible energy sources, rapid growth along with rising demand for electronic gadgets and wearable technologies are driving the growth rate of the global 3D printed battery market. Sources: https://english.news.cn/20221029/62a05360ae0f41c1a40f2196d56bc9fb/c.html https://interestingengineering.com/innovation/nasa-3d-print-batteries-using-moon https://manufactur3dmag.com/chinese-startup-succeeds-3d-printed-battery/ https://www.freethink.com/energy/solid-state-battery https://www.freethink.com/energy/solid-state-battery https://link.springer.com/chapter/10.1007/978-981-99-4193-3_25s https://www.forbes.co3795 1. Introduction 1.1. Study Objective 1.2. Market Definition 1.3. Study Scope 1.3.1. Markets Covered 1.3.2. Geographic Scope 1.3.3. Years Considered 1.3.4. Stakeholders 2. Research Methodology 2.1. Data Procurement 2.2. Paid Database 2.2.1. Secondary Data 2.2.1.1. Key Secondary sources 2.2.2. Primary Data 2.2.2.1 Primary sources 2.2.2.2. Key industry insights 2.2.2.3. Primary interviews with experts 2.2.2.4. Key primary respondent list 2.3. Market Size Estimation 2.4. Bottom-Up and Top-Down Approaches 2.4.1. Bottom-Up Approach 2.4.1.1. Approach for arriving at market size By bottom-up analysis 2.4.2. Top-Down Approach 2.4.2.1. Approach for Capturing Market Size By Top-Down Analysis 2.5. Market Breakdown and Data Triangulation 2.6. Research Methodology 2.7. Risk Assessment 3. Executive Summary 3.1. 3D Printed Battery Market: Post-Covid-19 3.1.1 Actual Scenario 3.1.2 Pessimistic Scenario 3.1.3 Optimistic Scenario 3.1.4 Market Summary 4. Industry Outlook 4.1 Market Snapshot 4.2 Regional Analysis 4.2.1 market, By region, 2020 - 2030 (USD Million) 4.3 By Architectural Process Analysis 4.3.1 market, By Architectural Process, 2020 - 2030 (USD Million) 4.4 By End-user Analysis 4.4.1 market, By End-user, 2020 - 2030 (USD Million) 4.5 Application Analysis 4.5.1 market, By Application, 2020 - 2030 (USD Million) 4.6 Value Chain Analysis 4.7 Market Variable Analysis 4.7.1 Market Drivers Analysis 4.7.2 Market Restraints Analysis 4.8 Environment Analysis Tool 4.8.1 PEST analysis 4.8.2 Porter’s analysis 4.9 Penetration & Growth Prospect Mapping 5. Market Dynamics 5.1. Introduction 5.2. Market Dynamics 5.2.1. Drivers 5.2.2. Restraints 5.2.3. Opportunities 5.2.4. Challenges 5.3. Impact of Covid-19 On Market 5.4. Value Chain Analysis 5.5. Ecosystem 5.6. Patent Analysis 5.7. Trade Analysis 5.8. Tariff Analysis 5.9. Case Study Analysis 5.10. Porter’s Five Forces Analysis 5.10.1 Threat of New Entrants 5.10.2 Threat of Substitutes 5.10.3 Bargaining Power of Buyers 5.10.4 Bargaining Power of Suppliers 5.10.5 Degree of Competition 5.11. Application Analysis 5.11.1. Trends in Application (2014-2020) 5.11.2. Trends in Application (2021-2028) 5.12. Pricing Analysis 5.12.1. Average Price Trend Analysis (By Region, By Country) 6. Competitive & Vendor Landscape 6.1. Company Market Share Analysis 6.2. Manufacturing Sites, Area Served, Architectural Process Architectural Process 6.3. Market Competitive Situation and Trends 6.4. Manufacturers Mergers & Acquisitions, Expansion Plans 7. Global Market: By Architectural Process Segment Analysis 7.1. Introduction 7.2. Sales Volume & Revenue Analysis (2020-2030) 7.3. Graphene-based PLA filaments 7.3.1. Graphene-based PLA filaments market, 2020 - 2030 (USD Million) 7.4. Graphene-based Li-ion Anodes 7.4.1. Graphene-based Li-ion Anodes market, 2020 - 2030 (USD Million) 7.5. Platinum-based Electrodes 7.5.1. Platinum-based Electrodes market, 2020 - 2030 (USD Million) 7.6. Others 7.6.1. Others market, 2020 - 2030 (USD Million) 8. Global Market: By Application Segment Analysis 8.1. Introduction 8.2. Sales Volume & Revenue Analysis (2020-2030) 8.3. Wearables 8.3.1. Wearables market, 2020 - 2030 (USD Million) 8.4. Smartphones 8.4.1. Smartphones market, 2020 - 2030 (USD Million) 9. Global Market: By End-User Segment Analysis 9.1. Introduction 9.2. Sales Volume & Revenue Analysis (2020-2030) 9.3. Energy Storage Devices 9.3.1. Energy Storage Devices market, 2020 - 2030 (USD Million) 9.4. Electronics 9.4.1. Electronics market, 2020 - 2030 (USD Million) 9.5. Others 9.5.1. Others market, 2020 - 2030 (USD Million) 10. Global Market: Regional Outlook 10.1 North America 10.1.1. North America market, By Architectural Process, 2020 - 2030 (USD Million) 10.1.2. North America market, By End-user, 2020 - 2030 (USD Million) 10.1.3. North America market, By Application, 2020 - 2030 (USD Million) 10.1.4. North America market, By Country, 2020 - 2030 (USD Million) 10.1.4.1. U.S. 10.1.4.1.1. U.S. market, By Architectural Process, 2020 - 2030 (USD Million) 10.1.4.1.2. U.S. market, By End-user, 2020 - 2030 (USD Million) 10.1.4.1.3. U.S. market, By Application, 2020 - 2030 (USD Million) 10.1.4.2. Canada 10.1.4.2.1. Canada market, By Architectural Process, 2020 - 2030 (USD Million) 10.1.4.2.2. Canada market, By End-user, 2020 - 2030 (USD Million) 10.1.4.2.3. Canada market, By Application, 2020 - 2030 (USD Million) 10.2. Europe 10.2.1. Europe market, By Architectural Process, 2020 - 2030 (USD Million) 10.2.2. Europe market, By End-user, 2020 - 2030 (USD Million) 10.2.3. Europe market, By Application, 2020 - 2030 (USD Million) 10.2.4. Europe market, By country, 2020 - 2030 (USD Million) 10.2.4.1 U.K. 10.2.4.1.1. U.K. market, By Architectural Process, 2020 - 2030 (USD Million) 10.2.4.1.2. U.K. market, By End-user, 2020 - 2030 (USD Million) 10.2.4.1.3. U.K. market, By Application, 2020 - 2030 (USD Million) 10.2.4.2. Germany 10.2.4.2.1. Germany market, By Architectural Process, 2020 - 2030 (USD Million) 10.2.4.2.2. Germany market, By End-user, 2020 - 2030 (USD Million) 10.2.4.2.3. Germany market, By Application, 2020 - 2030 (USD Million) 10.2.4.3. France 10.2.4.3.1. France market, By Architectural Process, 2020 - 2030 (USD Million) 10.2.4.3.2. France market, By End-user, 2020 - 2030 (USD Million) 10.2.4.3.3. France market, By Application, 2020 - 2030 (USD Million) 10.2.4.4. Rest of Europe 10.2.4.4.1. Rest of Europe market, By Architectural Process, 2020 - 2030 (USD Million) 10.2.4.4.2. Rest of Europe market, By End-user, 2020 - 2030 (USD Million) 10.2.4.4.3. Rest of Europe market, By Application, 2020 - 2030 (USD Million) 10.3. Asia Pacific 10.3.1. Asia Pacific market, By Architectural Process, 2020 - 2030 (USD Million) 10.3.2. Asia Pacific market, By End-user, 2020 - 2030 (USD Million) 10.3.3. Asia Pacific market, By Application, 2020 - 2030 (USD Million) 10.3.4. Asia Pacific market, By country, 2020 - 2030 (USD Million) 10.3.4.1. China 10.3.4.1.1. China market, By Architectural Process, 2020 - 2030 (USD Million) 10.3.4.1.2. China market, By End-user, 2020 - 2030 (USD Million) 10.3.4.1.3. China market, By Application, 2020 - 2030 (USD Million) 10.3.4.2. India 10.3.4.2.1. India market, By Architectural Process, 2020 - 2030 (USD Million) 10.3.4.2.2. India market, By End-user, 2020 - 2030 (USD Million) 10.3.4.2.3. India market, By Application, 2020 - 2030 (USD Million) 10.3.4.3. Japan 10.3.4.3.1. Japan market, By Architectural Process, 2020 - 2030 (USD Million) 10.3.4.3.2. Japan market, By End-user, 2020 - 2030 (USD Million) 10.3.4.3.3. Japan market, By Application, 2020 - 2030 (USD Million) 10.3.4.4. South Korea 10.3.4.4.1. South Korea market, By Architectural Process, 2020 - 2030 (USD Million) 10.3.4.4.2. South Korea market, By End-user, 2020 - 2030 (USD Million) 10.3.4.4.3. South Korea market, By Application, 2020 - 2030 (USD Million) 10.3.4.5. Rest of ASIA PACIFIC 10.3.4.5.1. Rest of ASIA PACIFIC market, By Architectural Process, 2020 - 2030 (USD Million) 10.3.4.5.2. Rest of ASIA PACIFIC market, By End-user, 2020 - 2030 (USD Million) 10.3.4.5.3. Rest of ASIA PACIFIC market, By Application, 2020 - 2030 (USD Million) 10.4. Latin America 10.4.1. Latin America market, By Architectural Process, 2020 - 2030 (USD Million) 10.4.2. Latin America market, By End-user, 2020 - 2030 (USD Million) 10.4.3. Latin America market, By Application, 2020 - 2030 (USD Million) 10.4.4. Latin America market, By country, 2020 - 2030 (USD Million) 10.4.4.1. Brazil 10.4.4.1.1. Brazil market, By Architectural Process, 2020 - 2030 (USD Million) 10.4.4.1.2. Brazil market, By End-user, 2020 - 2030 (USD Million) 10.4.4.1.3. Brazil market, By Application, 2020 - 2030 (USD Million) 10.4.4.2. Mexico 10.4.4.2.1. Mexico market, By Architectural Process, 2020 - 2030 (USD Million) 10.4.4.2.2. Mexico market, By End-user, 2020 - 2030 (USD Million) 10.4.4.2.3. Mexico market, By Application, 2020 - 2030 (USD Million) 10.4.4.3. Rest of the Latin America 10.4.4.3.1. Rest of the Latin America market, By Architectural Process, 2020 - 2030 (USD Million) 10.4.4.3.2. Rest of the Latin America market, By End-user, 2020 - 2030 (USD Million) 10.4.4.3.3. Rest of the Latin America market, By Application, 2020 - 2030 (USD Million) 10.5. MEA 10.5.1. MEA market, By Architectural Process, 2020 - 2030 (USD Million) 10.5.2. MEA market, By End-user, 2020 - 2030 (USD Million) 10.5.3. MEA market, By Application, 2020 - 2030 (USD Million) 10.5.4. MEA market, By Region, 2020 - 2030 (USD Million) 11. Competitive Landscape 11.1 KeraCel 11.1.1. Company overview 11.1.2. Financial performance 11.1.3. Architectural Process Portfolio Analysis 11.1.4. Strategy & Recent Development 11.2. Neware 11.2.1. Company overview 11.2.2. Financial performance 11.2.3. Architectural Process Portfolio Analysis 11.2.4. Strategy & Recent Development 11.3. Solvay AG 11.3.1. Company overview 11.3.2. Financial performance 11.3.3. Architectural Process Portfolio Analysis 11.3.4. Strategy & Recent Development 11.4. Stratasys Ltd 11.4.1. Company overview 11.4.2. Financial performance 11.4.3. Architectural Process Portfolio Analysis 11.4.4. Strategy & Recent Development 11.5. Materialize NV 11.5.1. Company overview 11.5.2. Financial performance 11.5.3. Architectural Process Portfolio Analysis 11.5.4. Strategy & Recent Development 11.6. 3D Systems 11.6.1. Company overview 11.6.2. Financial performance 11.6.3. Architectural Process Portfolio Analysis 11.6.4. Strategy & Recent Development 11.7. EOS GmbH 11.7.1. Company overview 11.7.2. Financial performance 11.7.3. Architectural Process Portfolio Analysis 11.7.4. Strategy & Recent Development 11.8. GE Additive 11.8.1. Company overview 11.8.2. Financial performance 11.8.3. Architectural Process Portfolio Analysis 11.8.4. Strategy & Recent Development 11.9. SLM Solutions 11.9.1. Company overview 11.9.2. Financial performance 11.9.3. Architectural Process Portfolio Analysis 11.9.4. Strategy & Recent Development 11.10. EXONE 11.10.1. Company overview 11.10.2. Financial performance 11.10.3. Architectural Process Portfolio Analysis 11.10.4. Strategy & Recent Development 11.11. Voxeljet 11.11.1. Company overview 11.11.2. Financial performance 11.11.3. Architectural Process Portfolio Analysis 11.11.4. Strategy & Recent Development 11.12. HP Company 11.12.1. Company overview 11.12.2. Financial performance 11.12.3. Architectural Process Portfolio Analysis 11.12.4. Strategy & Recent Development 11.13. Envision Tec 11.13.1. Company overview 11.13.2. Financial performance 11.13.3. Architectural Process Portfolio Analysis 11.13.4. Strategy & Recent Development 11.14. Blackstone Resources AG 11.14.1. Company overview 11.14.2. Financial performance 11.14.3. Architectural Process Portfolio Analysis 11.14.4. Strategy & Recent Development List of Tables (57 Tables) TABLE 1. MARKET, By Architectural Process, 2020-2030 (USD Million) TABLE 2. MARKET FOR Graphene-based PLA filaments, BY REGION, 2020-2030 (USD Million) TABLE 3. MARKET FOR Graphene-based Li-ion Anodes, BY REGION, 2020-2030 (USD Million) TABLE 4. MARKET FOR Platinum-based Electrodes, BY REGION, 2020-2030 (USD Million) TABLE 5. MARKET FOR Others, BY REGION, 2020-2030 (USD Million) TABLE 6. MARKET, By End-user, 2020-2030 (USD Million) TABLE 7. MARKET FOR Energy Storage Devices, BY REGION, 2020-2030 (USD Million) TABLE 8. MARKET FOR Electronics, BY REGION, 2020-2030 (USD Million) TABLE 9. MARKET FOR Others, BY REGION, 2020-2030 (USD Million) TABLE 10. MARKET, BY APPLICATION, 2020-2030 (USD Million) TABLE 11. MARKET FOR Wearables, BY REGION, 2020-2030 (USD Million) TABLE 12. MARKET FOR Smartphones, BY REGION, 2020-2030 (USD Million) TABLE 13. MARKET, BY REGION, 2020-2030 (USD Million) TABLE 14. NORTH AMERICA MARKET, BY COUNTRY, 2020-2030 (USD Million) TABLE 15. NORTH AMERICA MARKET, By Architectural Process, 2020-2030 (USD Million) TABLE 16. NORTH AMERICA MARKET, By End-user, 2020-2030 (USD Million) TABLE 17. NORTH AMERICA MARKET, BY APPLICATION, 2020-2030 (USD Million) TABLE 18. EUROPE MARKET, BY COUNTRY, 2020-2030 (USD Million) TABLE 19. EUROPE MARKET, By Architectural Process, 2020-2030 (USD Million) TABLE 20. EUROPE MARKET, By End-user, 2020-2030 (USD Million) TABLE 21. EUROPE MARKET, BY APPLICATION, 2020-2030 (USD Million) TABLE 22. ASIA-PACIFIC MARKET, BY COUNTRY, 2020-2030 (USD Million) TABLE 23. ASIA-PACIFIC MARKET, By Architectural Process, 2020-2030 (USD Million) TABLE 24. ASIA-PACIFIC MARKET, By End-user, 2020-2030 (USD Million) TABLE 25. ASIA-PACIFIC MARKET, BY APPLICATION, 2020-2030 (USD Million) TABLE 26. LAMEA MARKET, BY COUNTRY, 2020-2030 (USD Million) TABLE 27. LAMEA MARKET, By Architectural Process, 2020-2030 (USD Million) TABLE 28. LAMEA MARKET, By End-user, 2020-2030 (USD Million) TABLE 29. LAMEA MARKET, BY APPLICATION, 2020-2030 (USD Million) TABLE 30. KeraCel: COMPANY SNAPSHOT TABLE 31. KeraCel: OPERATING SEGMENTS TABLE 32. Neware: COMPANY SNAPSHOT TABLE 33. Neware: OPERATING SEGMENTS TABLE 34. Solvay AG: COMPANY SNAPSHOT TABLE 35. Solvay AG: OPERATING SEGMENTS TABLE 36. Stratasys Ltd : COMPANY SNAPSHOT TABLE 37. Stratasys Ltd: OPERATING SEGMENTS TABLE 38. Materialize NV: COMPANY SNAPSHOT TABLE 39. Materialize NV: OPERATING SEGMENTS TABLE 40. 3D Systems: COMPANY SNAPSHOT TABLE 41. 3D Systems: OPERATING SEGMENTS TABLE 42. EOS GmbH: COMPANY SNAPSHOT TABLE 43. EOS GmbH: OPERATING SEGMENTS TABLE 44. GE Additive: COMPANY SNAPSHOT TABLE 45. GE Additive: OPERATING SEGMENTS TABLE 46. SLM Solutions: COMPANY SNAPSHOT TABLE 47. SLM Solutions: OPERATING SEGMENTS TABLE 48. EXONE: COMPANY SNAPSHOT TABLE 49. EXONE: OPERATING SEGMENTS TABLE 50. Voxeljet: COMPANY SNAPSHOT TABLE 51. Voxeljet: OPERATING SEGMENTS TABLE 52. HP Company: COMPANY SNAPSHOT TABLE 53. HP Company: OPERATING SEGMENTS TABLE 54. Envision Tec: COMPANY SNAPSHOT TABLE 55. Envision Tec: OPERATING SEGMENTS TABLE 56. Blackstone Resources AG: COMPANY SNAPSHOT TABLE 57. Blackstone Resources AG: OPERATING SEGMENTS List of Figures (22 Figures) Figure 1 Research Methodology Steps Figure 2 Research Design Figure 3 Breakdown of Primaries Figure 4 Research Methodology: Hypothesis Building Figure 5 Architectural Process-Based Estimation Figure 6 Top 14 Companies with Highest No. Of Patent in Last 9 Years Figure 7 No. Of Patents Granted Per Year, 2019–2020 Figure 8 Import Data for 3D Printed Battery, By Country, 2016–2020 (USD Thousand) Figure 9 Export Data for 3D Printed Battery, By Country, 2016–2020 (USD Thousand) Figure 10 Data Triangulation Methodology Figure 11 Market, By End-user, 2019 vs. 2025 (USD Million) Figure 12 Market Share, By Application, 2019 vs. 2025 (USD Million) Figure 13 Market Share, By Architectural Process, 2019 vs. 2025 (USD Million) Figure 14 Geographical Snapshot of the Market Figure 15 Graphene-based PLA filaments to Witness Higher CAGR in Market for Architectural Process Segment during Forecast Period. Figure 16 Wearables to Witness Higher CAGR in Market for Application Segment during Forecast Period. Figure 17 Energy Storage Devices to Witness Higher CAGR in Market for End-user Segment during Forecast Period. Figure 18 North America region Accounted for the Largest Share of the Market, By Regional Basis, in 2019 Figure 19 Drivers, Restraints, Opportunities, and Challenges Figure 20 North America: Market Snapshot Figure 21 Asia Pacific: Market Snapshot Figure 22 Vendor Dive: Evaluation Overview