Materials Informatics Market By Technology (Data Analytics, Machine Learning, Artificial Intelligence, Others), By Simulation (Molecular Modeling, Finite Element Analysis, Others), By Application (Aerospace, Automotive, Electronics & Semiconductors, Energy & Utilities, Healthcare, Materials Science), By End-User (Enterprises, Academic Institutions, Government, Individuals), By Deployment Mode (On-Premise, Cloud-Based), By Service (Consulting, Training & Support); Global Insights & Forecast (2025 - 2030)

As per Intent Market Research, the Materials Informatics Market was valued at USD 5.3 Billion in 2024-e and will surpass USD 12.2 Billion by 2030; growing at a CAGR of 15.0% during 2025 - 2030.

The Materials Informatics market is experiencing significant growth as industries strive to accelerate innovation, reduce development time, and enhance the performance of materials used in various applications. By leveraging advanced data analytics, machine learning, artificial intelligence (AI), and simulation technologies, materials informatics helps in discovering, designing, and optimizing new materials with enhanced properties. The integration of computational tools with experimental methods is transforming the way materials are developed and tested, offering new solutions across industries such as aerospace, automotive, electronics, energy, and healthcare. As industries look for more efficient ways to innovate and solve complex material-related challenges, the adoption of materials informatics continues to rise.

The materials informatics market is supported by a variety of technological advancements, including machine learning, AI, molecular modeling, and finite element analysis. These technologies enable more accurate predictions of material behaviors, accelerated material design processes, and improved performance testing. As the demand for new materials with specific properties—such as lightweight, high strength, or improved conductivity—increases, industries are turning to materials informatics to optimize material discovery and development processes. The market also sees growing interest from academic institutions and government agencies, which are increasingly investing in research to push the boundaries of material science and drive further innovation.

Data Analytics Technologies Lead the Market Due to AI and Machine Learning Integration

In the Materials Informatics market, data analytics technologies, especially machine learning (ML) and artificial intelligence (AI), are driving the fastest growth. The integration of AI and ML in materials science is enabling more efficient data processing, pattern recognition, and predictive modeling. These technologies help identify hidden relationships in large datasets, optimize material properties, and predict material performance under different conditions, significantly accelerating the material design process. The ability to train machine learning models with experimental and computational data enables materials scientists to explore new material combinations and optimize their use across various industries.

AI and machine learning are being utilized to automate the discovery of new materials, such as alloys with desired mechanical, thermal, or electrical properties, or polymers with better durability and flexibility. By analyzing large volumes of data from diverse sources, ML algorithms can predict material behavior with remarkable accuracy, which helps reduce the need for time-consuming and costly physical testing. The application of these technologies is particularly transformative in sectors like aerospace, automotive, and electronics, where the demand for innovative, high-performance materials is high. As AI and ML continue to evolve, they are expected to remain the cornerstone of progress in the materials informatics space, revolutionizing how materials are designed, tested, and deployed.

Materials Informatics Market Size

Aerospace & Automotive Industries Drive Significant Demand for Materials Informatics

The aerospace and automotive sectors are the largest end-users in the Materials Informatics market due to their continuous demand for high-performance materials. Aerospace applications require lightweight, durable, and heat-resistant materials to meet stringent safety and performance standards. Similarly, automotive manufacturers are increasingly focusing on the use of advanced materials to reduce vehicle weight, enhance fuel efficiency, and improve safety. Materials informatics plays a crucial role in these industries by helping engineers develop new materials that meet these specific requirements faster and more cost-effectively.

In aerospace, materials informatics supports the development of composite materials that are lighter yet stronger than traditional metals, essential for improving fuel efficiency and reducing emissions. Similarly, in the automotive industry, the need for materials with better thermal resistance, corrosion resistance, and high strength-to-weight ratios is driving the adoption of materials informatics tools. By accelerating the material development cycle, these industries can achieve performance and sustainability goals more efficiently. With the growing emphasis on electric vehicles (EVs) in the automotive industry, the demand for specialized materials such as battery components is also contributing to the growth of materials informatics.

Cloud-Based Deployment Mode is Growing Rapidly Due to Flexibility and Accessibility

The cloud-based deployment mode is the fastest growing segment in the Materials Informatics market. Cloud platforms provide flexible, scalable, and accessible solutions that allow users to store, analyze, and share vast amounts of data without the need for extensive on-premise infrastructure. With cloud-based solutions, enterprises, academic institutions, and government agencies can collaborate in real-time and access powerful computational tools without the financial burden of maintaining expensive hardware. These platforms support the rapid processing of large datasets, which is essential for the high volume of data generated in materials research and testing.

Cloud-based deployment also enables organizations to integrate materials informatics solutions with other enterprise systems, such as supply chain management, production planning, and product lifecycle management. This level of integration is key to improving the efficiency and effectiveness of the materials development process. Additionally, as more companies and research institutions transition to remote or hybrid working models, the flexibility offered by cloud-based materials informatics tools ensures continued access to critical resources and collaboration opportunities. As a result, cloud-based solutions are becoming increasingly popular and are expected to dominate the market in the coming years.

Healthcare & Energy Sectors Exhibit Strong Growth Potential in Materials Informatics

While aerospace and automotive industries dominate the current market, the healthcare and energy sectors are emerging as strong drivers for future growth in materials informatics. The healthcare industry is exploring the use of new materials for medical devices, implants, drug delivery systems, and tissue engineering, all of which require specialized properties like biocompatibility, durability, and responsiveness. Materials informatics is helping researchers and manufacturers discover and design such materials more efficiently, reducing the time and cost of bringing new products to market.

The energy sector also holds substantial growth potential, as the demand for advanced materials to improve energy storage, efficiency, and sustainability continues to rise. Materials informatics is playing a key role in developing next-generation materials for batteries, solar cells, and energy-efficient coatings. With increasing investments in renewable energy and the push for cleaner energy solutions, the energy sector is expected to become a major contributor to the materials informatics market in the coming years, further driving innovation in the field.

North America Leads Materials Informatics Market with Innovation-Driven Growth

North America is the largest market for materials informatics, primarily driven by advancements in data analytics, machine learning, and artificial intelligence (AI). The region's dominance is attributed to its strong industrial base in aerospace, automotive, and electronics, along with significant investments in research and development. The U.S. spearheads the market, hosting numerous leading enterprises, academic institutions, and government initiatives focused on advanced materials discovery. Collaborations between industries and research organizations further boost market growth, enabling faster adoption of cloud-based and AI-driven simulation technologies.

Moreover, the region's advanced IT infrastructure supports the rapid deployment of cloud-based solutions, which are increasingly preferred for their scalability and cost-effectiveness. North America's focus on sustainability and the development of lightweight, energy-efficient materials also underscores its leadership in this domain.

Materials Informatics Market Size by Region 2030

Competitive Landscape

The Materials Informatics market is highly competitive, with several key players offering innovative solutions across various technologies and application areas. Prominent companies include Thermo Fisher Scientific, Dassault Systèmes, Exabyte.io, Granta Design, and Materials Design, each providing data analytics, simulation tools, and cloud-based platforms that support material discovery and optimization. These companies are focused on incorporating cutting-edge technologies such as AI, machine learning, and molecular modeling into their platforms to enhance material discovery and testing capabilities.

The competitive landscape is marked by constant innovation, with companies investing heavily in R&D to improve the accuracy, scalability, and accessibility of their solutions. Partnerships and collaborations between academia, industry, and government agencies are also common, as materials informatics requires expertise across multiple fields. Additionally, the increasing use of cloud-based solutions and the growing interest from emerging sectors such as healthcare and energy are fueling market growth. The market is expected to remain competitive, with new entrants and technological advancements continuing to shape its evolution.

Recent Developments:

  • IBM announced a collaboration with a leading automotive company to develop AI-powered materials for electric vehicle batteries in December 2024.
  • Dow Chemical launched a new suite of materials informatics solutions to accelerate sustainable materials development in November 2024.
  • NVIDIA unveiled new AI-based tools to enhance materials science research for electronics and semiconductor industries in October 2024.
  • Accenture expanded its materials informatics consulting services, focusing on the healthcare sector in September 2024.
  • Siemens entered into a strategic partnership with a major university to advance materials informatics research using high-performance computing in August 2024.

List of Leading Companies:

  • IBM
  • Microsoft
  • Intel
  • NVIDIA
  • TCS (Tata Consultancy Services)
  • BASF
  • GE (General Electric)
  • Dow Chemical
  • Accenture
  • Siemens
  • Oracle
  • SAP
  • Thermo Fisher Scientific
  • 3M
  • Honeywell

Report Scope:

Report Features

Description

Market Size (2024-e)

USD 5.3 Billion

Forecasted Value (2030)

USD 12.2 Billion

CAGR (2025 – 2030)

15.0%

Base Year for Estimation

2024-e

Historic Year

2023

Forecast Period

2025 – 2030

Report Coverage

Market Forecast, Market Dynamics, Competitive Landscape, Recent Developments

Segments Covered

Materials Informatics Market By Technology (Data Analytics, Machine Learning, Artificial Intelligence, Others), By Simulation (Molecular Modeling, Finite Element Analysis, Others), By Application (Aerospace, Automotive, Electronics & Semiconductors, Energy & Utilities, Healthcare, Materials Science), By End-User (Enterprises, Academic Institutions, Government, Individuals), By Deployment Mode (On-Premise, Cloud-Based), By Service (Consulting, Training & Support); Global Insights & Forecast (2025 - 2030)

Regional Analysis

North America (US, Canada, Mexico), Europe (Germany, France, UK, Italy, Spain, and Rest of Europe), Asia-Pacific (China, Japan, South Korea, Australia, India, and Rest of Asia-Pacific), Latin America (Brazil, Argentina, and Rest of Latin America), Middle East & Africa (Saudi Arabia, UAE, Rest of Middle East & Africa)

Major Companies

IBM, Microsoft, Intel, NVIDIA, TCS (Tata Consultancy Services), BASF, Dow Chemical, Accenture, Siemens, Oracle, SAP, Thermo Fisher Scientific, Honeywell

Customization Scope

Customization for segments, region/country-level will be provided. Moreover, additional customization can be done based on the requirements

1. Introduction

   1.1. Market Definition

   1.2. Scope of the Study

   1.3. Research Assumptions

   1.4. Study Limitations

2. Research Methodology

   2.1. Research Approach

      2.1.1. Top-Down Method

      2.1.2. Bottom-Up Method

      2.1.3. Factor Impact Analysis

  2.2. Insights & Data Collection Process

      2.2.1. Secondary Research

      2.2.2. Primary Research

   2.3. Data Mining Process

      2.3.1. Data Analysis

      2.3.2. Data Validation and Revalidation

      2.3.3. Data Triangulation

3. Executive Summary

   3.1. Major Markets & Segments

   3.2. Highest Growing Regions and Respective Countries

   3.3. Impact of Growth Drivers & Inhibitors

   3.4. Regulatory Overview by Country

4. Materials Informatics Market, by Technology (Market Size & Forecast: USD Million, 2023 – 2030)

   4.1. Data Analytics

      4.1.1. Machine Learning

      4.1.2. Artificial Intelligence

      4.1.3. Others

   4.2. Simulation

      4.2.1. Molecular Modeling

      4.2.2. Finite Element Analysis

      4.2.3. Others

5. Materials Informatics Market, by Application (Market Size & Forecast: USD Million, 2023 – 2030)

   5.1. Aerospace

   5.2. Automotive

   5.3. Electronics & Semiconductors

   5.4. Energy & Utilities

   5.5. Healthcare

   5.6. Materials Science

6. Materials Informatics Market, by End-User (Market Size & Forecast: USD Million, 2023 – 2030)

   6.1. Enterprises

   6.2. Academic Institutions

   6.3. Government

   6.4. Individuals

7. Materials Informatics Market, by Deployment Mode (Market Size & Forecast: USD Million, 2023 – 2030)

   7.1. On-Premise

   7.2. Cloud-Based

8. Materials Informatics Market, by Service (Market Size & Forecast: USD Million, 2023 – 2030)

   8.1. Consulting

   8.2. Training & Support

9. Regional Analysis (Market Size & Forecast: USD Million, 2023 – 2030)

   9.1. Regional Overview

   9.2. North America

      9.2.1. Regional Trends & Growth Drivers

      9.2.2. Barriers & Challenges

      9.2.3. Opportunities

      9.2.4. Factor Impact Analysis

      9.2.5. Technology Trends

      9.2.6. North America Materials Informatics Market, by Technology

      9.2.7. North America Materials Informatics Market, by Application

      9.2.8. North America Materials Informatics Market, by End-User

      9.2.9. North America Materials Informatics Market, by Deployment Mode

      9.2.10. North America Materials Informatics Market, by Service

      9.2.11. By Country

         9.2.11.1. US

               9.2.11.1.1. US Materials Informatics Market, by Technology

               9.2.11.1.2. US Materials Informatics Market, by Application

               9.2.11.1.3. US Materials Informatics Market, by End-User

               9.2.11.1.4. US Materials Informatics Market, by Deployment Mode

               9.2.11.1.5. US Materials Informatics Market, by Service

         9.2.11.2. Canada

         9.2.11.3. Mexico

    *Similar segmentation will be provided for each region and country

   9.3. Europe

   9.4. Asia-Pacific

   9.5. Latin America

   9.6. Middle East & Africa

10. Competitive Landscape

   10.1. Overview of the Key Players

   10.2. Competitive Ecosystem

      10.2.1. Level of Fragmentation

      10.2.2. Market Consolidation

      10.2.3. Product Innovation

   10.3. Company Share Analysis

   10.4. Company Benchmarking Matrix

      10.4.1. Strategic Overview

      10.4.2. Product Innovations

   10.5. Start-up Ecosystem

   10.6. Strategic Competitive Insights/ Customer Imperatives

   10.7. ESG Matrix/ Sustainability Matrix

   10.8. Manufacturing Network

      10.8.1. Locations

      10.8.2. Supply Chain and Logistics

      10.8.3. Product Flexibility/Customization

      10.8.4. Digital Transformation and Connectivity

      10.8.5. Environmental and Regulatory Compliance

   10.9. Technology Readiness Level Matrix

   10.10. Technology Maturity Curve

   10.11. Buying Criteria

11. Company Profiles

   11.1. IBM

      11.1.1. Company Overview

      11.1.2. Company Financials

      11.1.3. Product/Service Portfolio

      11.1.4. Recent Developments

      11.1.5. IMR Analysis

    *Similar information will be provided for other companies 

   11.2. Microsoft

   11.3. Intel

   11.4. NVIDIA

   11.5. TCS (Tata Consultancy Services)

   11.6. BASF

   11.7. GE (General Electric)

   11.8. Dow Chemical

   11.9. Accenture

   11.10. Siemens

   11.11. Oracle

   11.12. SAP

   11.13. Thermo Fisher Scientific

   11.14. 3M

   11.15. Honeywell

12. Appendix

A comprehensive market research approach was employed to gather and analyze data on the Materials Informatics Market. In the process, the analysis was also done to analyze the parent market and relevant adjacencies to measure the impact of them on the Materials Informatics Market. The research methodology encompassed both secondary and primary research techniques, ensuring the accuracy and credibility of the findings.

Research Approach -

Secondary Research

Secondary research involved a thorough review of pertinent industry reports, journals, articles, and publications. Additionally, annual reports, press releases, and investor presentations of industry players were scrutinized to gain insights into their market positioning and strategies.

Primary Research

Primary research involved conducting in-depth interviews with industry experts, stakeholders, and market participants across the E-Waste Management ecosystem. The primary research objectives included:

  • Validating findings and assumptions derived from secondary research
  • Gathering qualitative and quantitative data on market trends, drivers, and challenges
  • Understanding the demand-side dynamics, encompassing end-users, component manufacturers, facility providers, and service providers
  • Assessing the supply-side landscape, including technological advancements and recent developments

Market Size Assessment

A combination of top-down and bottom-up approaches was utilized to analyze the overall size of the Materials Informatics Market. These methods were also employed to assess the size of various subsegments within the market. The market size assessment methodology encompassed the following steps:

  1. Identification of key industry players and relevant revenues through extensive secondary research
  2. Determination of the industry's supply chain and market size, in terms of value, through primary and secondary research processes
  3. Calculation of percentage shares, splits, and breakdowns using secondary sources and verification through primary sources

Bottom Up and Top Down -

Data Triangulation

To ensure the accuracy and reliability of the market size, data triangulation was implemented. This involved cross-referencing data from various sources, including demand and supply side factors, market trends, and expert opinions. Additionally, top-down and bottom-up approaches were employed to validate the market size assessment.

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