Global Advanced Battery Materials Market Analysis–Trends, Insights & Forecasts 2024

  • Publish Date
    July 6, 2024
  • No of Pages
    432
  • SKU Code
    GIR 7085
  • Format

Report Overview

  • Understand the latest market trends and future growth opportunities for the Advance Battery Materials industry in globally with research from Global Industry Reports team of in-country analysts – experts by industry and geographic specialization.
  • Key trends are clearly and succinctly summarized alongside the most current research data available. Understand and assess competitive threats and plan corporate strategy with our qualitative analysis, insight, and confident growth projections.
  • The report will cover the overall analysis and insights in relation to the size and growth rate of the “Global Advanced Battery Material Market” by various segments at a global and regional level for the 2010-2027 period, with 2010-2020 as historical data, 2021 as a base year, 2022 as an estimated year and forecasts till 2027.

Report Description

  • Advancing lithium ion batteries for the future – Whether it be smartphones or EVs, the same dynamic prevails – customers demand increasing functionality and/or performance from their devices, which demands the same from their energy source. Today, that source consists primarily of batteries based upon lithium-ion technology in a limited set of formulations and configurations. A single electric car requires approximately 4,000 batteries, requiring 4 billion for 1 million EVs. And these are just a couple of the markets driving growth in the battery industry.
  • This study quantifies the consumption of key lithium-ion (Li-ion) battery materials and focuses on gauging the impact that key market developments, like the advancements in battery chemistries, the rapid increase in electric vehicle (EV) sales, an ever-tightening regulatory scenario, and a shift in consumer preferences towards EVs, etc., are expected to have on the demand for individual materials between 2022 and 2027.The study quantifies the consumption of key material types, namely cathode materials, anode materials, electrolytes, separators, binders, and adhesives & sealants. On the basis of applications, the study analyses the demand for battery materials from applications such as EVs, industrial and energy storage systems (ESS), consumer electronics, and others (medical & healthcare devices and portable tools). The study quantifies the consumption of each of these material types on the basis of a robust methodology comprising an analysis of total Li-ion battery production, EV production volumes, uptake of the considered materials, and supply of those materials.

Advance Battery Materials Market

The Advance Battery Materials Report Includes:

  • The report provides a deep dive details of the industry including definitions, classifications and industry chain structure.
  • Analysis of key supply-side and demand trends.
  • Detailed segmentation of international and local products.
  • Historic volume and value sizes, company, and brand market shares.
  • Five-year forecasts of market trends and market growth.
  • Robust and transparent research methodology, conducted in-country.
  • Qualitative and quantitative analysis of the market based on segmentation involving both economic as well as non-economic factors.
  • Provision of market value (USD Billion) data for each segment and sub-segment.
  • Analysis by geography, region, Country, and its states.
  • A brief overview of the commercial potential of products, technologies and applications.
  • Company profiles of leading market participants dealing in products category.
  • Description of properties and manufacturing processes.
  • Market segments on the basis of type, application, end users, region and others.
  • Discussion of the current state, setbacks, innovations, and the future needs of the market.
  • Examination of the market by application and by product sizes; utility scale, medium scale and small scale.
  • Country specific data and analysis for United States, Russia, China, Germany, United Kingdom, France, Japan, Israel, Saudi Arabia, South Korea, United Arab Emirates, Canada, Switzerland, Australia, India, Italy, Turkey, Qatar, Sweden, Spain, Belgium, Netherlands, Norway, Singapore, Egypt, Denmark, Austria, Vietnam, Brazil, Argentina, Mexico, South Africa, and others.
  • Coverage of historical overview, key industrial development and regulatory framework.
  • Analysis of competitive developments, such as contracts & agreements, expansions, new product developments, and mergers & acquisitions in the market.
  • A look at the opportunities in the market for stakeholders and provide a competitive landscape of the market leaders.

Advance Battery Materials Market 2023

Attribute Details
Market size available for years 2014–2027
Base year considered 2020
Forecast period 2021–2027
Historical period 2014-2019
Forecast units Value (USD) & Volume (Million Units)
Forecast units Value (USD) & Volume (Million Units)
Segmentation By Regions
North America, Europe, Asia Pacific, Latin America and Middle East & Africa
By Countries
United States, Russia, China, Germany, United Kingdom, France, Japan, Israel, Saudi Arabia, South Korea, United Arab Emirates, Canada, Switzerland, Australia, India, Italy, Turkey, Qatar, Sweden, Spain, Belgium, Netherlands, Norway, Singapore, Egypt, Denmark, Austria, Vietnam, Brazil, Argentina, Mexico, South Africa, and others.
By Type
Lithium-ion, Lead Acid, Sodium Sulfur, Sodium Metal Halide, Smart Nano Battery, Magnesium Ion, Next-Generation Flow Battery, Metal Air Battery and Nickel  Cadmium and Other.
By Material
Cathode, Anode, Electrolyte, Casing, Separator, Packaging and Others.
By Application
Consumer Electronics, Automotive, Industrial, Energy Storage Systems and Others.
Companies covered Asahi Kasei Corporation; BASF SE; Dowdupont, Inc.; Enerdel, Inc.; Entek International; Gravita India Limited; Gs Yuasa Corporation; Hitachi Chemical Co., Ltd.; Johnson Matthey Plc; Kureha Corporation; L&F; LG Chem Ltd; Mitsubishi Chemical Holdings; Mitsui Mining & Smelting Co., Ltd.; NEI Corporation; Nexeon Limited; Nichia Corporation; Oxis Energy Ltd; Pathion Inc.; Polyplus Battery Company, Inc.; Posco; Pulead Technology Industry Co., Ltd.; Saft Groupe Sa; Samsung Sdi Co.,Ltd.; Shanghai Shanshan Tech Co., Ltd.; Shanshan Technology; Showa Denko K.K.; Siemens; Sion Power Corporation; Sumitomo Corporation; Tanaka Chemical Corp.; Targray Technology International; TCI Chemicals Pvt. Ltd.; Toda Kogyo Corp.; Toray Industries, Inc.; Ube Industries Ltd.; Umicore Cobalt & Specialty Materials (CSM); Zhangjiagang Guotai Huarong Chemical New Material Co., Ltd. and Others.

Based on battery type:

  • Lead-acid battery
  • Lithium ion battery
  • Others

Based on material:

  • Cathode
  • Anode
  • Electrolyte
  • Separator
  • Packaging
  • Casing

Based on application:

  • Portable device
  • Electric vehicle
  • Energy Storage Systems
  • Industrial
  • Household Appliances
  • Automotive
  • Electronics Industry

Objectives of the study

To provide detailed information regarding drivers, restraints, opportunities and challenges are influencing the growth in the respective market. To analyze the competitive intelligence of players based on company profiles and their key growth strategies. To strategically analyze micro markets with respect to the individual growth trends, their prospects, and their contribution to the total respective market. To analyze competitive developments such as expansions, and product launches, along with research & development (R&D) activities undertaken in the respective market. A unique model is created customized for each study also offers suggestions that help enterprises to identify and mitigate risks.

After Sales Support

  • Every updated edition of the report and full data stack will be provided at no extra cost for 24 months.
  • Latest 2021 base year report.
  • No user limitation for the report. Unlimited access within the organization.
  • Unrestricted post-sales support at no additional cost
  • Free report customization (equivalent up to 10 analyst’s working days) with purchase. Addition or alteration to country, regional & segment scope
  • Global Industry Reports will support your post-purchase for a period of 24 months to answer any of your queries related to the following market and to provide you any more data needed, for your analysis.
  • Option to purchase regional or some selected Chapters from the report.

FREQUENTLY ASKED QUESTIONS?

  • What is the total market value?
  • What will be the growth in 2027?
  • What are the key trends in the market?
  • What are the major players in the markets?
  • What are the key growth strategies of industry players?
  • Which region would offer a higher growth?
  • What are the countries included in the rest of the word segments?
  • How can I get report sample?
  • Executive Summary
  • Research Methodology
    • Primary Research
    • Secondary Research
    • Market Analytics
    • Revenue Forecasting
  • Market Overview
    • Market Definition
    • Scope of the Study
      • Research Objectives
      • Assumptions & Limitations
      • Market Structure
    • Market Dynamics
      • Introduction
      • Microeconomic Factor Analysis
      • Market Evolution
      • Technology Roadmap
      • Demand-Supply Dynamics
      • Growth Drivers
      • Restraints
      • Opportunities
      • Challenges
      • Sustainable Strategies
    • Market Trend Analysis (Product Analysis, Technology Analysis, Application Analysis)
    • Industry Analysis
      • Profitability analysis
      • Supply Chain & Value Chain Analysis
      • Porter’s Five Forces Analysis
        • Bargaining power of Suppliers
        • Bargaining Power of Buyers
        • Threat of substitutes
        • Threat of new entrants
        • Degree of Competition
      • PEST Analysis
      • Upstream and downstream profitability analysis and opportunities

Global Market Scope

  1. Market analysis by product category
  2. Market analysis by component / type
  3. Market analysis by technology
  4. Market analysis by application
  5. Market analysis by industry vertical
  6. Market analysis by end-use
  7. Market analysis by emerging technologies, trends and applications
  8. Market analysis by region
    • North America
      • US
      • Canada
      • Mexico
      • Others
    • South America
      • Brazil
      • Argentina
      • Chile
      • Colombia
      • Peru
      • Venezuela
      • Ecuador
      • Others
    • Europe
      • Germany
      • France
      • UK
      • Russia
      • Italy
      • Spain
      • Sweden
      • Netherlands
      • Poland
      • Austria
      • Belgium
      • Finland
      • Norway
      • Switzerland
      • Denmark
      • Czech Republic
      • Portugal
      • Others
    • Asia-Pacific
      • China
      • Japan
      • South Korea
      • Taiwan
      • India
      • Australia
      • Indonesia
      • Philippines
      • Malaysia
      • Others
    • Middle East
      • Iran
      • Turkey
      • Kuwait
      • UAE
      • Israel
      • Oman
      • Bahrain
      • Saudi Arabia
      • Qatar
      • Egypt
      • Others
    • Africa
      • Algeria
      • Libya
      • South Africa
      • Sudan
      • Zimbabwe
      • Others
  1. Competitive Landscape
    • Introduction
    • Market share analysis by key market players (North America, South America, Europe, APAC, Africa)
    • Market Strategy
    • Mergers and Acquisitions
    • New Product Launches
    • Asset Transactions
    • Financial Announcements
  2. Company Profile (key market players)
    • Company profile 1
      • Company Overview
      • Strategic Initiatives
      • Financial Analysis
      • Product Benchmarking
      • SWOT Analysis
    • Company profile 2
      • Company Overview
      • Strategic Initiatives
      • Financial Analysis
      • Product Benchmarking
      • SWOT Analysis
    • Company profile 3
      • Company Overview
      • Strategic Initiatives
      • Financial Analysis
      • Product Benchmarking
      • SWOT Analysis
    • Company profile 4
      • Company Overview
      • Strategic Initiatives
      • Financial Analysis
      • Product Benchmarking
      • SWOT Analysis
    • Company profile 5
      • Company Overview
      • Strategic Initiatives
      • Financial Analysis
      • Product Benchmarking
      • SWOT Analysis
    • Company profile 6
      • Company Overview
      • Strategic Initiatives
      • Financial Analysis
      • Product Benchmarking
      • SWOT Analysis
    • Company profile 7
      • Company Overview
      • Strategic Initiatives
      • Financial Analysis
      • Product Benchmarking
      • SWOT Analysis
    • Company profile 8
      • Company Overview
      • Strategic Initiatives
      • Financial Analysis
      • Product Benchmarking
      • SWOT Analysis
    • Company profile 9
      • Company Overview
      • Strategic Initiatives
      • Financial Analysis
      • Product Benchmarking
      • SWOT Analysis
    • Company profile 10
      • Company Overview
      • Strategic Initiatives
      • Financial Analysis
      • Product Benchmarking
      • SWOT Analysis
  1. Other Companies

150+

Premium Chapters :

1.1 – Multifunctional Gradient Coatings for Scalable, High-Energy-Density

Sulfide-Based Solid-State Batteries

1.2 – Electrolytes for High-Energy, All-Solid-State, Lithium-Metal Batteries

1.3 – Thioborate Solid-State Electrolytes for Practical All-Solid-State Batteries

1.4 – Substituted Argyrodite Solid Electrolytes and High-Capacity Conversion

Cathodes for All-Solid-State Batteries

1.5 – Stable Solid-State Electrolyte and Interface for High-Energy, All-Solid-State,

Lithium-Sulfur Battery

1.6 – Development of Thin, Robust, Lithium-Impenetrable, High-Conductivity,

Electrochemically Stable, Scalable, and Low-Cost Glassy Solid Electrolytes for

Solid-State Lithium Batteries

1.7 – All-Solid-State Batteries Enabled by Multifunctional Electrolyte Materials

1.8 – Developing Materials for High-Energy-Density Solid-State Lithium-Sulfur

Batteries

1.9 – Hot Pressing of Reinforced Lithium-NMC All-Solid-State Batteries with

Sulfide Glass Electrolyte

1.10 – Three-Dimensional Printing of All-Solid-State Lithium Batteries

1.11 – Physical and Mechano-Electrochemical Phenomena of Thin-Film

Lithium-Ceramic Electrolyte Constructs

1.12 – Low Impedance Cathode/Electrolyte Interfaces for High-Energy-Density

Solid-State Batteries

1.13 – Development of All-Solid-State Battery Using Anti-Perovskite Electrolytes

1.14 – Lithium Halide-Based Superionic Solid Electrolytes and High-Voltage Cathode

Interface

1.15 – Developing an In Situ Formed Dynamic Protection Layer to Mitigate Lithium

Interface Shifting: Preventing Dendrite Formation on Metallic Lithium

Surface to Facilitate Long Cycle Life of Lithium Solid-State Batteries

1.16 – Polyester-Based Block Copolymer Electrolytes for Lithium-Metal Batteries

1.17 – Advanced Polymer Materials for Batteries

1.18 – Molecular Ionic Composites: A New Class of Polymer Electrolytes to Enable

All-Solid-State and High-Voltage Lithium Batteries

1.19 – Synthesis of Composite Electrolytes with Integrated Interface Design

1.20 – Polymer Electrolytes for Stable, Low-Impedance, Solid-State Battery

Interfaces

1.21 – Ion Conductive High Li+ Transference Number Polymer Composites for

Solid-State Batteries

1.22 – Inorganic-Polymer-Composite Electrolyte with Architecture Design

for Lithium-Metal Solid-State Batteries

1.23 – Solid-State Batteries with Long Cycle Life and High Energy Density through

Materials Design and Integration

1.24 – Low-Pressure All-Solid-State Cells

1.25 – Precision Control of the Lithium Surface for Solid-State Batteries

2.1 – Characterization and Modeling of Lithium-Metal Batteries: Model-System

Synthesis and Advanced Characterization

2.2 – Interfacial Processes – Diagnostics

2.3 – Advanced In Situ Diagnostic Techniques for Battery Materials

2.4 – Probing Interfacial Processes Controlled Electrode Stability in Rechargeable

Batteries

2.5 – Integrated Atomic-, Meso-, and Micro-Scale Diagnostics of Solid-State

Batteries

2.6 – Fundamental Understanding of Interfacial Phenomena in Solid-State

Batteries

2.7 – Multidimensional Diagnostics of the Interface Evolutions in Solid-State

Lithium Batteries

3 – Modeling

3.1 – Characterization and Modeling of Lithium-Metal Batteries: First-Principles

3.2 – Electrode Materials Design and Failure Prediction

3.3 – Modeling of Amorphous Solid-State Conductors

3.4 – In Situ and Operando Thermal Diagnostics of Buried Interfaces in Beyond

Lithium-Ion Cells

3.5 – Multi-Scale Modeling of Solid-State Electrolytes for Next-Generation

Lithium Batteries

3.6 – First-Principles Modeling of Cluster-Based Solid Electrolytes

3.7 – Predictive Engineering of Interfaces and Cathodes for

High-Performance All-Solid-State Lithium-Sulfur Batteries

3.8 – Predicting the Nucleation and Evolution of Interphases in All-Solid-State

Lithium Batteries

3.9 – Design of Strain Free Cathode – Solid-State Electrolyte Interfaces

Using Chemistry-Informed Deep Learning

3.10 – Tackling Solid-State Electrochemical Interfaces from Structure to Function

Utilizing High-Performance Computing and Machine-Learning Tools

3.11 – Integrated Multiscale Model for Design of Robust, Three-Dimensional,

Solid-State Lithium Batteries

4 – Metallic Lithium

4.1 – Lithium Dendrite Prevention for Lithium Batteries

4.2 – Prelithiation for High-Energy Lithium-Ion Batteries

4.3 – Anode-Free Lithium Batteries

5 – Lithium-Sulfur Batteries

5.1 – Novel Chemistry: Lithium Selenium and Selenium Sulfur Couple

5.2 – Development of High-Energy Lithium-Sulfur Batteries

5.3 – Nanostructured Design of Sulfur Cathodes for High-Energy Lithium-Sulfur

Batteries

5.4 – Investigation of Sulfur Reaction Mechanisms

5.5 – New Electrolytes for Lithium-Sulfur Battery

5.6 – Strategies to Enable Lean Electrolytes for High Loading and Stable Lithium[1]Sulfur Batteries

5.7 – New Engineering Concepts to High-Energy-Density Lithium-Sulfur Batteries

5.8 – Development of Lithium-Sulfur Battery Cells with High Energy Density and

Long Cycle Life

6 – Lithium-Air Batteries

6.1 – Lithium-Air Batteries

6.2 – Lithium Oxygen Battery Design and Predictions

6.3 – Development of a High-Rate Lithium-Air Battery Using a Gaseous

CO2 Reactant

7 – Sodium-Ion Batteries

7.1 – Exploratory Studies of Novel Sodium-Ion Battery Systems

7.2 – Development of a High-Energy Sodium-Ion Battery with Long Life

7.3 – Tailoring High-Capacity, Reversible Anodes for Sodium-Ion Batteries

7.4 – Electrolytes and Interfaces for Stable High-Energy Sodium-Ion Batteries

Methodology

Research Methodology is the process used to collect information and data for the purpose of making business decisions. The success of a research project is entirely dependent on the research methodology adopted by the company. Research Methodology and Scope We have implemented a mix of primary and secondary research for our market estimate and forecast. Secondary research formed the initial phase of our study, where we conducted extensive data mining, referring to verified data sources such as independent studies, company annual reports, white papers, case studies, government and regulatory published articles, technical journals, magazines, and paid data sources. It was also used to obtain important information about the key players and market classification & segmentation according to industry trends to the bottom-most level, and key developments related to market and technology perspectives. A database of the key industry leaders was also prepared using secondary research.

In the primary research process, various primary sources from both supply and demand sides have been interviewed to obtain qualitative and quantitative information important for respective regions. The primary sources from the supply side included industry experts such as CEOs, VPs, marketing directors, technology and innovation directors, and related executives from key companies and organizations operating in the respective regions. The primary data has been collected through questionnaires, e-mails, and telephonic interviews, end-user surveys, consumer surveys, technology distributors and wholesaler’s surveys.

  • Quantitative methods (e.g. surveys) are best for measuring, ranking, categorizing, identifying patterns and making generalizations
  • Qualitative methods (e.g. interviews) are best for describing, interpreting, contextualizing, and gaining in-depth insight into specific concepts or phenomena
  • Mixed methods allow for a combination of numerical measurement and in-depth exploration.

Market drivers and restraints, along with their current and expected impacts, technological scenario and expected developments, end-use industry trends and dynamics  and consumer behavior trends  these forecasting parameters were considered.

Ethical approach, attention to detail, consistency, latest trend in the market and highly authentic source these are benefits of company’s research methodology.

Global Industry Reports

Market size estimation methodology top-down and bottom-up approaches

Both top-down and bottom-up approaches have been used to estimate and validate the total size of the virtual reality market. These methods have also been extensively used to estimate the sizes of various market subsegments. Estimating the size of the market in each region by adding the sizes of country-wise markets and tracking the ongoing and upcoming implementation of virtual reality projects by various companies in each region and forecasting the size of the virtual reality market based on these developments and other critical parameters, including COVID-19 related impacts

Data Triangulation

After arriving at the overall market size—using the market size estimation processes explained above—the market has been split into several segments and subsegments. To complete the overall market engineering process and arrive at the exact statistics of each market segment and subsegment, data triangulation, and market breakdown procedures have been employed, wherever applicable. The data has been triangulated by studying various factors and trends from both the demand and supply sides. It provide detailed information regarding the major factors (drivers, restraints, opportunities, challenges, company profiles, key player strategies competitive developments and key developments) influencing the virtual reality market growth.

Statistical Model

Our market estimates and forecasts are derived through simulation models. A unique model is created customized for each study. Gathered information for market dynamics, technology landscape, application development and pricing trends is fed into the model and analyzed simultaneously. These factors are studied on a comparative basis, and their impact over the forecast period is quantified with the help of correlation, regression and time series analysis.

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