5G Infrastructure Material Market
By Material Type (Organic Material, [Liquid Crystal Material (LCP), Polyimide (PI), Polytetrafluoroethylene (PTFE), Others] Ceramics, Glass),
By Application (Base Stations, Smart Phone),
By End Use (Antenna & Antenna Radome, Microwave Circuits, Circuit Boards & Substrates, Power Amplifiers, Cables, Others),
By Region (North America, Europe, Asia-Pacific, Latin America, Middle East & Africa):
Global Analysis and Forecast 2022-2032.
The global 5G Infrastructure Material market showcased a revenue of USD 132.2 million and more than 8,000 tons in 2021 and is projected to witness a compounded annual growth rate (CAGR) of more than 24.19% over the forecast period of 2022-2032.
Russia-Ukraine War Impact
Market Scope
About the Market
Impact of COVID-19
Global Economic Slowdown
Market Dynamics
Driver
Restrain
Opportunity
Recent Developments
Synopsis
How is this report helpful
FAQ's
Report Coverage
Related Reports
5G is a communication infrastructure that offers notable upgrades to various verticals. Increased internet speed, low latency connection, wider coverage, and improved connectivity are among the primary benefits offered by 5G communication technology. Improved security, reliability, and quality of service have generated a demand for 5G communication systems across the globe in several industry segments such as automotive and transport, industrial, manufacturing, fast-moving consumer goods/durables (FMCG/FMCD), aerospace, military, and defense, among others. Increased speed connectivity and security have allowed these verticals to integrate high bandwidth technologies such as augmented reality (AR), virtual reality (VR), and the Internet of Things (IoT), further escalating the demand for 5G infrastructure across the globe.
The major factor supporting the lucrative growth rate of the 5G infrastructure industry market in the forecast timeframe (2022-2032) will be the increase in the scope of application for high-frequency appliances in different verticals. The rise in such applications has generated a demand for establishing a comprehensive and mature 5G infrastructure, allowing major corporate players to have notable business investments in the market. For instance, in September 2022, the major Indian telecommunication players are expected to invest a total amount of $19.5 billion in 5G infrastructure development by 2025. This investment is forecast to benefit the Indian economy by $445 billion by 2040. Such type of behemoth rollouts of 5G infrastructure development across several developing and under-developed nations across the globe will include several as a major competitive ground for major players.
Furthermore, continued efforts to develop indigenous manufacturing and 5G deployment capabilities by regional players are generating market competitiveness. Each country has a regional market leader, ensuring the majority of the share. For instance, the majority of the North American market is captured by T Mobile, AT&T, Sprint, and Verizon. Major European players include Swisscom, DiGi, Orange France, and Vodafone Germany. The Asia-Pacific region is captured by 5G service providers such as SK Telecom, Reliance Jio, and SoftBank, among others. The Middle Eastern region has MTN, Zain, and Etisalat, among others. Such intense market competitiveness, along with the involvement of regional government towards ownership of frequencies, has created a health market mix. These companies often collaborate with component and service-providing organizations such as Nokia, Ericsson, and Huawei to deploy 5G towers. Substrate material manufacturers also play a vital role in the 5G infrastructure market as they are the core suppliers of ceramics, glass, LCP, PTFE, and PEEK.
Impact of Russia-Ukraine War on 5G Infrastructure Material Market
The Russia-Ukraine war has had a notable impact on the 5G infrastructure material market. The war has a significant negative impact on all semiconductor industries, inline impacting the 5G infrastructure industry as well. There was already a shortage of semiconductor across the globe since COVID-19, as there was a sudden surge in the usage of electronics over the past decade; furthermore, the war situation and trade sanctions by European Union and NATO nations on Russia and Ukraine has worsened the situation. A large amount of trade sanctions were laid against Russia by the U.S. and other NATO nations with a goal to damage their military infrastructure due to lack of electronics; however, a range of telecommunication giants are also impacted due to the same. Following the situation of political conflicts, the Global System for Mobile Communications Association (GSMA) announced that they would not invite the MWC Barcelona trade. The absence of such trade shows will result in a notable loss of business penetration and global engagement opportunities for Russian industry players. The unstable government situation in Russia and Ukraine, with the continuous risk of damaging assets due to war, has forced companies to vacate these regions and shut their operations down. In April 2022, mobile infrastructure developers Ericsson and Nokia announced their exit from the Russian market.
5G Infrastructure Material: Market Scope
The 5G infrastructure market is primarily divided into three segments material type, application, and end user. Furthermore, these segments are subdivided into respective categories and cross-referenced to North America, Europe, Asia-Pacific, Latin America, and Middle East & Africa for regional analysis. The material type segment is segregated by organic material, ceramic, and glass. The organic material segment is further bifurcated into Liquid Crystal Material (LCP), Polyimide (PI), Polytetrafluoroethylene (PTFE), and Others. The application segment within the 5G infrastructure material market is divided into the base station and smartphone. The end-user segment encompasses Antenna, Antenna Radome, Microwave Circuits, Circuit Boards & Substrates, Power Amplifiers, Cables, and Others. Each of these segments is further classified into regions: North America, Europe, Asia-Pacific, Latin America, and Middle East & Africa. The historical dataset of value (USD Million) and volume (Tons) of 2017-2021 is provided in the report, whereas the forecast period of 2022-2032 is offered.
Organic material will capture the highest market share within the material type segment.
The organic material segment within the material type segment of the 5G infrastructure market will capture the highest market share during the forecast period, followed by an aggressive growth rate between 2022-2032. The high growth rate of organic material is attributed to the increasing demand for thermosetting insulating materials such as Liquid Crystal Material (LCP), Polyimide (PI), Polytetrafluoroethylene (PTFE), and Others in the semiconductor industry. Excellent insulation properties, corrosion resistance, temperature resistance, and long-term operations without wear and tear are some of the primary attributes supporting the demand for organic material within the 5G infrastructure market. Various organic materials, depending upon their properties, have found their application within the smartphone antenna or base station antenna. The segment is further divided by Liquid Crystal Material (LCP), Polyimide (PI), Polytetrafluoroethylene (PTFE), and Others as well.
The base station antenna segment will witness the highest growth rate between 2022-2032
The base station antenna within the 5G infrastructure material market will capture the highest market share in terms of value and volume within the forecast timeframe. The escalating integration of high bandwidth applications such as augmented reality (AR) and virtual reality (VR) devices, followed by the Internet of Things (IoT) and artificial intelligence (AI) in various segments, has generated a demand for strong and comprehensive 5G infrastructure, supporting the need of base stations. China, India, the U.S., and South Korea are forecasted to be the largest consumer of the market within the base station segment. The continuous rise in demand for 5G base stations and an increasing number of suppliers have generated market competitiveness. Companies across the globe engaged in developing more effective and low-cost 5G base stations, supporting business requirements. For instance, in November 2021, Huawei announced the launch of multiple input multiple outputs (MIMO) base station 5G antenna that operates on much lower power while offering higher speed and latency.
The antenna & antenna radome segment will capture the highest market share in the coming years.
The antenna and antenna radome segment within the end use of the 5G infrastructure material market is backed by increasing 5G infrastructure development across the globe. The rise in requirement for fast connectivity solutions on moving vehicles such as aircraft and commercial vehicles also supports the region's business opportunities. Companies across the globe are engaged in designing aerodynamic radome to ensure zero operational drag. For instance, in January 2020, ThinKom Solutions announced the launch of an aerodynamic antenna radome offering near zero drag. Industry players are also offering customized radome as per the client's requirement to ensure higher market penetration.
Asia-Pacific to capture the highest market share in the 5G Infrastructure Material Market.
The Asia-Pacific region will capture the highest market share in the 5G infrastructure material market, followed by a lucrative growth rate within the forecast timeframe. The mass manufacturing of semiconductors within China, India, and Japan backs the higher growth rate within the 5G infrastructure material. The higher density of internet users across Asia-Pacific as compared to North America and European is also one of the major factors driving the regional growth. The rise in indigenous efforts and subsidiaries provided by countries to ensure regional supply chain across the market, followed by rising application of 5G infrastructure such as higher upload and download speed on a personal and corporate level, the introduction of connected vehicles, penetration of Internet of Things (IoT) and quick adoption of industry 4.0.
Impact of COVID-19 on the 5G Infrastructure Material Industry
COVID-19 had a notable impact on the 5G infrastructure industry, followed by the rippling effect of the already suffering semiconductor industry. The 5G infrastructure material industry has a huge dependency on the semiconductor industry. The lack of trade and transport of substrate material had a major impact on regional manufacturers and service providers. Post-COVID-19, there was a notable inflation in the pricing of these materials, directly impacting the bottom line of business operations. Furthermore, reduced sales of connected devices and services across the globe further hindered the profit margins of the company.
5G Infrastructure Material: Market Dynamics
The market dynamics section of the report covers a depth analysis of drivers and restraints opportunities impacting the 5G Infrastructure material market. The report also encompasses major market strategies practiced by the industry, followed by patent analysis, product analysis, competitive benchmarking of companies, PORTER and PESTLE analysis of the 5G infrastructure material industry, pricing analysis, and geographic competitiveness to provide a detailed understanding. The major players operating the market are AGC Inc., Daikin Industries, Ltd., DuPont de Nemours, Inc, Hitachi Chemical Company, Ltd., ITEQ Corporation, Kaneka Corporation, Kuraray Co., Ltd., Panasonic Corporation, PolyOne Corporation, Rogers Corporation. These companies cumulatively hold most of the 5G infrastructure material market share and actively undergoes strategic development, such as new product launch, merger, collaboration, business expansion, acquisition, and long-term contracts to ensure market penetration. These companies also largely focus on research and development to gain technological competitiveness in the market. A detailed analysis of these companies is offered in the report.
Driver: Roll out of 5G technology across several nations
Countries aim to develop advanced 5G plans and a more extensive core network of base stations and equipment as they compete to implement 5G networks. Countries such as the U.S., South Korea, Japan, and China have showcased notable development towards integrating and adopting 5G technologies through investments and developing of their telecom sectors. One of the top nations that are excelling in different facets of 5G deployment is China. This is primarily because of the government's strategic planning and coordination with key players in the 5G industry. Various nations' governments fully support the manufacture of 5G infrastructure components by telecom vendors. A nation's economic position will benefit from the rollout of 5G, which is motivating various national governments to speed up deployment. For instance, in close collaboration with 5G equipment manufacturers and technology providers, the Chinese government has invested a significant $400 billion in the deployment of 5G. The demand for 5G substrate materials is anticipated to significantly increase on the global market as a result of the rapid rollout of 5G, offering plenty of room for expansion for businesses that produce 5G substrate materials.
Restrain the High cost of semiconductors and other substrate materials.
The commercial launch of 5G technology is underway, and sectors are adopting it at an ever-increasing rate. The main issue limiting the development of 5G technology is the high cost of the necessary infrastructure. Businesses must invest a sizable amount of money to make their business 5G-enabled in conjunction with the Internet of Things. High-frequency operating equipment and antennas are necessary for these services. Material costs primarily cause the high cost of 5G infrastructure. High-performance materials with a very low dielectric constant, moisture resistance, and minimal transmission losses are among the properties that the mm-wave components need. Companies like Rogers Corporation, PolyOne Corporation, and Panasonic Corporation are creating materials delivery systems that are extremely efficient but also quite expensive.
Opportunity: Global telecommunication companies target developing and underdeveloped countries
The fifth generation, or 5G, of telecommunications technology promises an improvement for the sector. Better connection and IoT capabilities provided by 5G technology enable industries to increase their annual revenue generation. With 5G technology, productivity, and innovation will advance thanks to its fast speed, low latency, and high throughput. Developing nations that are in the early stages of trials and infrastructure deployment for 5G could provide lucrative investment opportunities for material makers. Companies can make investments or increase the size of their production plants in these nations to be near their customers and to get ready for the upcoming expansion of the global 5G infrastructure. The governments of various nations are actively assisting businesses with their investments in and working on creating 5G-related materials and equipment to help them roll out 5G at an effective pace within the anticipated schedule. To fulfill the rising demand coming from Asian nations, major companies, including Panasonic Corporation, Kuraray Co., Ltd., and DuPont de Nemours, Inc., are expanding their production facilities in the Asia-Pacific area. To meet the specialized demands of end users, material makers should try to connect with 5G antenna producers in developing nations and work on a contract basis. So advancing their total growth in the material industry and seizing fresh market prospects.
5G Infrastructure Material Market: Recent Developments
- In November 2022, India was expected to witness the world's largest 5G rollout over the coming years, with more than 800 million active mobile devices. The rollout created a notable business demand within the Asia-Pacific region.
- In July 2022, IDTechEx announced its research into thermal management for 5G infrastructure and semiconductor technology has allowed them to explore challenges related to the deification of electronics leading to even higher latency and transfer speed.
5G Infrastructure Material Market: Synopsis
The study of the 5G infrastructure material market offers revenue and growth data sets in terms of value and volume of segments which are provided at the global level, regional level, and country level. The historical data set of 2017-2021 is offered in the report, along with the forecast period of 2022-2032. For the purpose of analysis, Quadrant Market Insights (QMI) has segregated the 5G infrastructure material market into three major segments as follows:
By Material Type
- Organic Material
- Liquid Crystal Material (LCP)
- Polyimide (PI)
- Polytetrafluoroethylene (PTFE)
- Others - Ceramics
- Glass
By Application
- Base Station
- Smart Phone
By End Use
- Antenna & Antenna Radome
- Microwave Circuits, Circuit Boards & Substrates
- Power Amplifiers
- Cables
- Others
The regional analysis of the 5G infrastructure material market is as follows:
North America
- U.S.
- Canada
- Mexico
Europe
- UK
- Germany
- France
- Russia
- Italy
- Spain
- Rest of Europe
Asia-Pacific
- China
- India
- Japan
- Australia
- Rest of Asia-Pacific
Latin America
- Brazil
- Mexico
- Argentina
- Chile
Middle East & Africa
- South Africa
- UAE
- Saudi Arabia
- Israel
Key players operating in the 5G infrastructure material industry are:
- AGC Inc.
- Daikin Industries, Ltd.
- DuPont de Nemours, Inc
- Hitachi Chemical Company, Ltd.
- ITEQ Corporation
- Kaneka Corporation
- Kuraray Co., Ltd.
- Panasonic Corporation
- PolyOne Corporation
- Rogers Corporation
5G Infrastructure Material Market: Who Should Purchase, and How It Will Help Readers
- The report is best suited for top-level decision-makers, individuals who are supposed to take a leadership role or require market research to start a business, independent researchers, research institutes, and anyone who wishes to gain detailed strategic insights into the 5G infrastructure material market.
- This report provides a qualitative and quantitative analysis of the market segments, current trends, estimations, and dynamics of the 5G infrastructure material market analysis from 2017 to 2032 to identify the prevailing market opportunities.
- Market research and information related to key drivers, restraints, and opportunities are offered.
- Porter's five forces and PESTLE analysis highlight the potency of buyers and suppliers to enable stakeholders' market profit-oriented business decisions and strengthen their supplier-buyer network.
- An in-depth analysis of the 5G infrastructure material segmentation assists in determining the prevailing market opportunities.
- Major countries in each region are mapped according to their revenue contribution to the global market.
- Market player positioning facilitates benchmarking and provides a clear understanding of the present position of the market players.
- The report includes an analysis of the regional and global 5G infrastructure material industry trends, key players, market segments, application areas, and market growth strategies.
- The report offers insights from primary interviews and CXOs of major industry players. It also offers a comprehensive contact and event repository to ensure future collaborations among industry stakeholders.
5G Infrastructure Material Market: Frequently Asked Questions (FAQ)
Q: How big is the 5G infrastructure material market?
A: The global 5G Infrastructure Material market showcased a revenue of USD 132.2 million and more than 8,000 tons in 2021 and is projected to witness a compounded annual growth rate (CAGR)of more than 24.19% over the forecast period of 2022-2032.
Q: Does the report have several 5G infrastructure material bifurcated by segments and regions?
A: The report offers a total number of 5G infrastructure material , further bifurcated into segments and regions. Please refer to the TOC page for more information.
Q: What are the major trends in the 5G infrastructure material market?
A: The rise in awareness from the consumer end about various usage and benefits of 5G infrastructure material , followed by increasing research and development by major industry players across the globe, are major trends expected to shape the market opportunities over the coming years.
Q: How can I get the sample Report on the 5G infrastructure material market?
A: The 5G infrastructure material market report sample can be obtained on demand from the website. Also, 24*7 chat support and direct call services are provided to procure the sample report
Q: Is it possible to purchase a specific or customized report as per my needs
A: Yes, it is possible to purchase a specific part of the report or edit the scope of the report at your convenience. Feel free to drop us the mail/talk to our customer support or schedule a conversation to procure a customized report.
Report Coverage
- Material Type
- Application
- End Use
- North America
- Europe
- Asia-Pacific
- Latin America
- Middle East & Africa
- Roll out of 5G technology across several nations
- Government initiatives and polices supporting 5G rollout
- Improving economic conditions, globalisation and international trade and transactions
- Global telecommunication companies target developing and underdeveloped countries
- Emerging technologies demand more stable connection with larger bandwidth
- E-Commerce, and digitisation of crucial business operations
- High cost of semi-conductors and other substrate material
- Intense competition
AGC Inc., Daikin Industries, Ltd., DuPont de Nemours, Inc, Hitachi Chemical Company, Ltd., ITEQ Corporation, Kaneka Corporation, Kuraray Co., Ltd., Panasonic Corporation, PolyOne Corporation, Rogers Corporation
1. Introduction
1.1 Report Description
1.1.1 Definition
1.1.2 Abbreviations
1.2 Key Market Segments
1.3 Benefits to Stakeholders
1.4 Research Methodology
1.4.1 Market Scoping
1.4.1.1 Problem Identification
1.4.1.2 Defining the Market
1.4.2 Market Estimation
1.4.2.1 Data Mining
1.4.2.2 Product Analysis
1.4.2.3 Application Analysis
1.4.2.4 Market Engineering and Forecasting
1.4.2.4.1 Bottom-up Demand Side
1.4.2.4.2 Bottom-up Supply side
1.4.3 Market Authentication
1.4.3.1 Data Triangulation
1.4.3.1.1 Top-down Supply Side
1.4.3.1.2 Top-down Demand Side
1.4.3.1.3 Data Triangulation
1.4.3.2 Primary Insights and Industry feedback
1.4.4 Report Writing
2. Executive Summary
2.1 Market Snapshot
2.2 Primary Insights
3. Market Overview
3.1 Market Segment and Scope
3.2 Top Investment Pockets
3.3 Key Strategic Initiatives
3.4 Artificial Skin Market Industry Ecosystem
3.5 Market Evolution
3.6 Patent Analysis
3.7 Technology Landscape
3.8 Regulatory Infrastructure
3.9 Porter’s Analysis
3.9.1 Bargaining Power of Buyer
3.9.2 Bargaining Power of Supplier
3.9.3 Threat of New Entrants
3.9.4 Threat of Substitutes
3.9.5 Industry Rivalry
3.10 PESTLE Analysis
3.11 Market Dynamics
3.11.1 Drivers
3.11.2 Restrains
3.11.3 Opportunities
3.12 Impact of COVID-19 on Artificial Skin Market
3.13 Russia-Ukraine War Impact on Artificial Skin Market
3.14 Growth Share Matrix
3.15 Artificial Skin Market Quadrant
4. 5G Infrastructure Material Market, By Material Type
4.1 Major Impacting Factors, By Material Type
4.1.1 Key Market Trends and Growth Factors
4.1.2 Market Size and Forecast, by Region, 2017-2032, (USD Million), (tons)
4.1.3 Market Size and Forecast, by Country, 2017-2032, (USD Million), (tons)
4.2 Organic Material
4.2.1 Key Market Trends and Growth Factors
4.2.2 Market Size and Forecast, by Region, 2017-2032, (USD Million), (tons)
4.2.3 Market Size and Forecast, by Country, 2017-2032, (USD Million), (tons)
4.2.4 Liquid Crystal Material (LCP)
4.2.4.1 Key Market Trends and Growth Factors
4.2.4.2 Market Size and Forecast, by Region, 2017-2032, (USD Million), (tons)
4.2.4.3 Market Size and Forecast, by Country, 2017-2032, (USD Million), (tons)
4.2.5 Polyimide (PI)
4.2.5.1 Key Market Trends and Growth Factors
4.2.5.2 Market Size and Forecast, by Region, 2017-2032, (USD Million), (tons)
4.2.5.3 Market Size and Forecast, by Country, 2017-2032, (USD Million), (tons)
4.2.6 Polytetrafluoroethylene (PTFE)
4.2.6.1 Key Market Trends and Growth Factors
4.2.6.2 Market Size and Forecast, by Region, 2017-2032, (USD Million), (tons)
4.2.6.3 Market Size and Forecast, by Country, 2017-2032, (USD Million), (tons)
4.2.7 Others
4.2.7.1 Key Market Trends and Growth Factors
4.2.7.2 Market Size and Forecast, by Region, 2017-2032, (USD Million), (tons)
4.2.7.3 Market Size and Forecast, by Country, 2017-2032, (USD Million), (tons)
4.3 Ceramics
4.3.1 Key Market Trends and Growth Factors
4.3.2 Market Size and Forecast, by Region, 2017-2032, (USD Million), (tons)
4.3.3 Market Size and Forecast, by Country, 2017-2032, (USD Million), (tons)
4.4 Glass
4.4.1 Key Market Trends and Growth Factors
4.4.2 Market Size and Forecast, by Region, 2017-2032, (USD Million), (tons)
4.4.3 Market Size and Forecast, by Country, 2017-2032, (USD Million), (tons)
5. 5G Infrastructure Material Market, By Application
5.1 Major Impacting Factors, By Application
5.1.1 Key Market Trends and Growth Factors
5.1.2 Market Size and Forecast, by Region, 2017-2032, (USD Million), (tons)
5.1.3 Market Size and Forecast, by Country, 2017-2032, (USD Million), (tons)
5.2 Base Station
5.2.1 Key Market Trends and Growth Factors
5.2.2 Market Size and Forecast, by Region, 2017-2032, (USD Million), (tons)
5.2.3 Market Size and Forecast, by Country, 2017-2032, (USD Million), (tons)
5.3 Smart Phone
5.3.1 Key Market Trends and Growth Factors
5.3.2 Market Size and Forecast, by Region, 2017-2032, (USD Million), (tons)
5.3.3 Market Size and Forecast, by Country, 2017-2032, (USD Million), (tons)
6. 5G Infrastructure Material Market, By Application
6.1 Major Impacting Factors, By End Use
6.1.1 Key Market Trends and Growth Factors
6.1.2 Market Size and Forecast, by Region, 2017-2032, (USD Million), (tons)
6.1.3 Market Size and Forecast, by Country, 2017-2032, (USD Million), (tons)
6.2 Antenna & Antenna Radome
6.2.1 Key Market Trends and Growth Factors
6.2.2 Market Size and Forecast, by Region, 2017-2032, (USD Million), (tons)
6.2.3 Market Size and Forecast, by Country, 2017-2032, (USD Million), (tons)
6.3 Microwave Circuits, Circuit Boards & Substrates
6.3.1 Key Market Trends and Growth Factors
6.3.2 Market Size and Forecast, by Region, 2017-2032, (USD Million), (tons)
6.3.3 Market Size and Forecast, by Country, 2017-2032, (USD Million), (tons)
6.4 Power Amplifiers
6.4.1 Key Market Trends and Growth Factors
6.4.2 Market Size and Forecast, by Region, 2017-2032, (USD Million), (tons)
6.4.3 Market Size and Forecast, by Country, 2017-2032, (USD Million), (tons)
6.5 Cables
6.5.1 Key Market Trends and Growth Factors
6.5.2 Market Size and Forecast, by Region, 2017-2032, (USD Million), (tons)
6.5.3 Market Size and Forecast, by Country, 2017-2032, (USD Million), (tons)
6.6 Others
6.6.1 Key Market Trends and Growth Factors
6.6.2 Market Size and Forecast, by Region, 2017-2032, (USD Million), (tons)
6.6.3 Market Size and Forecast, by Country, 2017-2032, (USD Million), (tons)
7. 5G Infrastructure Material Market, By Region
7.1 Global Market Trends and Growth Factors
7.2 Market Size and Forecast, by Material Type, 2017-2032, (USD Million), (tons)
7.2.1 Market Size and Forecast, by Organic Material, 2017-2032, (USD Million), (tons)
7.3 Market Size and Forecast, by Application, 2017-2032, (USD Million), (tons)
7.4 Market Size and Forecast, by End Use, 2017-2032, (USD Million), (tons)
7.5 Market Size and Forecast, by Region, 2017-2032, (USD Million), (tons)
7.6 North America
7.6.1 Key Market Trends and Growth Factors
7.6.2 Market Size and Forecast, by Material Type, 2017-2032, (USD Million), (tons)
7.6.2.1 Market Size and Forecast, by Organic Material, 2017-2032, (USD Million), (tons)
7.6.3 Market Size and Forecast, by Application, 2017-2032, (USD Million), (tons)
7.6.4 Market Size and Forecast, by End Use, 2017-2032, (USD Million), (tons)
7.6.5 Market Size and Forecast, by Country, 2017-2032, (USD Million), (tons)
7.6.6 U.S.
7.6.6.1 Market Size and Forecast, by Material Type, 2017-2032, (USD Million), (tons)
7.6.6.1.1 Market Size and Forecast, by Organic Material, 2017-2032, (USD Million), (tons)
7.6.6.2 Market Size and Forecast, by Application, 2017-2032, (USD Million), (tons)
7.6.6.3 Market Size and Forecast, by End Use, 2017-2032, (USD Million), (tons)
7.6.7 Canada
7.6.7.1 Market Size and Forecast, by Material Type, 2017-2032, (USD Million), (tons)
7.6.7.1.1 Market Size and Forecast, by Organic Material, 2017-2032, (USD Million), (tons)
7.6.7.2 Market Size and Forecast, by Application, 2017-2032, (USD Million), (tons)
7.6.7.3 Market Size and Forecast, by End Use, 2017-2032, (USD Million), (tons)
7.6.8 Mexico
7.6.8.1 Market Size and Forecast, by Material Type, 2017-2032, (USD Million), (tons)
7.6.8.1.1 Market Size and Forecast, by Organic Material, 2017-2032, (USD Million), (tons)
7.6.8.2 Market Size and Forecast, by Application, 2017-2032, (USD Million), (tons)
7.6.8.3 Market Size and Forecast, by End Use, 2017-2032, (USD Million), (tons)
7.7 Europe
7.7.1 Key Market Trends and Growth Factors
7.7.2 Market Size and Forecast, by Material Type, 2017-2032, (USD Million), (tons)
7.7.2.1 Market Size and Forecast, by Organic Material, 2017-2032, (USD Million), (tons)
7.7.3 Market Size and Forecast, by Application, 2017-2032, (USD Million), (tons)
7.7.4 Market Size and Forecast, by End Use, 2017-2032, (USD Million), (tons)
7.7.5 Market Size and Forecast, by Country, 2017-2032, (USD Million), (tons)
7.7.6 UK
7.7.6.1 Market Size and Forecast, by Material Type, 2017-2032, (USD Million), (tons)
7.7.6.1.1 Market Size and Forecast, by Organic Material, 2017-2032, (USD Million), (tons)
7.7.6.2 Market Size and Forecast, by Application, 2017-2032, (USD Million), (tons)
7.7.6.3 Market Size and Forecast, by End Use, 2017-2032, (USD Million), (tons)
7.7.7 Germany
7.7.7.1 Market Size and Forecast, by Material Type, 2017-2032, (USD Million), (tons)
7.7.7.1.1 Market Size and Forecast, by Organic Material, 2017-2032, (USD Million), (tons)
7.7.7.2 Market Size and Forecast, by Application, 2017-2032, (USD Million), (tons)
7.7.7.3 Market Size and Forecast, by End Use, 2017-2032, (USD Million), (tons)
7.7.8 France
7.7.8.1 Market Size and Forecast, by Material Type, 2017-2032, (USD Million), (tons)
7.7.8.1.1 Market Size and Forecast, by Organic Material, 2017-2032, (USD Million), (tons)
7.7.8.2 Market Size and Forecast, by Application, 2017-2032, (USD Million), (tons)
7.7.8.3 Market Size and Forecast, by End Use, 2017-2032, (USD Million), (tons)
7.7.9 Russia
7.7.9.1 Market Size and Forecast, by Material Type, 2017-2032, (USD Million), (tons)
7.7.9.1.1 Market Size and Forecast, by Organic Material, 2017-2032, (USD Million), (tons)
7.7.9.2 Market Size and Forecast, by Application, 2017-2032, (USD Million), (tons)
7.7.9.3 Market Size and Forecast, by End Use, 2017-2032, (USD Million), (tons)
7.7.10 Italy
7.7.10.1 Market Size and Forecast, by Material Type, 2017-2032, (USD Million), (tons)
7.7.10.1.1 Market Size and Forecast, by Organic Material, 2017-2032, (USD Million), (tons)
7.7.10.2 Market Size and Forecast, by Application, 2017-2032, (USD Million), (tons)
7.7.10.3 Market Size and Forecast, by End Use, 2017-2032, (USD Million), (tons)
7.7.11 Rest of Europe
7.7.11.1 Market Size and Forecast, by Material Type, 2017-2032, (USD Million), (tons)
7.7.11.1.1 Market Size and Forecast, by Organic Material, 2017-2032, (USD Million), (tons)
7.7.11.2 Market Size and Forecast, by Application, 2017-2032, (USD Million), (tons)
7.7.11.3 Market Size and Forecast, by End Use, 2017-2032, (USD Million), (tons)
7.8 Asia-Pacific
7.8.1 Key Market Trends and Growth Factors
7.8.2 Market Size and Forecast, by Material Type, 2017-2032, (USD Million), (tons)
7.8.2.1 Market Size and Forecast, by Organic Material, 2017-2032, (USD Million), (tons)
7.8.3 Market Size and Forecast, by Application, 2017-2032, (USD Million), (tons)
7.8.4 Market Size and Forecast, by End Use, 2017-2032, (USD Million), (tons)
7.8.5 Market Size and Forecast, by Country, 2017-2032, (USD Million), (tons)
7.8.6 China
7.8.6.1 Market Size and Forecast, by Material Type, 2017-2032, (USD Million), (tons)
7.8.6.1.1 Market Size and Forecast, by Organic Material, 2017-2032, (USD Million), (tons)
7.8.6.2 Market Size and Forecast, by Application, 2017-2032, (USD Million), (tons)
7.8.6.3 Market Size and Forecast, by End Use, 2017-2032, (USD Million), (tons)
7.8.7 India
7.8.7.1 Market Size and Forecast, by Material Type, 2017-2032, (USD Million), (tons)
7.8.7.1.1 Market Size and Forecast, by Organic Material, 2017-2032, (USD Million), (tons)
7.8.7.2 Market Size and Forecast, by Application, 2017-2032, (USD Million), (tons)
7.8.7.3 Market Size and Forecast, by End Use, 2017-2032, (USD Million), (tons)
7.8.8 Japan
7.8.8.1 Market Size and Forecast, by Material Type, 2017-2032, (USD Million), (tons)
7.8.8.1.1 Market Size and Forecast, by Organic Material, 2017-2032, (USD Million), (tons)
7.8.8.2 Market Size and Forecast, by Application, 2017-2032, (USD Million), (tons)
7.8.8.3 Market Size and Forecast, by End Use, 2017-2032, (USD Million), (tons)
7.8.9 Australia
7.8.9.1 Market Size and Forecast, by Material Type, 2017-2032, (USD Million), (tons)
7.8.9.1.1 Market Size and Forecast, by Organic Material, 2017-2032, (USD Million), (tons)
7.8.9.2 Market Size and Forecast, by Application, 2017-2032, (USD Million), (tons)
7.8.9.3 Market Size and Forecast, by End Use, 2017-2032, (USD Million), (tons)
7.8.10 Rest of Asia-Pacific
7.8.10.1 Market Size and Forecast, by Material Type, 2017-2032, (USD Million), (tons)
7.8.10.1.1 Market Size and Forecast, by Organic Material, 2017-2032, (USD Million), (tons)
7.8.10.2 Market Size and Forecast, by Application, 2017-2032, (USD Million), (tons)
7.8.10.3 Market Size and Forecast, by End Use, 2017-2032, (USD Million), (tons)
7.9 Latin America
7.9.1 Key Market Trends and Growth Factors
7.9.2 Market Size and Forecast, by Material Type, 2017-2032, (USD Million), (tons)
7.9.2.1 Market Size and Forecast, by Organic Material, 2017-2032, (USD Million), (tons)
7.9.3 Market Size and Forecast, by Application, 2017-2032, (USD Million), (tons)
7.9.4 Market Size and Forecast, by End Use, 2017-2032, (USD Million), (tons)
7.9.5 Market Size and Forecast, by Country, 2017-2032, (USD Million), (tons)
7.9.6 Brazil
7.9.6.1 Market Size and Forecast, by Material Type, 2017-2032, (USD Million), (tons)
7.9.6.1.1 Market Size and Forecast, by Organic Material, 2017-2032, (USD Million), (tons)
7.9.6.2 Market Size and Forecast, by Application, 2017-2032, (USD Million), (tons)
7.9.6.3 Market Size and Forecast, by End Use, 2017-2032, (USD Million), (tons)
7.9.7 Argentina
7.9.7.1 Market Size and Forecast, by Material Type, 2017-2032, (USD Million), (tons)
7.9.7.1.1 Market Size and Forecast, by Organic Material, 2017-2032, (USD Million), (tons)
7.9.7.2 Market Size and Forecast, by Application, 2017-2032, (USD Million), (tons)
7.9.7.3 Market Size and Forecast, by End Use, 2017-2032, (USD Million), (tons)
7.9.8 Mexico
7.9.8.1 Market Size and Forecast, by Material Type, 2017-2032, (USD Million), (tons)
7.9.8.1.1 Market Size and Forecast, by Organic Material, 2017-2032, (USD Million), (tons)
7.9.8.2 Market Size and Forecast, by Application, 2017-2032, (USD Million), (tons)
7.9.8.3 Market Size and Forecast, by End Use, 2017-2032, (USD Million), (tons)
7.9.9 Chile
7.9.9.1 Market Size and Forecast, by Material Type, 2017-2032, (USD Million), (tons)
7.9.9.1.1 Market Size and Forecast, by Organic Material, 2017-2032, (USD Million), (tons)
7.9.9.2 Market Size and Forecast, by Application, 2017-2032, (USD Million), (tons)
7.9.9.3 Market Size and Forecast, by End Use, 2017-2032, (USD Million), (tons)
7.10 Middle East and Africa
7.10.1 Key Market Trends and Growth Factors
7.10.2 Market Size and Forecast, by Material Type, 2017-2032, (USD Million), (tons)
7.10.2.1 Market Size and Forecast, by Organic Material, 2017-2032, (USD Million), (tons)
7.10.3 Market Size and Forecast, by Application, 2017-2032, (USD Million), (tons)
7.10.4 Market Size and Forecast, by End Use, 2017-2032, (USD Million), (tons)
7.10.5 Market Size and Forecast, by Country, 2017-2032, (USD Million), (tons)
7.10.6 South Africa
7.10.6.1 Market Size and Forecast, by Material Type, 2017-2032, (USD Million), (tons)
7.10.6.1.1 Market Size and Forecast, by Organic Material, 2017-2032, (USD Million), (tons)
7.10.6.2 Market Size and Forecast, by Application, 2017-2032, (USD Million), (tons)
7.10.6.3 Market Size and Forecast, by End Use, 2017-2032, (USD Million), (tons)
7.10.7 UAE
7.10.7.1 Market Size and Forecast, by Material Type, 2017-2032, (USD Million), (tons)
7.10.7.1.1 Market Size and Forecast, by Organic Material, 2017-2032, (USD Million), (tons)
7.10.7.2 Market Size and Forecast, by Application, 2017-2032, (USD Million), (tons)
7.10.7.3 Market Size and Forecast, by End Use, 2017-2032, (USD Million), (tons)
7.10.8 Saudi Arabia
7.10.8.1 Market Size and Forecast, by Material Type, 2017-2032, (USD Million), (tons)
7.10.8.1.1 Market Size and Forecast, by Organic Material, 2017-2032, (USD Million), (tons)
7.10.8.2 Market Size and Forecast, by Application, 2017-2032, (USD Million), (tons)
7.10.8.3 Market Size and Forecast, by End Use, 2017-2032, (USD Million), (tons)
7.10.9 Israel
7.10.9.1 Market Size and Forecast, by Material Type, 2017-2032, (USD Million), (tons)
7.10.9.1.1 Market Size and Forecast, by Organic Material, 2017-2032, (USD Million), (tons)
7.10.9.2 Market Size and Forecast, by Application, 2017-2032, (USD Million), (tons)
7.10.9.3 Market Size and Forecast, by End Use, 2017-2032, (USD Million), (tons)
8. Markets-Competitive Benchmarking & Company Profiles
8.1 Competitive Benchmarking
8.1.1 Company Market Share
8.1.2 Product Mapping
8.1.3 Competitive Heat map
8.2 AGC Inc.
8.2.1 Company Overview
8.2.2 Financial Analysis
8.2.3 Product Offering
8.2.4 Strategic Initiatives
8.2.5 SWOT
8.2.6 Ansoff Matrix
8.3 Daikin Industries, Ltd.
8.3.1 Company Overview
8.3.2 Financial Analysis
8.3.3 Product Offering
8.3.4 Strategic Initiatives
8.3.5 SWOT
8.3.6 Ansoff Matrix
8.4 DuPont de Nemours, Inc
8.4.1 Company Overview
8.4.2 Financial Analysis
8.4.3 Product Offering
8.4.4 Strategic Initiatives
8.4.5 SWOT
8.4.6 Ansoff Matrix
8.5 Hitachi Chemical Company, Ltd.
8.5.1 Company Overview
8.5.2 Financial Analysis
8.5.3 Product Offering
8.5.4 Strategic Initiatives
8.5.5 SWOT
8.5.6 Ansoff Matrix
8.6 ITEQ Corporation
8.6.1 Company Overview
8.6.2 Financial Analysis
8.6.3 Product Offering
8.6.4 Strategic Initiatives
8.6.5 SWOT
8.6.6 Ansoff Matrix
8.7 Kaneka Corporation
8.7.1 Company Overview
8.7.2 Financial Analysis
8.7.3 Product Offering
8.7.4 Strategic Initiatives
8.7.5 SWOT
8.7.6 Ansoff Matrix
8.8 Kuraray Co., Ltd.
8.8.1 Company Overview
8.8.2 Financial Analysis
8.8.3 Product Offering
8.8.4 Strategic Initiatives
8.8.5 SWOT
8.8.6 Ansoff Matrix
8.9 Panasonic Corporation
8.9.1 Company Overview
8.9.2 Financial Analysis
8.9.3 Product Offering
8.9.4 Strategic Initiatives
8.9.5 SWOT
8.9.6 Ansoff Matrix
8.10 PolyOne Corporation
8.10.1 Company Overview
8.10.2 Financial Analysis
8.10.3 Product Offering
8.10.4 Strategic Initiatives
8.10.5 SWOT
8.10.6 Ansoff Matrix
8.11 Rogers Corporation
8.11.1 Company Overview
8.11.2 Financial Analysis
8.11.3 Product Offering
8.11.4 Strategic Initiatives
8.11.5 SWOT
8.11.6 Ansoff Matrix
9. Industry Connects and Seminars