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レポート概要
新型コロナウイルス感染症とロシア・ウクライナ戦争の影響により、5G用低損失材料のグローバル市場は 2022にxxxドルと推定され、2028年までにxxxドルの規模に達し、2022年から2028年の予測期間中にxxx%のCAGRで成長すると予測されています。 5G用低損失材料のアメリカ市場は、2023年から2028年の予測期間中にxxx%のCAGRで、2022年xxxドルから2028年xxxドルに達すると推定されています。 5G用低損失材料の中国市場は、2023年から2028年の予測期間中にxxx%のCAGRで、2022年xxxドルから2028年xxxドルに達すると推定されています。 5G用低損失材料のヨーロッパ市場は、2023年から2028年の予測期間中にxxx%のCAGRで、2022年xxxドルから2028年xxxドルに達すると推定されています。 生産面において、本レポートは2017年から2022年までの5G用低損失材料の生産、成長率、メーカー別市場シェア、地域別市場シェア、および2028年までの予測を調査しています。販売面において、本レポートは2017年から2022年までの地域別、企業別、タイプ別、アプリケーション別の5G用低損失材料の売上および2028年までの予測に焦点を当てています。 5G用低損失材料のグローバル主要企業には、DuPont、Sartomer (Arkema)、AGC Chemicals、Toray Industries、Mitsubishi Gas Chemicals、JSR Corp、Hitachi Chemicals、SABIC、Solvay、Kyocera、Sumitomo Bakeliteなどがあります。2021年、世界のトップ5プレイヤーは売上ベースで約xxx%の市場シェアを占めています。 5G用低損失材料市場は、タイプとアプリケーションによって区分されます。世界の5G用低損失材料市場のプレーヤー、利害関係者、およびその他の参加者は、当レポートを有益なリソースとして使用することで優位に立つことができます。セグメント分析は、2017年~2028年期間のタイプ別およびアプリケーション別の販売量、売上、予測に焦点を当てています。 【タイプ別セグメント】 Sub-6 GHz 5G、mmWave 5G 【アプリケーション別セグメント】 スマートプロダクト、インフラ、宅内機器(CPE) 【掲載地域】 北米:アメリカ、カナダ ヨーロッパ:ドイツ、フランス、イギリス、イタリア、ロシア アジア太平洋:日本、中国、韓国、インド、オーストラリア、台湾、インドネシア、タイ、マレーシア 中南米:メキシコ、ブラジル、アルゼンチン 中東・アフリカ:トルコ、サウジアラビア、UAE 【目次(一部)】 ・調査の範囲 - 5G用低損失材料製品概要 - タイプ別市場(Sub-6 GHz 5G、mmWave 5G) - アプリケーション別市場(スマートプロダクト、インフラ、宅内機器(CPE)) - 調査の目的 ・エグゼクティブサマリー - 世界の5G用低損失材料販売量予測2017-2028 - 世界の5G用低損失材料売上予測2017-2028 - 5G用低損失材料の地域別販売量 - 5G用低損失材料の地域別売上 - 北米市場 - ヨーロッパ市場 - アジア太平洋市場 - 中南米市場 - 中東・アフリカ市場 ・メーカーの競争状況 - 主要メーカー別5G用低損失材料販売量 - 主要メーカー別5G用低損失材料売上 - 主要メーカー別5G用低損失材料価格 - 競争状況の分析 - 企業M&A動向 ・タイプ別市場規模(Sub-6 GHz 5G、mmWave 5G) - 5G用低損失材料のタイプ別販売量 - 5G用低損失材料のタイプ別売上 - 5G用低損失材料のタイプ別価格 ・アプリケーション別市場規模(スマートプロダクト、インフラ、宅内機器(CPE)) - 5G用低損失材料のアプリケーション別販売量 - 5G用低損失材料のアプリケーション別売上 - 5G用低損失材料のアプリケーション別価格 ・北米市場 - 北米の5G用低損失材料市場規模(タイプ別、アプリケーション別) - 主要国別の5G用低損失材料市場規模(アメリカ、カナダ) ・ヨーロッパ市場 - ヨーロッパの5G用低損失材料市場規模(タイプ別、アプリケーション別) - 主要国別の5G用低損失材料市場規模(ドイツ、フランス、イギリス、イタリア、ロシア) ・アジア太平洋市場 - アジア太平洋の5G用低損失材料市場規模(タイプ別、アプリケーション別) - 主要国別の5G用低損失材料市場規模(日本、中国、韓国、インド、オーストラリア、台湾、インドネシア、タイ、マレーシア) ・中南米市場 - 中南米の5G用低損失材料市場規模(タイプ別、アプリケーション別) - 主要国別の5G用低損失材料市場規模(メキシコ、ブラジル、アルゼンチン) ・中東・アフリカ市場 - 中東・アフリカの5G用低損失材料市場規模(タイプ別、アプリケーション別) - 主要国別の5G用低損失材料市場規模(トルコ、サウジアラビア) ・企業情報 DuPont、Sartomer (Arkema)、AGC Chemicals、Toray Industries、Mitsubishi Gas Chemicals、JSR Corp、Hitachi Chemicals、SABIC、Solvay、Kyocera、Sumitomo Bakelite ・産業チェーン及び販売チャネル分析 - 5G用低損失材料の産業チェーン分析 - 5G用低損失材料の原材料 - 5G用低損失材料の生産プロセス - 5G用低損失材料の販売及びマーケティング - 5G用低損失材料の主要顧客 ・マーケットドライバー、機会、課題、リスク要因分析 - 5G用低損失材料の産業動向 - 5G用低損失材料のマーケットドライバー - 5G用低損失材料の課題 - 5G用低損失材料の阻害要因 ・主な調査結果 |
The most revolutionary aspect of 5G network relies on the high frequency 5G technologies, i.e. mmWave 5G, which utilize spectrum from 26 GHz up to 40 GHz. At such high frequency, many technologies and devices are facing challenges. The high-frequency signals result in significant transmission loss, require higher power and more efficient power supply, and generate more heat. The transmission loss is a pain point for the antenna design and radio frequency (RF) integrated circuits (ICs) for 5G applications. For low-frequency 5G, i.e. sub-6 GHz 5G, due to the high data transfer speed, reducing signal loss is also desirable. With the future rise of mmWave 5G, low-loss materials will foresee a rapid growth and play an increasingly important role. In this report, we survey the landscape of the low-loss materials and benchmark their performance by five key factors, i.e. dielectric constant (Dk), dissipation factor (Df), moisture absorption, cost, and manufacturability. The scope for the report is shown in figure 2. Low-loss materials will not only be used as substrate or PCB board, but also for advanced packages. One of the strong trends is antenna in package (AiP); as we go higher in frequency towards mmWave, the size of the antenna elements will shrink and the arrays can be fitted into the package itself. This integration will also help shorten the RF paths, and thus minimize the transmission losses. AiP will need low-loss materials for the substrates (redistribution layers as well), electromagnetic interference (EMI) shielding, molded underfill (MUF) materials and more.
Report Overview
Due to the COVID-19 pandemic and Russia-Ukraine War Influence, the global market for Low-loss Materials for 5G estimated at US$ million in the year 2022, is projected to reach a revised size of US$ million by 2028, growing at a CAGR of % during the forecast period 2022-2028.
The USA market for Low-loss Materials for 5G is estimated to increase from $ million in 2022 to reach $ million by 2028, at a CAGR of % during the forecast period of 2023 through 2028.
The China market for Low-loss Materials for 5G is estimated to increase from $ million in 2022 to reach $ million by 2028, at a CAGR of % during the forecast period of 2023 through 2028.
The Europe market for Low-loss Materials for 5G is estimated to increase from $ million in 2022 to reach $ million by 2028, at a CAGR of % during the forecast period of 2023 through 2028.
The global key manufacturers of Low-loss Materials for 5G include DuPont, Sartomer (Arkema), AGC Chemicals, Toray Industries, Mitsubishi Gas Chemicals, JSR Corp, Hitachi Chemicals, SABIC and Solvay, etc. In 2021, the global top five players had a share approximately % in terms of revenue.
In terms of production side, this report researches the Low-loss Materials for 5G production, growth rate, market share by manufacturers and by region (region level and country level), from 2017 to 2022, and forecast to 2028.
In terms of sales side, this report focuses on the sales of Low-loss Materials for 5G by region (region level and country level), by company, by Type and by Application. from 2017 to 2022 and forecast to 2028.
Report Scope
This latest report researches the industry structure, capacity, production, sales (consumption), revenue, price and gross margin. Major producers’ production locations, market shares, industry ranking and profiles are presented. The primary and secondary research is done in order to access up-to-date government regulations, market information and industry data. Data were collected from the Low-loss Materials for 5G manufacturers, distributors, end users, industry associations, governments’ industry bureaus, industry publications, industry experts, third party database, and our in-house databases.
This report also includes a discussion of the major players across each regional Low-loss Materials for 5G market. Further, it explains the major drivers and regional dynamics of the global Low-loss Materials for 5G market and current trends within the industry.
Key Companies Covered
In this section of the report, the researchers have done a comprehensive analysis of the prominent players operating and the strategies they are focusing on to combat the intense competition. Company profiles and market share analysis of the prominent players are also provided in this section. Additionally, the specialists have done an all-encompassing analysis of each player. They have also provided reliable sales, revenue, price, market share and rank data of the manufacturers for the period 2017-2022. With the assistance of this report, key players, stakeholders, and other participants will be able to stay abreast of the recent and upcoming developments in the business, further enabling them to make efficient choices. Mentioned below are the prime players taken into account in this research report:
DuPont
Sartomer (Arkema)
AGC Chemicals
Toray Industries
Mitsubishi Gas Chemicals
JSR Corp
Hitachi Chemicals
SABIC
Solvay
Kyocera
Sumitomo Bakelite
Market Segments
This report has explored the key segments: by Type and by Application. The lucrativeness and growth potential have been looked into by the industry experts in this report. This report also provides sales, revenue and average price forecast data by type and by application segments based on production, price, and value for the period 2017-2028.
Low-loss Materials for 5G Segment by Type
Sub-6 GHz 5G
mmWave 5G
Low-loss Materials for 5G Segment by Application
Smart Products
Infrastructure
Customer Premise Equipment (CPE)
Key Regions & Countries
This section of the report provides key insights regarding various regions and the key players operating in each region. This report analyzes the Low-loss Materials for 5G production by region/country, and the sales (consumption) by region/country. Economic, social, environmental, technological, and political factors have been taken into consideration while assessing the growth of the particular region/country. The readers will also get their hands on the value and sales data of each region and country for the period 2017-2028.
North America
United States
Canada
Europe
Germany
France
U.K.
Italy
Russia
Asia-Pacific
China
Japan
South Korea
India
Australia
China Taiwan
Indonesia
Thailand
Malaysia
Latin America
Mexico
Brazil
Argentina
Colombia
Middle East & Africa
Turkey
Saudi Arabia
UAE
Key Drivers & Barriers
High-impact rendering factors and drivers have been studied in this report to aid the readers to understand the general development. Moreover, the report includes restraints and challenges that may act as stumbling blocks on the way of the players. This will assist the users to be attentive and make informed decisions related to business. Specialists have also laid their focus on the upcoming business prospects.
COVID-19 and Russia-Ukraine War Influence Analysis
The readers in the section will understand how the Low-loss Materials for 5G market scenario changed across the globe during the pandemic, post-pandemic and Russia-Ukraine War. The study is done keeping in view the changes in aspects such as demand, consumption, transportation, consumer behavior, supply chain management, export and import, and production. The industry experts have also highlighted the key factors that will help create opportunities for players and stabilize the overall industry in the years to come.
Report Includes:
This report presents an overview of global market for Low-loss Materials for 5G, capacity, output, revenue and price. Analyses of the global market trends, with historic market revenue/sales data for 2017 – 2021, estimates for 2022, and projections of CAGR through 2028.
This report researches the key producers of Low-loss Materials for 5G, also provides the consumption of main regions and countries. Highlights of the upcoming market potential for Low-loss Materials for 5G, and key regions/countries of focus to forecast this market into various segments and sub-segments. Country specific data and market value analysis for the U.S., Canada, Mexico, Brazil, China, Japan, South Korea, Southeast Asia, India, Germany, the U.K., Italy, Middle East, Africa, and Other Countries.
This report focuses on the Low-loss Materials for 5G sales, revenue, market share and industry ranking of main manufacturers, data from 2017 to 2022. Identification of the major stakeholders in the global Low-loss Materials for 5G market, and analysis of their competitive landscape and market positioning based on recent developments and segmental revenues. This report will help stakeholders to understand the competitive landscape and gain more insights and position their businesses and market strategies in a better way.
This report analyzes the segments data by type and by application, sales, revenue, and price, from 2017 to 2028. Evaluation and forecast the market size for Low-loss Materials for 5G sales, projected growth trends, production technology, application and end-user industry.
Descriptive company profiles of the major global players, including DuPont, Sartomer (Arkema), AGC Chemicals, Toray Industries, Mitsubishi Gas Chemicals, JSR Corp, Hitachi Chemicals, SABIC and Solvay, etc.
Chapter Outline
Chapter 1: Introduces the report scope of the report, executive summary of different market segments (product type, application, etc), including the market size of each market segment, future development potential, and so on. It offers a high-level view of the current state of the market and its likely evolution in the short to mid-term, and long term.
Chapter 2: Low-loss Materials for 5G capacity, production/output of global and key producers (regions/countries). It provides a quantitative analysis of the capacity, production, and development potential of each producer in the next six years.
Chapter 3: Sales (consumption), revenue of Low-loss Materials for 5G in global, regional level and country level. It provides a quantitative analysis of the market size and development potential of each region and its main countries and introduces the market development, future development prospects, market space, and capacity of each country in the world.
Chapter 4: Detailed analysis of Low-loss Materials for 5G manufacturers competitive landscape, price, sales, revenue, market share and industry ranking, latest development plan, merger, and acquisition information, etc.
Chapter 5: Provides the analysis of various market segments according to product types, covering the sales, revenue, average price, and development potential of each market segment, to help readers find the blue ocean market in different market segments.
Chapter 6: Provides the analysis of various market segments according to application, covering the sales, revenue, average price, and development potential of each market segment, to help readers find the blue ocean market in different downstream markets.
Chapter 7: North America by type, by application and by country, sales and revenue for each segment.
Chapter 8: Europe by type, by application and by country, sales and revenue for each segment.
Chapter 9: Asia Pacific by type, by application and by country, sales and revenue for each segment.
Chapter 10: Latin America by type, by application and by country, sales and revenue for each segment.
Chapter 11: Middle East and Africa by type, by application and by country, sales and revenue for each segment.
Chapter 12: Provides profiles of key manufacturers, introducing the basic situation of the main companies in the market in detail, including product descriptions and specifications, Low-loss Materials for 5G sales, revenue, price, gross margin, and recent development, etc.
Chapter 13: Analysis of industrial chain, sales channel, key raw materials, distributors and customers.
Chapter 14: Introduces the market dynamics, latest developments of the market, the driving factors and restrictive factors of the market, the challenges and risks faced by manufacturers in the industry, and the analysis of relevant policies in the industry.
Chapter 15: The main points and conclusions of the report.
1 Study Coverage
1.1 Low-loss Materials for 5G Product Introduction
1.2 Market by Type
1.2.1 Global Low-loss Materials for 5G Market Size by Type, 2017 VS 2021 VS 2028
1.2.2 Sub-6 GHz 5G
1.2.3 mmWave 5G
1.3 Market by Application
1.3.1 Global Low-loss Materials for 5G Market Size by Application, 2017 VS 2021 VS 2028
1.3.2 Smart Products
1.3.3 Infrastructure
1.3.4 Customer Premise Equipment (CPE)
1.4 Study Objectives
1.5 Years Considered
2 Global Low-loss Materials for 5G Production
2.1 Global Low-loss Materials for 5G Production Capacity (2017-2028)
2.2 Global Low-loss Materials for 5G Production by Region: 2017 VS 2021 VS 2028
2.3 Global Low-loss Materials for 5G Production by Region
2.3.1 Global Low-loss Materials for 5G Historic Production by Region (2017-2022)
2.3.2 Global Low-loss Materials for 5G Forecasted Production by Region (2023-2028)
2.4 North America
2.5 Europe
2.6 Asia Pacific
3 Global Low-loss Materials for 5G Sales in Volume & Value Estimates and Forecasts
3.1 Global Low-loss Materials for 5G Sales Estimates and Forecasts 2017-2028
3.2 Global Low-loss Materials for 5G Revenue Estimates and Forecasts 2017-2028
3.3 Global Low-loss Materials for 5G Revenue by Region: 2017 VS 2021 VS 2028
3.4 Global Low-loss Materials for 5G Sales by Region
3.4.1 Global Low-loss Materials for 5G Sales by Region (2017-2022)
3.4.2 Global Sales Low-loss Materials for 5G by Region (2023-2028)
3.5 Global Low-loss Materials for 5G Revenue by Region
3.5.1 Global Low-loss Materials for 5G Revenue by Region (2017-2022)
3.5.2 Global Low-loss Materials for 5G Revenue by Region (2023-2028)
3.6 North America
3.7 Europe
3.8 Asia-Pacific
3.9 Latin America
3.10 Middle East & Africa
4 Competition by Manufactures
4.1 Global Low-loss Materials for 5G Production Capacity by Manufacturers
4.2 Global Low-loss Materials for 5G Sales by Manufacturers
4.2.1 Global Low-loss Materials for 5G Sales by Manufacturers (2017-2022)
4.2.2 Global Low-loss Materials for 5G Sales Market Share by Manufacturers (2017-2022)
4.2.3 Global Top 10 and Top 5 Largest Manufacturers of Low-loss Materials for 5G in 2021
4.3 Global Low-loss Materials for 5G Revenue by Manufacturers
4.3.1 Global Low-loss Materials for 5G Revenue by Manufacturers (2017-2022)
4.3.2 Global Low-loss Materials for 5G Revenue Market Share by Manufacturers (2017-2022)
4.3.3 Global Top 10 and Top 5 Companies by Low-loss Materials for 5G Revenue in 2021
4.4 Global Low-loss Materials for 5G Sales Price by Manufacturers
4.5 Analysis of Competitive Landscape
4.5.1 Manufacturers Market Concentration Ratio (CR5 and HHI)
4.5.2 Global Low-loss Materials for 5G Market Share by Company Type (Tier 1, Tier 2, and Tier 3)
4.5.3 Global Low-loss Materials for 5G Manufacturers Geographical Distribution
4.6 Mergers & Acquisitions, Expansion Plans
5 Market Size by Type
5.1 Global Low-loss Materials for 5G Sales by Type
5.1.1 Global Low-loss Materials for 5G Historical Sales by Type (2017-2022)
5.1.2 Global Low-loss Materials for 5G Forecasted Sales by Type (2023-2028)
5.1.3 Global Low-loss Materials for 5G Sales Market Share by Type (2017-2028)
5.2 Global Low-loss Materials for 5G Revenue by Type
5.2.1 Global Low-loss Materials for 5G Historical Revenue by Type (2017-2022)
5.2.2 Global Low-loss Materials for 5G Forecasted Revenue by Type (2023-2028)
5.2.3 Global Low-loss Materials for 5G Revenue Market Share by Type (2017-2028)
5.3 Global Low-loss Materials for 5G Price by Type
5.3.1 Global Low-loss Materials for 5G Price by Type (2017-2022)
5.3.2 Global Low-loss Materials for 5G Price Forecast by Type (2023-2028)
6 Market Size by Application
6.1 Global Low-loss Materials for 5G Sales by Application
6.1.1 Global Low-loss Materials for 5G Historical Sales by Application (2017-2022)
6.1.2 Global Low-loss Materials for 5G Forecasted Sales by Application (2023-2028)
6.1.3 Global Low-loss Materials for 5G Sales Market Share by Application (2017-2028)
6.2 Global Low-loss Materials for 5G Revenue by Application
6.2.1 Global Low-loss Materials for 5G Historical Revenue by Application (2017-2022)
6.2.2 Global Low-loss Materials for 5G Forecasted Revenue by Application (2023-2028)
6.2.3 Global Low-loss Materials for 5G Revenue Market Share by Application (2017-2028)
6.3 Global Low-loss Materials for 5G Price by Application
6.3.1 Global Low-loss Materials for 5G Price by Application (2017-2022)
6.3.2 Global Low-loss Materials for 5G Price Forecast by Application (2023-2028)
7 North America
7.1 North America Low-loss Materials for 5G Market Size by Type
7.1.1 North America Low-loss Materials for 5G Sales by Type (2017-2028)
7.1.2 North America Low-loss Materials for 5G Revenue by Type (2017-2028)
7.2 North America Low-loss Materials for 5G Market Size by Application
7.2.1 North America Low-loss Materials for 5G Sales by Application (2017-2028)
7.2.2 North America Low-loss Materials for 5G Revenue by Application (2017-2028)
7.3 North America Low-loss Materials for 5G Sales by Country
7.3.1 North America Low-loss Materials for 5G Sales by Country (2017-2028)
7.3.2 North America Low-loss Materials for 5G Revenue by Country (2017-2028)
7.3.3 United States
7.3.4 Canada
8 Europe
8.1 Europe Low-loss Materials for 5G Market Size by Type
8.1.1 Europe Low-loss Materials for 5G Sales by Type (2017-2028)
8.1.2 Europe Low-loss Materials for 5G Revenue by Type (2017-2028)
8.2 Europe Low-loss Materials for 5G Market Size by Application
8.2.1 Europe Low-loss Materials for 5G Sales by Application (2017-2028)
8.2.2 Europe Low-loss Materials for 5G Revenue by Application (2017-2028)
8.3 Europe Low-loss Materials for 5G Sales by Country
8.3.1 Europe Low-loss Materials for 5G Sales by Country (2017-2028)
8.3.2 Europe Low-loss Materials for 5G Revenue by Country (2017-2028)
8.3.3 Germany
8.3.4 France
8.3.5 U.K.
8.3.6 Italy
8.3.7 Russia
9 Asia Pacific
9.1 Asia Pacific Low-loss Materials for 5G Market Size by Type
9.1.1 Asia Pacific Low-loss Materials for 5G Sales by Type (2017-2028)
9.1.2 Asia Pacific Low-loss Materials for 5G Revenue by Type (2017-2028)
9.2 Asia Pacific Low-loss Materials for 5G Market Size by Application
9.2.1 Asia Pacific Low-loss Materials for 5G Sales by Application (2017-2028)
9.2.2 Asia Pacific Low-loss Materials for 5G Revenue by Application (2017-2028)
9.3 Asia Pacific Low-loss Materials for 5G Sales by Region
9.3.1 Asia Pacific Low-loss Materials for 5G Sales by Region (2017-2028)
9.3.2 Asia Pacific Low-loss Materials for 5G Revenue by Region (2017-2028)
9.3.3 China
9.3.4 Japan
9.3.5 South Korea
9.3.6 India
9.3.7 Australia
9.3.8 China Taiwan
9.3.9 Indonesia
9.3.10 Thailand
9.3.11 Malaysia
10 Latin America
10.1 Latin America Low-loss Materials for 5G Market Size by Type
10.1.1 Latin America Low-loss Materials for 5G Sales by Type (2017-2028)
10.1.2 Latin America Low-loss Materials for 5G Revenue by Type (2017-2028)
10.2 Latin America Low-loss Materials for 5G Market Size by Application
10.2.1 Latin America Low-loss Materials for 5G Sales by Application (2017-2028)
10.2.2 Latin America Low-loss Materials for 5G Revenue by Application (2017-2028)
10.3 Latin America Low-loss Materials for 5G Sales by Country
10.3.1 Latin America Low-loss Materials for 5G Sales by Country (2017-2028)
10.3.2 Latin America Low-loss Materials for 5G Revenue by Country (2017-2028)
10.3.3 Mexico
10.3.4 Brazil
10.3.5 Argentina
10.3.6 Colombia
11 Middle East and Africa
11.1 Middle East and Africa Low-loss Materials for 5G Market Size by Type
11.1.1 Middle East and Africa Low-loss Materials for 5G Sales by Type (2017-2028)
11.1.2 Middle East and Africa Low-loss Materials for 5G Revenue by Type (2017-2028)
11.2 Middle East and Africa Low-loss Materials for 5G Market Size by Application
11.2.1 Middle East and Africa Low-loss Materials for 5G Sales by Application (2017-2028)
11.2.2 Middle East and Africa Low-loss Materials for 5G Revenue by Application (2017-2028)
11.3 Middle East and Africa Low-loss Materials for 5G Sales by Country
11.3.1 Middle East and Africa Low-loss Materials for 5G Sales by Country (2017-2028)
11.3.2 Middle East and Africa Low-loss Materials for 5G Revenue by Country (2017-2028)
11.3.3 Turkey
11.3.4 Saudi Arabia
11.3.5 UAE
12 Corporate Profiles
12.1 DuPont
12.1.1 DuPont Corporation Information
12.1.2 DuPont Overview
12.1.3 DuPont Low-loss Materials for 5G Sales, Price, Revenue and Gross Margin (2017-2022)
12.1.4 DuPont Low-loss Materials for 5G Product Model Numbers, Pictures, Descriptions and Specifications
12.1.5 DuPont Recent Developments
12.2 Sartomer (Arkema)
12.2.1 Sartomer (Arkema) Corporation Information
12.2.2 Sartomer (Arkema) Overview
12.2.3 Sartomer (Arkema) Low-loss Materials for 5G Sales, Price, Revenue and Gross Margin (2017-2022)
12.2.4 Sartomer (Arkema) Low-loss Materials for 5G Product Model Numbers, Pictures, Descriptions and Specifications
12.2.5 Sartomer (Arkema) Recent Developments
12.3 AGC Chemicals
12.3.1 AGC Chemicals Corporation Information
12.3.2 AGC Chemicals Overview
12.3.3 AGC Chemicals Low-loss Materials for 5G Sales, Price, Revenue and Gross Margin (2017-2022)
12.3.4 AGC Chemicals Low-loss Materials for 5G Product Model Numbers, Pictures, Descriptions and Specifications
12.3.5 AGC Chemicals Recent Developments
12.4 Toray Industries
12.4.1 Toray Industries Corporation Information
12.4.2 Toray Industries Overview
12.4.3 Toray Industries Low-loss Materials for 5G Sales, Price, Revenue and Gross Margin (2017-2022)
12.4.4 Toray Industries Low-loss Materials for 5G Product Model Numbers, Pictures, Descriptions and Specifications
12.4.5 Toray Industries Recent Developments
12.5 Mitsubishi Gas Chemicals
12.5.1 Mitsubishi Gas Chemicals Corporation Information
12.5.2 Mitsubishi Gas Chemicals Overview
12.5.3 Mitsubishi Gas Chemicals Low-loss Materials for 5G Sales, Price, Revenue and Gross Margin (2017-2022)
12.5.4 Mitsubishi Gas Chemicals Low-loss Materials for 5G Product Model Numbers, Pictures, Descriptions and Specifications
12.5.5 Mitsubishi Gas Chemicals Recent Developments
12.6 JSR Corp
12.6.1 JSR Corp Corporation Information
12.6.2 JSR Corp Overview
12.6.3 JSR Corp Low-loss Materials for 5G Sales, Price, Revenue and Gross Margin (2017-2022)
12.6.4 JSR Corp Low-loss Materials for 5G Product Model Numbers, Pictures, Descriptions and Specifications
12.6.5 JSR Corp Recent Developments
12.7 Hitachi Chemicals
12.7.1 Hitachi Chemicals Corporation Information
12.7.2 Hitachi Chemicals Overview
12.7.3 Hitachi Chemicals Low-loss Materials for 5G Sales, Price, Revenue and Gross Margin (2017-2022)
12.7.4 Hitachi Chemicals Low-loss Materials for 5G Product Model Numbers, Pictures, Descriptions and Specifications
12.7.5 Hitachi Chemicals Recent Developments
12.8 SABIC
12.8.1 SABIC Corporation Information
12.8.2 SABIC Overview
12.8.3 SABIC Low-loss Materials for 5G Sales, Price, Revenue and Gross Margin (2017-2022)
12.8.4 SABIC Low-loss Materials for 5G Product Model Numbers, Pictures, Descriptions and Specifications
12.8.5 SABIC Recent Developments
12.9 Solvay
12.9.1 Solvay Corporation Information
12.9.2 Solvay Overview
12.9.3 Solvay Low-loss Materials for 5G Sales, Price, Revenue and Gross Margin (2017-2022)
12.9.4 Solvay Low-loss Materials for 5G Product Model Numbers, Pictures, Descriptions and Specifications
12.9.5 Solvay Recent Developments
12.10 Kyocera
12.10.1 Kyocera Corporation Information
12.10.2 Kyocera Overview
12.10.3 Kyocera Low-loss Materials for 5G Sales, Price, Revenue and Gross Margin (2017-2022)
12.10.4 Kyocera Low-loss Materials for 5G Product Model Numbers, Pictures, Descriptions and Specifications
12.10.5 Kyocera Recent Developments
12.11 Sumitomo Bakelite
12.11.1 Sumitomo Bakelite Corporation Information
12.11.2 Sumitomo Bakelite Overview
12.11.3 Sumitomo Bakelite Low-loss Materials for 5G Sales, Price, Revenue and Gross Margin (2017-2022)
12.11.4 Sumitomo Bakelite Low-loss Materials for 5G Product Model Numbers, Pictures, Descriptions and Specifications
12.11.5 Sumitomo Bakelite Recent Developments
13 Industry Chain and Sales Channels Analysis
13.1 Low-loss Materials for 5G Industry Chain Analysis
13.2 Low-loss Materials for 5G Key Raw Materials
13.2.1 Key Raw Materials
13.2.2 Raw Materials Key Suppliers
13.3 Low-loss Materials for 5G Production Mode & Process
13.4 Low-loss Materials for 5G Sales and Marketing
13.4.1 Low-loss Materials for 5G Sales Channels
13.4.2 Low-loss Materials for 5G Distributors
13.5 Low-loss Materials for 5G Customers
14 Market Drivers, Opportunities, Challenges and Risks Factors Analysis
14.1 Low-loss Materials for 5G Industry Trends
14.2 Low-loss Materials for 5G Market Drivers
14.3 Low-loss Materials for 5G Market Challenges
14.4 Low-loss Materials for 5G Market Restraints
15 Key Finding in The Global Low-loss Materials for 5G Study
16 Appendix
16.1 Research Methodology
16.1.1 Methodology/Research Approach
16.1.2 Data Source
16.2 Author Details
16.3 Disclaimer