X-ray Photoelectron Spectroscopy Market

Published Jun 21, 2022

Length 250 Pages

SKU # FMARI17899958

Description

X-ray Photoelectron Spectroscopy Market

X-ray Photoelectron Spectroscopy (XPS) is also known as Electron Spectroscopy for Chemical Analysis (ESCA). X-ray Photoelectron Spectroscopy is a quantitative technique which identifies the chemical composition of surfaces. X-ray Photoelectron Spectroscopy surface-sensitive technique was developed by a research group in University of Uppsala, Sweden led by Kai Siegbahn. X-ray Photoelectron Spectroscopy analyses the surface chemistry of a material in natural state or after treatments such as exposure to heat or ultra-violet radiation for detailed and better analysis. X-ray Photoelectron Spectroscopy uses photoelectric effect created by x-rays. X-rays converge on the sample surface and the energy distributed by the electrons ejected from the sample surface is probed, a process known as irradiation. The electrons ejected by the sample surface in X-ray Photoelectron Spectroscopy contain information about the chemical oxidation state, atomic composition, morphology and electronic structure of the chemicals present on the sample surface. In this way, X-ray Photoelectron Spectroscopy analyses the surface composition, electronic environment and atomic composition of the surface sample under study.

X-ray Photoelectron Spectroscopy Market: Drivers & Restraints

X-ray Photoelectron Spectroscopy technique studies the surface sample without destroying the surface. X-ray Photoelectron Spectroscopy is a useful technique to quantify the compositions of ultrathin layers of sample surfaces. Hence, X-ray Photoelectron Spectroscopy is vital for studying the interfacial phenomena at the borders of solids and gas. X-ray Photoelectron Spectroscopy market limitation is that it analyses only the surface chemistry of samples. X-ray Photoelectron Spectroscopy gauges the electrons ejected by surface of topmost layers of samples.

X-ray Photoelectron Spectroscopy detects elements with atomic number of 3 and above only. X-ray Photoelectron Spectroscopy is unable to detect hydrogen or helium easily. X-ray Photoelectron Spectroscopy detection limits are in the range of parts per thousand and detection limit of parts per million range for X-ray Photoelectron Spectroscopy requires special conditions and arrangements.

X-ray Photoelectron Spectroscopy Market: Segmentation

X-ray Photoelectron Spectroscopy market is classified on the basis of end use, application and geography.

Based on application, the global X-ray Photoelectron Spectroscopy market is segmented into the following:

Forensic analysis

Corrosion chemistry evaluation

Contamination detection

Others (Element detection, density estimation, empirical formula detection)

Based on end use, the global X-ray Photoelectron Spectroscopy market is segmented into the following:

Healthcare

Electronics

Others (Automotive, aerospace)

X-ray Photoelectron Spectroscopy Market: Overview

X-ray Photoelectron Spectroscopy is used to study the composition of inorganic compounds, alloys, paints, wood, inks, paper, semiconductors, catalysts, glass, oils, polymers, bio-materials to name a few. The global X-ray Photoelectron Spectroscopy market is expected to expand at an exceptional CAGR during the forecast period 2015 to 2025.

X-ray Photoelectron Spectroscopy Market: Region-wise Outlook

Depending on geographic regions, global X-ray Photoelectron Spectroscopy market is segmented into seven key regions: North America, South America, Eastern Europe, Western Europe, Asia Pacific, Japan, and Middle East & Africa. North America X-ray Photoelectron Spectroscopy market holds approximately half the global X-ray Photoelectron Spectroscopy market share on account of existing awareness levels regarding health and availability of demand and technologically advanced XPS systems. Asia Pacific market is witnessing a surge in large untapped demand. The government initiatives are on a rise and improving the scenario for X-ray Photoelectron Spectroscopy market through strong investments. The Asia Pacific X-ray Photoelectron Spectroscopy market is lucrative during forecast period (2015-2025).

X-ray Photoelectron Spectroscopy Market: Key Players

Some of the key market players in global X-ray Photoelectron Spectroscopy market are Shimadzu Corporation, Physical Electronics Inc., Thermo Fisher Scientific Inc., Japan Electrons Optic Laboratory Company Limited, ReVera Incorporated and SPECS GmbH. The competition in X-ray Photoelectron Spectroscopy market is majorly based on achieving fully automated yet affordable X-ray Photoelectron Spectroscopy systems. The companies aim to provide discounts on the systems while recovering the value through service.

The research report presents a comprehensive assessment of the market and contains thoughtful insights, facts, historical data, and statistically supported and industry-validated market data. It also contains projections using a suitable set of assumptions and methodologies. The research report provides analysis and information according to categories such as market segments, geographies, accessories and applications.

The report covers exhaustive analysis on:

Market Segments

Market Dynamics

Market Size

Supply & Demand

Current Trends/Issues/Challenges

Competition & Companies involved

Technology

Value Chain

Regional analysis includes

North America (U.S., Canada)

Latin America (Mexico, Brazil)

Western Europe (Germany, Italy, France, U.K)

Eastern Europe (Poland, Russia)

Asia Pacific (China, India, ASEAN, Australia & New Zealand)

Japan

Middle East and Africa (GCC and S. Africa)

The report is a compilation of first-hand information, qualitative and quantitative assessment by industry analysts, inputs from industry experts and industry participants across the value chain. The report provides in-depth analysis of parent market trends, macro-economic indicators and governing factors along with market attractiveness as per segments. The report also maps the qualitative impact of various market factors on market segments and geographies.

Report Highlights:

Detailed overview of parent market

Changing market dynamics in the industry

In-depth market segmentation

Historical, current and projected market size in terms of volume and value

Recent industry trends and developments

Competitive landscape

Strategies of key players and products offered

Potential and niche segments, geographical regions exhibiting promising growth

A neutral perspective on market performance

Must-have information for market players to sustain and enhance their market footprint.

1. Executive Summary | X-ray Photoelectron Spectroscopy Market: 1.1. Global Market Outlook; 1.2. Demand-side Trends; 1.3. Supply-side Trends; 1.4. Technology Roadmap Analysis; 1.5. Analysis and Recommendations
2. Market Overview: 2.1. Market Coverage / Taxonomy; 2.2. Market Definition / Scope / Limitations
3. Market Background: 3.1. Market Dynamics; 3.1.1. Drivers; 3.1.2. Restraints; 3.1.3. Opportunity; 3.1.4. Trends; 3.2. Scenario Forecast; 3.2.1. Demand in Optimistic Scenario; 3.2.2. Demand in Likely Scenario; 3.2.3. Demand in Conservative Scenario; 3.3. Opportunity Map Analysis; 3.4. Investment Feasibility Matrix; 3.5. Value Chain Analysis; 3.5.1. Profit Margin Analysis; 3.5.2. Service Providers; 3.6. PESTLE and Porter’s Analysis; 3.7. Regulatory Landscape; 3.7.1. By Key Regions; 3.7.2. By Key Countries; 3.8. Regional Parent Market Outlook
4. Global Market Analysis 2017 to 2021 and Forecast, 2022 to 2032: 4.1. Historical Market Size Value (US$ Million) Analysis, 2017 to 2021; 4.2. Current and Future Market Size Value (US$ Million) Projections, 2022 to 2032; 4.2.1. Y-o-Y Growth Trend Analysis; 4.2.2. Absolute $ Opportunity Analysis
5. Global Market Analysis 2017 to 2021 and Forecast 2022 to 2032, By Component: 5.1. Introduction / Key Findings; 5.2. Historical Market Size Value (US$ Million) Analysis By Component, 2017 to 2021; 5.3. Current and Future Market Size Value (US$ Million) Analysis and Forecast By Component, 2022 to 2032; 5.3.1. Hardware; 5.3.2. Software; 5.3.3. Services; 5.4. Y-o-Y Growth Trend Analysis By Component, 2017 to 2021; 5.5. Absolute $ Opportunity Analysis By Component, 2022 to 2032 Deep-dive segmentation will be available in the sample on request
6. Global Market Analysis 2017 to 2021 and Forecast 2022 to 2032, By Application: 6.1. Introduction / Key Findings; 6.2. Historical Market Size Value (US$ Million) Analysis By Application, 2017 to 2021; 6.3. Current and Future Market Size Value (US$ Million) Analysis and Forecast By Application, 2022 to 2032; 6.3.1. Thin Film Analysis; 6.3.2. Adhesion Failure Evaluation; 6.3.3. Elemental Composition Measurement; 6.3.4. Chemical State Identification; 6.3.5. Elemental Profiling; 6.4. Y-o-Y Growth Trend Analysis By Application, 2017 to 2021; 6.5. Absolute $ Opportunity Analysis By Application, 2022 to 2032 Deep-dive segmentation will be available in the sample on request
7. Global Market Analysis 2017 to 2021 and Forecast 2022 to 2032, By End-user Industries: 7.1. Introduction / Key Findings; 7.2. Historical Market Size Value (US$ Million) Analysis By End-user Industries, 2017 to 2021; 7.3. Current and Future Market Size Value (US$ Million) Analysis and Forecast By End-user Industries, 2022 to 2032; 7.3.1. Energy Sector; 7.3.2. Medical Organizations; 7.3.3. Educational & Research Institutions; 7.3.4. Polymer & Thin Film Industries; 7.3.5. Metallurgical Industries; 7.3.6. Semiconductor & Microelectronics; 7.3.7. Others (Aerospace, Automotive, Printing, and Packaging); 7.4. Y-o-Y Growth Trend Analysis By End-user Industries, 2017 to 2021; 7.5. Absolute $ Opportunity Analysis By End-user Industries, 2022 to 2032 Deep-dive segmentation will be available in the sample on request
8. Global Market Analysis 2017 to 2021 and Forecast 2022 to 2032, By Region: 8.1. Introduction; 8.2. Historical Market Size Value (US$ Million) Analysis By Region, 2017 to 2021; 8.3. Current Market Size Value (US$ Million) Analysis and Forecast By Region, 2022 to 2032; 8.3.1. North America; 8.3.2. Latin America; 8.3.3. Europe; 8.3.4. East Asia; 8.3.5. South Asia & Pacific; 8.3.6. Middle East and Africa(MEA); 8.4. Market Attractiveness Analysis By Region
9. North America Market Analysis 2017 to 2021 and Forecast 2022 to 2032, By Country: 9.1. Historical Market Size Value (US$ Million) Trend Analysis By Market Taxonomy, 2017 to 2021; 9.2. Market Size Value (US$ Million) Forecast By Market Taxonomy, 2022 to 2032; 9.2.1. By Country; 9.2.1.1. USA; 9.2.1.2. Canada; 9.2.2. By Component; 9.2.3. By Application; 9.2.4. By End-user Industries; 9.3. Market Attractiveness Analysis; 9.3.1. By Country; 9.3.2. By Component; 9.3.3. By Application; 9.3.4. By End-user Industries; 9.4. Key Takeaways
10. Latin America Market Analysis 2017 to 2021 and Forecast 2022 to 2032, By Country: 10.1. Historical Market Size Value (US$ Million) Trend Analysis By Market Taxonomy, 2017 to 2021; 10.2. Market Size Value (US$ Million) Forecast By Market Taxonomy, 2022 to 2032; 10.2.1. By Country; 10.2.1.1. Mexico; 10.2.1.2. Brazil; 10.2.1.3. Rest of Latin America; 10.2.2. By Component; 10.2.3. By Application; 10.2.4. By End-user Industries; 10.3. Market Attractiveness Analysis; 10.3.1. By Country; 10.3.2. By Component; 10.3.3. By Application; 10.3.4. By End-user Industries; 10.4. Key Takeaways
11. Europe Market Analysis 2017 to 2021 and Forecast 2022 to 2032, By Country: 11.1. Historical Market Size Value (US$ Million) Trend Analysis By Market Taxonomy, 2017 to 2021; 11.2. Market Size Value (US$ Million) Forecast By Market Taxonomy, 2022 to 2032; 11.2.1. By Country; 11.2.1.1. Germany; 11.2.1.2. Italy; 11.2.1.3. France; 11.2.1.4. United Kingdom; 11.2.1.5. Spain; 11.2.1.6. BENELUX; 11.2.1.7. Russia; 11.2.1.8. Rest of Europe; 11.2.2. By Component; 11.2.3. By Application; 11.2.4. By End-user Industries; 11.3. Market Attractiveness Analysis; 11.3.1. By Country; 11.3.2. By Component; 11.3.3. By Application; 11.3.4. By End-user Industries; 11.4. Key Takeaways
12. East Asia Market Analysis 2017 to 2021 and Forecast 2022 to 2032, By Country: 12.1. Historical Market Size Value (US$ Million) Trend Analysis By Market Taxonomy, 2017 to 2021; 12.2. Market Size Value (US$ Million) Forecast By Market Taxonomy, 2022 to 2032; 12.2.1. By Country; 12.2.1.1. China; 12.2.1.2. Japan; 12.2.1.3. South Korea; 12.2.2. By Component; 12.2.3. By Application; 12.2.4. By End-user Industries; 12.3. Market Attractiveness Analysis; 12.3.1. By Country; 12.3.2. By Component; 12.3.3. By Application; 12.3.4. By End-user Industries; 12.4. Key Takeaways
13. South Asia & Pacific Market Analysis 2017 to 2021 and Forecast 2022 to 2032, By Country: 13.1. Historical Market Size Value (US$ Million) Trend Analysis By Market Taxonomy, 2017 to 2021; 13.2. Market Size Value (US$ Million) Forecast By Market Taxonomy, 2022 to 2032; 13.2.1. By Country; 13.2.1.1. India; 13.2.1.2. ASEAN; 13.2.1.3. Australia and New Zealand; 13.2.1.4. Rest of South Asia & Pacific; 13.2.2. By Component; 13.2.3. By Application; 13.2.4. By End-user Industries; 13.3. Market Attractiveness Analysis; 13.3.1. By Country; 13.3.2. By Component; 13.3.3. By Application; 13.3.4. By End-user Industries; 13.4. Key Takeaways
14. MEA Market Analysis 2017 to 2021 and Forecast 2022 to 2032, By Country: 14.1. Historical Market Size Value (US$ Million) Trend Analysis By Market Taxonomy, 2017 to 2021; 14.2. Market Size Value (US$ Million) Forecast By Market Taxonomy, 2022 to 2032; 14.2.1. By Country; 14.2.1.1. GCC Countries; 14.2.1.2. Turkey; 14.2.1.3. South Africa; 14.2.1.4. Rest of Middle East and Africa(MEA); 14.2.2. By Component; 14.2.3. By Application; 14.2.4. By End-user Industries; 14.3. Market Attractiveness Analysis; 14.3.1. By Country; 14.3.2. By Component; 14.3.3. By Application; 14.3.4. By End-user Industries; 14.4. Key Takeaways
15. Key Countries Market Analysis: 15.1. USA; 15.1.1. Pricing Analysis; 15.1.2. Market Share Analysis, 2021; 15.1.2.1. By Component; 15.1.2.2. By Application; 15.1.2.3. By End-user Industries; 15.2. Canada; 15.2.1. Pricing Analysis; 15.2.2. Market Share Analysis, 2021; 15.2.2.1. By Component; 15.2.2.2. By Application; 15.2.2.3. By End-user Industries; 15.3. Mexico; 15.3.1. Pricing Analysis; 15.3.2. Market Share Analysis, 2021; 15.3.2.1. By Component; 15.3.2.2. By Application; 15.3.2.3. By End-user Industries; 15.4. Brazil; 15.4.1. Pricing Analysis; 15.4.2. Market Share Analysis, 2021; 15.4.2.1. By Component; 15.4.2.2. By Application; 15.4.2.3. By End-user Industries; 15.5. Germany; 15.5.1. Pricing Analysis; 15.5.2. Market Share Analysis, 2021; 15.5.2.1. By Component; 15.5.2.2. By Application; 15.5.2.3. By End-user Industries; 15.6. Italy; 15.6.1. Pricing Analysis; 15.6.2. Market Share Analysis, 2021; 15.6.2.1. By Component; 15.6.2.2. By Application; 15.6.2.3. By End-user Industries; 15.7. France; 15.7.1. Pricing Analysis; 15.7.2. Market Share Analysis, 2021; 15.7.2.1. By Component; 15.7.2.2. By Application; 15.7.2.3. By End-user Industries; 15.8. United Kingdom; 15.8.1. Pricing Analysis; 15.8.2. Market Share Analysis, 2021; 15.8.2.1. By Component; 15.8.2.2. By Application; 15.8.2.3. By End-user Industries; 15.9. Spain; 15.9.1. Pricing Analysis; 15.9.2. Market Share Analysis, 2021; 15.9.2.1. By Component; 15.9.2.2. By Application; 15.9.2.3. By End-user Industries; 15.10. BENELUX; 15.10.1. Pricing Analysis; 15.10.2. Market Share Analysis, 2021; 15.10.2.1. By Component; 15.10.2.2. By Application; 15.10.2.3. By End-user Industries; 15.11. Russia; 15.11.1. Pricing Analysis; 15.11.2. Market Share Analysis, 2021; 15.11.2.1. By Component; 15.11.2.2. By Application; 15.11.2.3. By End-user Industries; 15.12. China; 15.12.1. Pricing Analysis; 15.12.2. Market Share Analysis, 2021; 15.12.2.1. By Component; 15.12.2.2. By Application; 15.12.2.3. By End-user Industries; 15.13. Japan; 15.13.1. Pricing Analysis; 15.13.2. Market Share Analysis, 2021; 15.13.2.1. By Component; 15.13.2.2. By Application; 15.13.2.3. By End-user Industries; 15.14. South Korea; 15.14.1. Pricing Analysis; 15.14.2. Market Share Analysis, 2021; 15.14.2.1. By Component; 15.14.2.2. By Application; 15.14.2.3. By End-user Industries; 15.15. India; 15.15.1. Pricing Analysis; 15.15.2. Market Share Analysis, 2021; 15.15.2.1. By Component; 15.15.2.2. By Application; 15.15.2.3. By End-user Industries; 15.16. ASEAN; 15.16.1. Pricing Analysis; 15.16.2. Market Share Analysis, 2021; 15.16.2.1. By Component; 15.16.2.2. By Application; 15.16.2.3. By End-user Industries; 15.17. Australia and New Zealand; 15.17.1. Pricing Analysis; 15.17.2. Market Share Analysis, 2021; 15.17.2.1. By Component; 15.17.2.2. By Application; 15.17.2.3. By End-user Industries; 15.18. GCC Countries; 15.18.1. Pricing Analysis; 15.18.2. Market Share Analysis, 2021; 15.18.2.1. By Component; 15.18.2.2. By Application; 15.18.2.3. By End-user Industries; 15.19. Turkey; 15.19.1. Pricing Analysis; 15.19.2. Market Share Analysis, 2021; 15.19.2.1. By Component; 15.19.2.2. By Application; 15.19.2.3. By End-user Industries; 15.20. South Africa; 15.20.1. Pricing Analysis; 15.20.2. Market Share Analysis, 2021; 15.20.2.1. By Component; 15.20.2.2. By Application; 15.20.2.3. By End-user Industries
16. Market Structure Analysis: 16.1. Competition Dashboard; 16.2. Competition Benchmarking; 16.3. Market Share Analysis of Top Players; 16.3.1. By Regional; 16.3.2. By Component; 16.3.3. By Application; 16.3.4. By End-user Industries
17. Competition Analysis: 17.1. Competition Deep Dive; 17.1.1. JEOL Ltd; 17.1.1.1. Overview; 17.1.1.2. Product Portfolio; 17.1.1.3. Profitability by Market Segments; 17.1.1.4. Sales Footprint; 17.1.1.5. Strategy Overview; 17.1.1.5.1. Marketing Strategy; 17.1.1.5.2. Product Strategy; 17.1.1.5.3. Channel Strategy; 17.1.2. Kratos Analytical (Shimadzu Group); 17.1.2.1. Overview; 17.1.2.2. Product Portfolio; 17.1.2.3. Profitability by Market Segments; 17.1.2.4. Sales Footprint; 17.1.2.5. Strategy Overview; 17.1.2.5.1. Marketing Strategy; 17.1.2.5.2. Product Strategy; 17.1.2.5.3. Channel Strategy; 17.1.3. Physical Electronics Inc.; 17.1.3.1. Overview; 17.1.3.2. Product Portfolio; 17.1.3.3. Profitability by Market Segments; 17.1.3.4. Sales Footprint; 17.1.3.5. Strategy Overview; 17.1.3.5.1. Marketing Strategy; 17.1.3.5.2. Product Strategy; 17.1.3.5.3. Channel Strategy; 17.1.4. Thermo Fisher Scientific Inc.; 17.1.4.1. Overview; 17.1.4.2. Product Portfolio; 17.1.4.3. Profitability by Market Segments; 17.1.4.4. Sales Footprint; 17.1.4.5. Strategy Overview; 17.1.4.5.1. Marketing Strategy; 17.1.4.5.2. Product Strategy; 17.1.4.5.3. Channel Strategy; 17.1.5. Scienta Omicron; 17.1.5.1. Overview; 17.1.5.2. Product Portfolio; 17.1.5.3. Profitability by Market Segments; 17.1.5.4. Sales Footprint; 17.1.5.5. Strategy Overview; 17.1.5.5.1. Marketing Strategy; 17.1.5.5.2. Product Strategy; 17.1.5.5.3. Channel Strategy; 17.1.6. Evans Analytical Group; 17.1.6.1. Overview; 17.1.6.2. Product Portfolio; 17.1.6.3. Profitability by Market Segments; 17.1.6.4. Sales Footprint; 17.1.6.5. Strategy Overview; 17.1.6.5.1. Marketing Strategy; 17.1.6.5.2. Product Strategy; 17.1.6.5.3. Channel Strategy; 17.1.7. SPECS GmbH; 17.1.7.1. Overview; 17.1.7.2. Product Portfolio; 17.1.7.3. Profitability by Market Segments; 17.1.7.4. Sales Footprint; 17.1.7.5. Strategy Overview; 17.1.7.5.1. Marketing Strategy; 17.1.7.5.2. Product Strategy; 17.1.7.5.3. Channel Strategy; 17.1.8. Lucideon; 17.1.8.1. Overview; 17.1.8.2. Product Portfolio; 17.1.8.3. Profitability by Market Segments; 17.1.8.4. Sales Footprint; 17.1.8.5. Strategy Overview; 17.1.8.5.1. Marketing Strategy; 17.1.8.5.2. Product Strategy; 17.1.8.5.3. Channel Strategy
18. Assumptions & Acronyms Used
19. Research Methodology

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