Physical Vapor Deposition Market size was estimated to be US$ 18 billion in 2019 and expected to grow at a CAGR of 6.3% during 2020 and 2030. Rising demand from consumer electronics, automotive and healthcare industries, increasing investment in development of advanced surface coating technologies, and eco-friendly characteristics of physical vapor deposition process are the primary factors influencing the growth of the global physical vapor deposition market. Primarily used for fabrication or deposition of thin film and surface coating, physical vapor deposition plays a vital role in material processing and surface coating industry. During vapor deposition process, the material to be deposited goes from condensed phase to vapor phase and back to condensed phase in the form of thin film. The physical vapor deposition process does not require a process medium and does not produce any process waste, thereby making the process environment friendly. The demand for physical vapor deposition is primarily driven by increased demand for affordable and sustainable surface coating technology. The physical vapor deposition technique is used for deposition of protective coating on healthcare equipment, cutting tools, surgical tools, solar products, microelectronics and storage devices. Strong adoption of physical vapor deposition process and expansion of electronic, healthcare and energy & utility industry is anticipated to contribute towards the growth of the global physical vapor deposition market in coming years.
The Asia Pacific physical vapor deposition market contributed a dominating share to the global physical vapor deposition market in 2019 and is anticipated to be a dominating segment throughout the forecast period. Asia Pacific is witnessing expansion of healthcare, semiconductor & electronics, and automotive industries owing to increased investment across major countries such as India, Indonesia, and Malaysia. This is expected to offer prominent opportunities to the manufacturers and suppliers of physical vapor deposition equipment, materials and services providers in coming years. The North America physical vapor deposition market is anticipated to witness steady growth during the forecast period, with healthcare equipment and microelectronics device manufacturing industries being the major growth contributors.
Physical Vapor Deposition Market Share Analysis, by Geography (2021)
The report titled “Physical Vapor Deposition Market - Global Market Share, Trends, Analysis and Forecasts, 2022-2032” wherein 2020 is historic period, 2021 is the base year, and 2022 to 2032 is forecast period. Additionally, the study takes into consideration the competitive landscape, wherein the report would provide company overview and market outlook for leading players in the global physical vapor deposition market. Furthermore, the report would reflect the key developments, global & regional sales network, business strategies, research & development activities, employee strength, and key executive, for all the major players operating in the market.
The global physical vapor deposition (PVD) market is segmented on the basis of components, applications, and geography. Based on component, the global physical vapor deposition market is segmented into PVD equipment, PVD material, and PVD services. Based on applications, the global physical vapor deposition market is segmented into microelectronics, data storage, solar products, cutting tools, medical equipment, and others. Based on geography, the global physical vapor deposition market is segmented into North America, Europe, Asia Pacific, Middle East & Africa, and South America.
The research provides in-depth analysis of prominent players holding majority share of the global market with a focus on all operating business segment, and would identify the segment of the company focusing on physical vapor deposition. Further, market share of prominent companies in the global physical vapor deposition market would also be estimated. The study takes into consideration the key competitive information such as business strategy, product portfolio, key development, SWOT analysis, and research and development focus of all the Physical Vapor Deposition companies.
The global physical vapor deposition market study would take into consideration the participants engaged throughout the supply chain and value chain of the market, along with their contribution. Product portfolio would focus on all the products under the physical vapor deposition business segment of the company. Similarly, the recent development section would focus on the latest developments of company such as strategic alliances and partnerships, merger and acquisition, new product launched and geographic expansion in the global physical vapor deposition market.
Major players active in the global physical vapor deposition market include Advanced Energy Industries, Inc., AJA INTERNATIONAL, Inc., Angstrom Engineering Inc., Applied Materials, Inc., Buhler AG., HEF USA, IHI Corporation, Mustang Vacuum Systems, Oerlikon Balzers, Platit AG, Semicore Equipment, Inc., Silfex Inc. (Lam Research Corp.), Singulus Technologies AG, ULVAC Inc., and Veeco Instruments Inc.
InsightSLICE adopts a research methodology which is highly meticulous and comprehensive, yielding accurate research results. Our research methodology utilizes data triangulation model which helps in the precise collection and validation of information. Our set processes for problem solving and paid primary tools guarantee that any client requirement is met with utmost diligence and accuracy. Some of the primary components that are consequential to our research approach are:
Secondary Research or Desk Research
Distinctive Data Model
Secondary Sources include but are not limited to:
Past Published Research
Historical Data and Information
Primary Sources include but are not limited to:
InsightSLICE also leverages three types of data triangulation approaches as follows:
Data Source Triangulation
Extracting data and validation from multiple type of secondary and primary sources
Combining various methodologies to validate data inputs
Applying different theories to check credibility of data sets