Exploring the Global Laser Market: Trends, Applications, and Growth Opportunities

Market Overview

The lasers market is projected to experience a compound annual growth rate (CAGR) exceeding 13% throughout the forecast period (2024-2029).

Key Trends in the Laser Market

Advancements in Fiber Lasers: Fiber lasers are rapidly gaining popularity in the industrial sector due to their energy efficiency, high power, and long operational life. These lasers are ideal for precision tasks and are increasingly used in electronics, aerospace, and automotive industries.

Rising Demand for Miniaturization: In electronics, the trend towards smaller devices requires highly precise laser applications for cutting and marking micro-components, especially in smartphones and microprocessors.

Medical Lasers in Demand: With the rise of non-invasive surgical procedures, medical lasers are seeing increased use in dental treatments, eye surgeries, and dermatology. These advancements are contributing to safer, quicker, and more effective medical treatments.

Environmental Applications: The laser industry is also exploring opportunities in environmental applications, such as laser-induced breakdown spectroscopy (LIBS) for pollution monitoring and laser-based sensors for climate studies.

Challenges and Opportunities

Despite the rapid growth, the laser market faces challenges, particularly high costs associated with advanced laser systems, and the need for significant R&D investment. However, with ongoing technological developments and broader adoption across new applications, the market offers tremendous opportunities for innovation. As industries continue to automate, the demand for highly efficient, reliable, and precise laser technology will remain strong.

Future Outlook

The laser market is set to benefit from continued advancements in AI, machine learning, and the integration of IoT with laser technologies, allowing for more precise and adaptable systems. Emerging markets in Asia-Pacific and Latin America present high-growth opportunities due to increasing industrialization and demand for consumer electronics. With a projected CAGR reflecting robust growth, the laser market is positioned for transformative changes that will have far-reaching impacts across numerous industries.

For a detailed overview and more insights, you can refer to the full market research report by Mordor Intelligence: https://www.mordorintelligence.com/industry-reports/lasers-market

Laser Processing Market 2030 Top Key Players, Trends, Share, Industry Size, Segmentation

The global laser processing market was valued at USD 17.48 billion in 2021, with projections for a compound annual growth rate (CAGR) of 9.1% from 2022 to 2030. This growth is largely driven by the increasing adoption of lasers in medical devices and surgical applications. Additionally, the advancement of nano-fabrication technology is expected to further accelerate market expansion. Laser processing has become a popular choice in the manufacturing sector for material processing due to its numerous benefits over traditional methods, and this shift is one of the main contributors to the market’s growth.

For instance, traditional methods like manual metal arc welding have considerable environmental impacts, a significant concern for industries such as automotive manufacturing. The adoption of laser technology has offered a solution to this issue. In July 2021, Furukawa Electric introduced a 12kW industrial fiber laser system for automotive applications, including welding car bodies, processing aluminum components, and battery and motor welding. This innovation exemplifies how laser technology addresses environmental concerns while enhancing precision and efficiency in manufacturing.

Government regulations regarding laser technology applications, particularly for marking and engraving products, are also expected to positively impact market growth in the coming years. The laser processing market is anticipated to expand as this technology finds use in a variety of applications, including welding, marking, cutting, drilling, and engraving. These applications have broad industrial relevance, enabling laser technology to address diverse industry needs.

Strict regulatory directives around the use of laser technology for marking and engraving, coupled with its rising adoption in medical devices and surgical applications, are expected to boost market growth in the near term. A notable example in the medical field is the LASIK & Refractive technology, widely used in laser eye surgery to correct vision issues like myopia, hyperopia, presbyopia, and astigmatism. This technology underscores the importance of lasers in precision medical procedures, further driving demand.

Gather more insights about the market drivers, restrains and growth of the Laser Processing Market

Regional Insights:

In 2021, the Asia Pacific region led the laser processing market, capturing over 40.0% of the revenue share. The region is poised for continued growth due to an increasing number of original equipment manufacturers (OEMs). China is projected to emerge as the leading consumer of industrial lasers and systems used in material and micro-processing. Other countries in the region, including India, South Korea, Japan, and China, are anticipated to experience strong growth due to factors such as the expanding number of OEMs and growth in the automotive sector.

Additionally, the growing adoption of laser systems across various applications in the region is expected to drive further market expansion. Government regulations mandating permanent, clear markings on consumer goods are also likely to promote greater adoption of laser processing technology across multiple regions. In Europe, increasing use of laser systems within the automotive sector is expected to further support demand growth.

Browse through Grand View Research's Category Electronic Devices Industry Research Reports.

The global ATM market size was estimated at USD 25.29 billion in 2024 and is projected to grow at a CAGR of 3.6% from 2025 to 2030.

The global inspection camera system market size was valued at USD 390.0 million in 2024 and is expected to grow at a CAGR of 11.2% from 2025 to 2030.

Key Companies & Market Share Insights

The laser processing market is characterized by intense competition, with several key global players holding a significant market share. These major companies focus on continuous product innovation to enhance profitability and strengthen customer relationships. For example, Universal Laser Systems provides laser solutions for asset management, custom parts fabrication, and security applications, serving security agencies and military organizations. These systems are utilized in diverse locations such as airfields, military bases, and naval vessels around the world, highlighting the versatility and wide application of laser processing technology in both industrial and defense sectors.

This competitive landscape reveals how companies are not only diversifying their product offerings but also expanding into new markets to address a variety of customer needs across industries.

Key Laser Processing Companies

Altec GmbH

Alpha Nov laser

Amada Co., Ltd.

Bystronic Laser AG

Epilog Laser, Inc.

Eurolaser GmbH

Han's Laser Technology Industry Group Co., Ltd.

IPG Photonics Corporation

Newport Corporation (MKS Instruments, Inc.)

LaserStar Technologies Corporation

Coherent Inc.

IPG Photonics Corporation

Newport Corporation

Trumpf GmbH + Co. KG

Universal Laser Systems, Inc.

Xenetech Global Inc.

Order a free sample PDF of the Laser Processing Market Intelligence Study, published by Grand View Research.

Laser Processing Market 2030 Driving Factors, Future Trends, Size & Key Vendors

The global laser processing market was valued at USD 17.48 billion in 2021, with projections for a compound annual growth rate (CAGR) of 9.1% from 2022 to 2030. This growth is largely driven by the increasing adoption of lasers in medical devices and surgical applications. Additionally, the advancement of nano-fabrication technology is expected to further accelerate market expansion. Laser processing has become a popular choice in the manufacturing sector for material processing due to its numerous benefits over traditional methods, and this shift is one of the main contributors to the market’s growth.

For instance, traditional methods like manual metal arc welding have considerable environmental impacts, a significant concern for industries such as automotive manufacturing. The adoption of laser technology has offered a solution to this issue. In July 2021, Furukawa Electric introduced a 12kW industrial fiber laser system for automotive applications, including welding car bodies, processing aluminum components, and battery and motor welding. This innovation exemplifies how laser technology addresses environmental concerns while enhancing precision and efficiency in manufacturing.

Government regulations regarding laser technology applications, particularly for marking and engraving products, are also expected to positively impact market growth in the coming years. The laser processing market is anticipated to expand as this technology finds use in a variety of applications, including welding, marking, cutting, drilling, and engraving. These applications have broad industrial relevance, enabling laser technology to address diverse industry needs.

Strict regulatory directives around the use of laser technology for marking and engraving, coupled with its rising adoption in medical devices and surgical applications, are expected to boost market growth in the near term. A notable example in the medical field is the LASIK & Refractive technology, widely used in laser eye surgery to correct vision issues like myopia, hyperopia, presbyopia, and astigmatism. This technology underscores the importance of lasers in precision medical procedures, further driving demand.

Gather more insights about the market drivers, restrains and growth of the Laser Processing Market

Regional Insights:

In 2021, the Asia Pacific region led the laser processing market, capturing over 40.0% of the revenue share. The region is poised for continued growth due to an increasing number of original equipment manufacturers (OEMs). China is projected to emerge as the leading consumer of industrial lasers and systems used in material and micro-processing. Other countries in the region, including India, South Korea, Japan, and China, are anticipated to experience strong growth due to factors such as the expanding number of OEMs and growth in the automotive sector.

Additionally, the growing adoption of laser systems across various applications in the region is expected to drive further market expansion. Government regulations mandating permanent, clear markings on consumer goods are also likely to promote greater adoption of laser processing technology across multiple regions. In Europe, increasing use of laser systems within the automotive sector is expected to further support demand growth.

Browse through Grand View Research's Category Electronic Devices Industry Research Reports.

The global ATM market size was estimated at USD 25.29 billion in 2024 and is projected to grow at a CAGR of 3.6% from 2025 to 2030.

The global inspection camera system market size was valued at USD 390.0 million in 2024 and is expected to grow at a CAGR of 11.2% from 2025 to 2030.

Key Companies & Market Share Insights

The laser processing market is characterized by intense competition, with several key global players holding a significant market share. These major companies focus on continuous product innovation to enhance profitability and strengthen customer relationships. For example, Universal Laser Systems provides laser solutions for asset management, custom parts fabrication, and security applications, serving security agencies and military organizations. These systems are utilized in diverse locations such as airfields, military bases, and naval vessels around the world, highlighting the versatility and wide application of laser processing technology in both industrial and defense sectors.

This competitive landscape reveals how companies are not only diversifying their product offerings but also expanding into new markets to address a variety of customer needs across industries.

Key Laser Processing Companies

Altec GmbH

Alpha Nov laser

Amada Co., Ltd.

Bystronic Laser AG

Epilog Laser, Inc.

Eurolaser GmbH

Han's Laser Technology Industry Group Co., Ltd.

IPG Photonics Corporation

Newport Corporation (MKS Instruments, Inc.)

LaserStar Technologies Corporation

Coherent Inc.

IPG Photonics Corporation

Newport Corporation

Trumpf GmbH + Co. KG

Universal Laser Systems, Inc.

Xenetech Global Inc.

Order a free sample PDF of the Laser Processing Market Intelligence Study, published by Grand View Research.

3D Printing Market — Forecast(2024–2030)

3D Printing Market Overview:

However, artificial 3D printing has opened up scope in the modern medical industry for people to opt for advanced, cost-effective, and appealing designed prosthetics. Healthcare sector has helped in generating a huge demand in the 3D printing market owing to its versatile application in dental implants, hearing aids, artificial organs, etc. 3D bioprinting fills up the gap between animal and human experimental trials with advanced bio-printed human skin, thyroid gland, and many other vital parts. Technological advancement has extended the manufacturing of almost every possible subject for 3D printing: automotive parts, metal printing, sample architectures and constructions, prototypes of footwear, energy production, food, educational, aeronautical approaches, robotics and drones, and many others. Moreover, continuous and limitless breakthroughs in 3D printing have created an enormous impact on the industrial and commercial field thereby expanding the 3D printing economy. The extensive market opportunity is expected to advance at a robust compound annual growth rate (CAGR) of 23% through 2030.

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3D printing or additive manufacturing employs layer-by-layer deposition of suitable materials to create an object. Acceptance of 3D printing has increased progressively from prototyping to low-volume manufacturing of customized products. Different types of 3D printing technologies are Stereo-lithography (SLA), Fused Deposition Modeling (FDM), and Selective Laser Sintering (SLS), among others. These above-mentioned technologies are deployed in various industries such as consumers, automotive, construction, aerospace, medical and others.

This report incorporates an in-depth assessment of the 3D printing market by type, technology, application, end user industries and geography. The offering types of 3D printing encompassed in the scope include hardware, software and services. The hardware segment is further sub segmented into printers, scanners and materials.

The 3D printing market is witnessing a surge in material diversity, with advancements in composite materials, biodegradable plastics, and metal alloys. This trend allows for more versatile and application-specific 3D printing, catering to industries such as aerospace, healthcare, and automotive. The 3D printing trend toward large-scale manufacturing is reshaping industries traditionally reliant on massive components. From building construction to shipbuilding, the ability to 3D print large structures is revolutionizing design possibilities, streamlining production, and ushering in a new era of efficiency and customization. Large-scale additive manufacturing is gaining traction, allowing for the production of bigger and more complex structures. Industries like construction, shipbuilding, and infrastructure are exploring the potential of 3D printing for large components, reducing assembly requirements and lead times.

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Market Snapshot:

Report Coverage

The “3D Printing Market Report — Forecast (2024–2030)”, by IndustryARC, covers an in-depth analysis of the following segments of the Bulletproof Glass Industry.

By Product: Hardware [Printers (Industrial, Consumer), Scanners], Software (Design, Scanning, Inspection, Printing), Services (Parts on Demand, Prototypes, Others)

By Material: Polymers [Thermoplastics (Polylactic Acid (PLA), Acrylonitrile Butadiene Styrene (ABS), Polyvinyl Alcohol (PVA ), Polyamide, Polypropylene, Others), Photopolymers], Metals and Alloys (Steel, Titanium, Silver, Gold, Nickel, Bronze, Aluminum, Copper, Iron, Manganese, Others), Fibers (Carbon, Glass, Kevlar, Others), Ceramics (Quartz, Silica, Glass, Others), Wax, Paper, Wood, Others

By Form: Filament, Liquid, Powder

By Technology: Stereolithography (SLA), Fuse deposition modeling (FDM), Selective laser sintering (SLS), Inkjet printing, Electron beam melting (EBM), Laser metal deposition (LMD), PolyJet printing, Digital Light Processing (DLP), Others

By Application: Production, Prototyping, Research & Education

By End Use Industry: Consumers [Decorative Items/Art Work (Freeform Art and Sculpture, Jewelry, Collectible Trinkets, Hospitality, Interior Decorative Items, Others), Others], Industrial (Machine Parts, Dies, Molds and Patterns, Others), Automotive [Exterior (Bumpers, Wind Breakers, Body Panels, Others), Interior (Dashboards, Seat Frames, Others), Engines and Engine Components (Cylinder Heads, Intake Manifolds, Engine Blocks, Others), Transmission Housings, Hubcaps, Tires, Suspension Spring, Others], Aerospace (Complex Gear Cases and Covers, Fuel Tanks, Transmission Housings, Components Requiring Draft Free Walls, Impellers, Turbine Blades, Lightweight Engine Parts, Structural Hinges, Others), Medical [Surgical Instruments, Implants (Dental (Sub-Periosteal Implants, Endosteal Implants), Orthopedic Implants, Prosthetic Implants, Spinal Rods, Bone Plates, Cranial Implants, Others), Tissue Engineering, Others], Construction (Commercial, Residential, Infrastructure, Industrial), Others

By Geography: North America, South America, Europe, APAC, and RoW

What are the major end users for 3D Printing?

The report includes an assessment of various end user industries such as automotive, construction, aerospace, medical, consumers and others. Medical industry is one of the major end users for 3D printing and holds a tremendous opportunity in the near future. This segment is expected to dominate the market in the short to long term. 3D Printing in the medical industry can be employed for multiple applications such as surgical instruments, dental implants, orthopedic implants, prosthetic implants, cranial implants and others.

Market Research and Market Trends of 3D Printing Ecosystem

• The American space company, SpaceX has sent a Dragon capsule to the International Space Station (ISS) which carried the first ever zero-G 3D printer. In addition, increasing traction by space agencies such as the National Aeronautics and Space Administration (NASA), European Space Agency (ESA) and others are anticipated to show a significant impact on the 3D printing market in the near future.

• The bio printers’ technology is in the experimental stage and is anticipated to provide prospects for the 3d printing market in the food industry. Furthermore, the importance of this technology has resulted in growing R&D investments by food companies such as chocolate & confectionery manufacturers.

• According to Oxford Performance Materials, more than 75% of American patients’ damaged skulls by disease or trauma were replaced with an implant from Oxford Performance Materials 3D printer and hence brought a revolution in the healthcare industry

The consumer 3D printers market is becoming highly consolidated with Stratasys Ltd. and 3D Systems Corp. being the global behemoths in this industry. 3DSystems has been highly active with a string of acquisitions of smaller companies across the globe

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Who are the Major Players in the 3D Printing Market?

The companies referred to in the market research report include Flashforge 3D Technology Co., Ltd., Hewlett-Packard, 3D Systems, Inc., Stratasys Ltd., SLM Solutions Group AG, ExOne Company LLC., Organovo Holdings, Inc., EOS GmbH, General Electric Company, XYZprinting, Inc., and others and more than 15 other companies.

What is our report scope?

The report incorporates an in-depth assessment of the competitive landscape, product market sizing, product benchmarking, market trends, product developments, financial analysis, strategic analysis and so on to gauge the impact forces and potential opportunities of the market. Apart from this the report also includes a study of major developments in the market such as product launches, agreements, acquisitions, collaborations, mergers and so on to comprehend the prevailing market dynamics at present and their impact during the forecast period 2024–2030.

All our reports are customizable to your company’s needs to a certain extent, we do provide 20 free consulting hours along with the purchase of each report, and this will allow you to request any additional data to customize the report to your needs.

Key Takeaways from this Report

• Evaluate market potential by analyzing growth rates (CAGR %), Volume (Units) and Value ($M) data given at country level — for product types, end use applications and by different industry verticals.

• Understand the different dynamics influencing the market — key driving factors, challenges and hidden opportunities.

• Get in-depth insights on your competitor’s performance — market shares, strategies, financial benchmarking, product benchmarking, SWOT and more.

• Analyze the sales and distribution channels across key geographies to improve top-line revenues.

• Understand the industry supply chain with a deep-dive on the value augmentation at each step, in order to optimize value and bring efficiencies in your processes.

• Get a quick outlook on the market entropy — M&A’s, deals, partnerships, and product launches of all key players for the past 4 years.

• Evaluate the supply-demand gaps, import-export statistics and regulatory landscape for more than the top 20 countries globally for the market.

3D Printing Market Outlook:

Computer-aided high-quality 3D printing designs of delicate human organs and vascular systems provide a better chance for medical experts to perform risk-free preliminary trials of critical surgery. Earlier 3D printing was accomplished with inkjet printers but vernacular mediums and innovations have made it comparatively easier to print 3D models of any object successfully in modern times. Prototyping is the major push towards 3D printing industries leaving behind conventional practices of manufacturing models and machineries. It uses high-performing materials such as thermoplastics for yielding engineered aeronautical, automotive, and medical utilities. Booming 3D printing market is anticipated to leverage a mounting demand from the automotive industry with an outstanding CAGR of 15% during the period 2024–2030. Apart from North America other provinces are susceptible to the 3D printing market transition with compelling revenue income during the forecast period.

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3D Printing Market Growth Drivers:

• Surgical trials on 3D printed organ models lead to minimal risks, proper surgery planning, identifying suitable tools for a particular case, and shrinks surgical complications, consequently, enhancing medical prowess and driving the global 3D printing market demand.

• Designing new tools and their effective application generates amplifying prospects for 3D printing companies.

• Automotive industry is a major driving force in the 3D printing market owing to better customization, lower material wastage, accuracy and less time consumption, and flexible designing.

• Research on 3D printing organ transplantation is conducted on a large scale to replace the complication of live organ transplantation owing to cost-inefficiency, inadequate donor availability, and donor-receiver incompatibility. Around 13 people die every day without a kidney transplantation. Persistent biomedical engineering advances will increase the efficacy of 3D bio-printed organs and will accomplish sophisticated applications in the medical field in the forthcoming years.

3D Printing Market Challenge:

Critical problems associated with the trending 3D printing progression include limited material variety, limited repetition process, and narrow scale of niche expertise. Albeit the low-cost 3D printing products, exorbitant rates of manufacturing procedure, equipment installation, and post-processing necessities thwart the global 3D market development. However, the optimistic approach of the manufacturing companies outpaces these market challenges with rigorous investment in the technologies and embracing strategic changes.

3D Printing Market Key Players:

The leading market innovators of the global 3D printing market include Flashforge 3D Technology Co., Ltd., Hewlett-Packard, 3D Systems, Inc., Stratasys Ltd., SLM Solutions Group AG, ExOne Company LLC., Organovo Holdings, Inc., EOS GmbH, General Electric Company, XYZprinting, Inc., and others.

XYZ Printing is a 3D printer manufacturing company incorporating the 3D printing experience in offices, schools, and homes with accessible and less expensive printers. With 8500 engineers, they deliver products such as 3D pen, mini, and nano series, original and junior series, color, pro, nobel, and 3D scanner series.

3D Printing Market Trends:

3D Printing Bunion Rectification

Traumatic bunion development on the foot leads to difficulty in walking and toe movement. MedShape Orthopedic Solution Company has invented a new device for correcting hallux valgus deformity with an FDA-administered bone tether plate sculpted through 3D titanium alloy printing. Furthermore, mechanical drilling of bones will be escaped owing to the innovative FastForward bunion correction plate.

Revolutionary Bio-Printed Human Skin

Recent research directed by the unique 3D bio-printer to create a lab-made skin is suitable for testing chemicals, cosmetics, and pharmaceutical experiments as well as compatible with transplantation in burn incidences. A close replica of human skin bio-printing, this method is cost-effective as compared to manual production of artificial skin.

Persuasive Prosthetic Designs

Prosthetics have improved physical deformity with newer advances keeping an eye on the quality, design, and comfort level of the patients. Amputees’ changed outlook on the modern world has shaped their personal preferences. Designer prosthetics in the form of modern bionics of popular characters such as artificial hero arms are widely gaining traction among children worldwide. Widely accepted by teenagers and young amputees, the bionic trend is gradually overpowering the 3D printed prosthetics market.

3D Printing Market Research Scope:

The base year of the study is 2023, with forecasts done up to 2030. The study presents a thorough analysis of the competitive landscape, taking into account the market shares of the leading companies. It also provides information on unit shipments. These provide the key market participants with the necessary business intelligence and help them understand the future of the 3D printing market. The assessment includes the forecast, an overview of the competitive structure, the market shares of the competitors, as well as the market trends, market demands, market drivers, market challenges, and product analysis. The market drivers and restraints have been assessed to fathom their impact over the forecast period. This report further identifies the key opportunities for growth while also detailing the key challenges and possible threats. The key areas of focus include the type of 3D printing in the 3D printing market and their specific applications in different areas.

3D Printing Market: Industry Coverage:

Global 3D printing market is segmented based on offering, application, and end user. Bifurcation based on offering includes printer, scanner, material, software, service, and others. Based on application categorization includes production, prototyping, and research and education. By end user, this market is divided into consumers, automotive, construction, and so on.

The 3D printing market also analyzes the major geographic regions for the market as well as the major countries for the market in these regions.

The regions and countries covered in the study include:

• North America: The U.S., Canada, Mexico

• South America: Brazil, Venezuela, Argentina, Ecuador, Peru, Colombia, Costa Rica

• Europe: The U.K., Germany, Italy, France, the Netherlands, Belgium, Spain, Denmark

• APAC: China, Japan, Australia, South Korea, India, Taiwan, Malaysia, Hong Kong

Middle East and Africa: Israel, South Africa, Saudi Arabia

More information about 3D Printing Market report click here

Fiber Laser Market worth $12.8 billion by 2029

The fiber laser market to grow from USD 7.7 billion in 2024 and is expected to reach USD 12.8 billion by 2029, growing at a CAGR of 10.8% from 2024 to 2029 according to a new report by MarketsandMarkets™. The key factors contributing to the growth of the fiber laser market include the Industrial automation boosts fiber laser adoption for their precision, efficiency, and reliability, growing demand for fiber lasers in medical and healthcare industries, rising adoption of fiber lasers in consumer electronics, expansion of 3D printing and additive manufacturing. Fiber lasers offer high energy efficiency, low maintenance, and long lifespan.

Laser Cleaning Market Size, Business Revenue Forecast, Leading Competitors And Growth Trends

Laser Cleaning Market Key Players and Forecast Insights Through 2032

The latest ""Laser Cleaning Market"" Insight Report for 2024 offers a comprehensive analysis of the industry's key contributions, marketing strategies, and recent advancements by leading companies. This report provides a succinct overview of both historical and current performance metrics for major market players. It employs various analytical methods to deliver precise insights into the Laser Cleaning Market, with coverage across regions including North America, Europe, Asia Pacific, and more. The recent analysis also includes an in-depth review of the business strategies adopted by emerging industry players, along with detailed information on market segments, geographic coverage, product trends, and cost structures.

What are the growth projections for the Laser Cleaning Market?

According to Straits Research, the global Laser Cleaning Market  size was valued at USD 685.38 Million in 2022. It is projected to reach from USD XX Million in 2023 to USD 992.83 Million by 2031, growing at a CAGR of 4.21% during the forecast period (2023–2031).

Get Free Request Sample Report @ https://straitsresearch.com/report/laser-cleaning-market/request-sample

Top Competitive Players of Laser Cleaning Market

Coherent

Trumpf Group

Narran

Adapt Laser Systems LLC

Clean Laser Systeme GmbH

Advanced Laser Technology (ALT)

Anilox Roll Cleaning Systems

General Lasertronics

Laser Photonics

Laserax

White Lion Dry Ice & Laser Cleaning Technology

ARCS-ANILOX ROLL CLEANING SYSTEMS INC.

P-Laser

LASCAM

Andritz Powerlase

Han's Laser

Suresh Indu Lasers (SIL)

SPI LASERS LIMITED

IPG Photonics Corporation.

What are the key trends within each segment of the Laser Cleaning Market?

By Laser Type

Solid Laser

Yttrium Aluminum Garnet (YAG) Laser

Fiber Laser

Gas Lasers

Excimer Lasers

Co2 Laser

By Industry

General Manufacturing

Aerospace

Nuclear

Medical

Food & Beverage

By Application

Contaminant Cleaning

Coating Stripping

Mold Maintenance

Surface Cleaning

Adhesion Enhancement

Coating Life Extension

Sterilization

Weld Cleaning

View the full report and table of contents here: https://straitsresearch.com/report/laser-cleaning-market/toc

The report forecasts revenue growth at all geographic levels and provides an in-depth analysis of the latest industry trends and development patterns from 2022 to 2030 in each of the segments and sub-segments. Some of the major geographies included in the market are given below:

North America (U.S., Canada)

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

Asia Pacific (China, India, Japan, Singapore, Malaysia)

Latin America (Brazil, Mexico)

Middle East & Africa

This Report is available for purchase on Buy Laser Cleaning Market Report

Key Highlights

Provide a detailed explanation of various aspects including introduction, product types and applications, market overview, country-specific market analysis, opportunities, risks, and driving forces.

Examine manufacturers, including their profiles, primary business activities, recent news, sales and pricing, revenue, and market share.

Offer an overview of the competitive landscape, detailing sales, revenue, and market share among leading global manufacturers.

Present a detailed market breakdown by type and application, including sales, pricing, revenue, market share, and growth rates.

Analyze key regions—North America, Europe, Asia Pacific, the Middle East, and South America—covering sales, revenue, and market share segmented by manufacturers, types, and applications.

Investigate production costs, essential raw materials, and production methods.

Reasons to Buy:

In-depth analysis of market segmentation.

Country-specific insights alongside global demand and supply dynamics.

Examination of key players, including their products, financial performance, and strategies.

Insights into emerging market trends, opportunities, and challenges.

About Us:

StraitsResearch.com is a leading research and intelligence organization, specializing in research, analytics, and advisory services along with providing business insights & research reports.

Contact Us: Email: [email protected] Address: 825 3rd Avenue, New York, NY, USA, 10022 Tel: +1 6464807505, +44 203 318 2846

Laser Processing Industry Growth Trends, Research and Revenue Analysis, 2030

The global laser processing market was valued at USD 17.48 billion in 2021 and is projected to grow at a compound annual growth rate (CAGR) of 9.1% from 2022 to 2030. This anticipated growth is primarily due to the increasing use of lasers in medical devices, particularly in surgical applications, where lasers provide precise, minimally invasive solutions. Additionally, the rapid advancement of nano-fabrication technology is expected to drive demand for laser processing, given its applications in high-precision fields such as microelectronics and medical devices. Furthermore, the manufacturing sector has increasingly adopted laser processing due to its advantages over traditional methods for material processing, contributing significantly to the market's growth.

Traditional processing techniques, such as manual metal arc welding, present high environmental risks. This concern has been alleviated by using laser processing, particularly in the automotive industry. For instance, in July 2021, Furukawa Electric introduced an industrial fiber laser system with a 12kw fiber laser that can handle complex automotive manufacturing tasks such as welding car bodies, processing aluminum, welding batteries, and assembling motors, further demonstrating the role of laser technology in reducing environmental impact and enhancing manufacturing precision.

Gather more insights about the market drivers, restrains and growth of the Laser Processing Market

Government regulations supporting the use of laser technology for product marking and engraving are expected to positively impact market growth. Laser processing technology is increasingly popular across various applications, including welding, marking, cutting, drilling, and engraving. Strict government directives, combined with the expanding use of laser technology in medical applications, are likely to drive significant market growth in the coming years. For instance, in the field of eye surgery, LASIK and refractive technologies utilize lasers to correct vision issues such as myopia, hyperopia, presbyopia, and astigmatism.

Technical advancements have also improved the quality and speed of laser processing. Hamamatsu Photonics, for example, developed a spatial light modulator (SLM) with a liquid-crystal design capable of handling pulsed laser powers up to 400 GW/cm², enabling high-throughput and high-precision laser processing for industries that demand precise manufacturing capabilities.

Application Segmentation Insights:

In 2021, the machine tools segment led the laser processing market with over a 30% revenue share. This segment benefits from the widespread adoption of laser technology in industrial material processing applications such as cutting, welding, drilling, and engraving. The demand for laser processing is growing in sectors like microelectronics and medical devices. In medical manufacturing, welding is vital for creating devices like pacemakers, implantable devices, and surgical tools that require ultra-fine, non-porous, and sterile materials suitable for use in cardiac surgeries.

Investments in research and development by industry players are further propelling the market. For example, researchers at Fudan University have developed an all-silicon laser with high optical gains using silicon nanocrystals, similar to gallium arsenide (GaAs) and indium phosphide (InP). This silicon-based laser, used in fields such as sensing, communication, displays, detection, and imaging, combines microelectronics and optoelectronics, expanding laser processing applications. Emerging applications in automotive and oil and gas sectors, along with demand in machine tool manufacturing, are expected to support market growth. In automotive manufacturing, laser cutting offers benefits like high processing speeds, superior edge quality, and reduced heat input, which are crucial for efficient automobile production.

In summary, the laser processing market is expected to experience robust growth driven by advances in medical applications, government regulations, technical innovations, and widespread industrial use across various sectors.

Order a free sample PDF of the Laser Processing Market Intelligence Study, published by Grand View Research.

Laser Processing Industry 2030 Overview, Regional Outlook, Growth Report

The global laser processing market was valued at USD 17.48 billion in 2021 and is projected to grow at a compound annual growth rate (CAGR) of 9.1% from 2022 to 2030. This anticipated growth is primarily due to the increasing use of lasers in medical devices, particularly in surgical applications, where lasers provide precise, minimally invasive solutions. Additionally, the rapid advancement of nano-fabrication technology is expected to drive demand for laser processing, given its applications in high-precision fields such as microelectronics and medical devices. Furthermore, the manufacturing sector has increasingly adopted laser processing due to its advantages over traditional methods for material processing, contributing significantly to the market's growth.

Traditional processing techniques, such as manual metal arc welding, present high environmental risks. This concern has been alleviated by using laser processing, particularly in the automotive industry. For instance, in July 2021, Furukawa Electric introduced an industrial fiber laser system with a 12kw fiber laser that can handle complex automotive manufacturing tasks such as welding car bodies, processing aluminum, welding batteries, and assembling motors, further demonstrating the role of laser technology in reducing environmental impact and enhancing manufacturing precision.

Gather more insights about the market drivers, restrains and growth of the Laser Processing Market

Government regulations supporting the use of laser technology for product marking and engraving are expected to positively impact market growth. Laser processing technology is increasingly popular across various applications, including welding, marking, cutting, drilling, and engraving. Strict government directives, combined with the expanding use of laser technology in medical applications, are likely to drive significant market growth in the coming years. For instance, in the field of eye surgery, LASIK and refractive technologies utilize lasers to correct vision issues such as myopia, hyperopia, presbyopia, and astigmatism.

Technical advancements have also improved the quality and speed of laser processing. Hamamatsu Photonics, for example, developed a spatial light modulator (SLM) with a liquid-crystal design capable of handling pulsed laser powers up to 400 GW/cm², enabling high-throughput and high-precision laser processing for industries that demand precise manufacturing capabilities.

Application Segmentation Insights:

In 2021, the machine tools segment led the laser processing market with over a 30% revenue share. This segment benefits from the widespread adoption of laser technology in industrial material processing applications such as cutting, welding, drilling, and engraving. The demand for laser processing is growing in sectors like microelectronics and medical devices. In medical manufacturing, welding is vital for creating devices like pacemakers, implantable devices, and surgical tools that require ultra-fine, non-porous, and sterile materials suitable for use in cardiac surgeries.

Investments in research and development by industry players are further propelling the market. For example, researchers at Fudan University have developed an all-silicon laser with high optical gains using silicon nanocrystals, similar to gallium arsenide (GaAs) and indium phosphide (InP). This silicon-based laser, used in fields such as sensing, communication, displays, detection, and imaging, combines microelectronics and optoelectronics, expanding laser processing applications. Emerging applications in automotive and oil and gas sectors, along with demand in machine tool manufacturing, are expected to support market growth. In automotive manufacturing, laser cutting offers benefits like high processing speeds, superior edge quality, and reduced heat input, which are crucial for efficient automobile production.

In summary, the laser processing market is expected to experience robust growth driven by advances in medical applications, government regulations, technical innovations, and widespread industrial use across various sectors.

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Automotive Body-in-white Market Projections: Global Industry Analysis and Forecast (2023-2032)

The global automotive body-in-white market has grown steadily in recent years and is predicted to increase at a CAGR of 2.50% between 2023 and 2030. In 2022, the market was worth USD 79.2 billion, and it is predicted to grow to USD 94.5 billion by 2030.

The automotive body-in-white (BIW) refers to the stage in vehicle manufacturing where a car body’s frame, made primarily from welded sheet metal components, is constructed before moving on to painting and final assembly. At this stage, all structural and non-moving components are assembled into a single shell, which includes the vehicle’s roof, door frames, side panels, and pillars. The BIW structure is critical to vehicle safety, durability, and weight, making it essential for automotive manufacturers to focus on materials and design that optimize strength while minimizing weight. Lightweight materials, such as high-strength steel, aluminum, and composites, are increasingly used in BIW production to meet stringent fuel efficiency and emission standards. Advances in manufacturing techniques, such as laser welding, robotic assembly, and adhesive bonding, are also transforming BIW construction, allowing for enhanced precision and durability. As the automotive industry moves toward electric and autonomous vehicles, BIW designs are evolving to incorporate features for battery placement, sensor integration, and structural rigidity, highlighting the BIW’s pivotal role in vehicle innovation.

The automotive body-in-white (BIW) market is set for considerable growth, fueled by several opportunities linked to advancements in materials, manufacturing processes, and automotive trends. Key growth opportunities include:

Increased Demand for Lightweight Materials: With stringent fuel efficiency and emissions regulations, manufacturers are focusing on reducing vehicle weight, creating a strong demand for lightweight BIW materials such as high-strength steel, aluminum, and carbon fiber composites. These materials allow manufacturers to enhance fuel economy without compromising safety.

Growth of Electric Vehicles (EVs): The rapid adoption of EVs opens up new design possibilities and structural requirements for BIW, as these vehicles need reinforced frameworks to support heavy batteries while maximizing interior space. This shift is driving innovation in BIW materials and layouts to accommodate battery modules and improve energy efficiency.

Advancements in Manufacturing Techniques: Emerging technologies such as laser welding, adhesive bonding, and robotic assembly enhance BIW production by increasing precision, improving structural strength, and reducing assembly time. These techniques offer manufacturers cost-efficient solutions to achieve high-quality, durable frames.

Adoption of Modular BIW Design: Modular design approaches enable manufacturers to streamline production by using standardized BIW components across different models, reducing costs and enhancing manufacturing flexibility. This trend is especially relevant for global manufacturers looking to optimize production for diverse markets.

Growing Popularity of Autonomous Vehicles: Autonomous vehicle development requires BIW structures that can support an array of sensors, cameras, and LiDAR systems, while also ensuring safety. This need for integrated BIW solutions creates opportunities for customized designs that cater specifically to autonomous vehicle requirements.

Expansion in Emerging Markets: As vehicle production expands in emerging economies, particularly in Asia-Pacific and Latin America, there is a rising demand for cost-effective, lightweight, and efficient BIW solutions. Growth in these regions is driven by increasing vehicle sales, urbanization, and economic development.

Sustainability and Recyclable Materials: Consumer and regulatory demands for sustainable practices are pushing manufacturers to use recyclable materials and eco-friendly production techniques in BIW manufacturing. Recyclable aluminum and high-strength steels, which reduce environmental impact, are gaining traction in this shift toward sustainable BIW solutions.

Increased Focus on Safety Standards: As global safety standards become more stringent, there is a need for BIW designs that enhance crashworthiness and passenger protection. Advanced BIW materials and engineering approaches that absorb and distribute impact forces offer growth opportunities for safety-focused innovations.

Collaborations and Joint Ventures: Partnerships between material suppliers, automotive OEMs, and technology companies are creating avenues for shared research and development, especially in lightweight materials, advanced welding techniques, and modular designs, accelerating BIW innovation.

R&D Investments in Hybrid Material BIWs: Hybrid BIW structures that combine materials, like steel-aluminum composites, optimize weight and strength, offering an attractive solution for performance and cost. Investments in R&D to develop these materials are growing, allowing for lighter, more durable BIW solutions.

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Key Players

Thyssenkrupp AG

Tata Steel Limited

Kuka AG

TECOSIM Group

Magna International Inc.

ABB Corporation

Gestamp Automocion SA

Aisin Seiki Co. Limited

Dura Automotive Systems

Tower International

CIE Automotive

Benteler International

Norsk Hydro ASA

The automotive body-in-white (BIW) market is influenced by several trending factors as the industry adapts to changing technologies, consumer demands, and regulatory pressures. Key trending factors include:

Lightweighting for Fuel Efficiency: With stricter fuel efficiency and emission regulations, reducing vehicle weight has become a priority. This trend is driving a shift from traditional materials like mild steel to lighter alternatives such as high-strength steel, aluminum, and composite materials, enabling manufacturers to improve fuel economy while meeting safety standards.

Increased Demand from Electric Vehicles (EVs): The rise of EVs has reshaped BIW requirements, as electric vehicles require reinforced and optimized structures to support battery packs and maximize range. BIW designs are increasingly incorporating materials and layouts specifically tailored to enhance energy efficiency and accommodate battery systems.

Modular and Flexible BIW Designs: Manufacturers are adopting modular BIW designs to increase production flexibility and efficiency. Modular platforms enable the same BIW components to be used across multiple vehicle models, streamlining manufacturing, reducing costs, and enabling faster model variations for a range of vehicle segments.

Advancements in Joining Techniques: The use of advanced joining technologies, such as laser welding, adhesive bonding, and friction-stir welding, allows for stronger, lighter, and more precise BIW assemblies. These methods are particularly important as they enable multi-material construction, a critical factor in lightweight BIW design.

Focus on Crashworthiness and Safety: As safety regulations become more stringent worldwide, automakers are investing in BIW structures that improve crashworthiness. Trends in BIW design now include crumple zones, high-strength materials in critical areas, and optimized load paths to protect occupants during collisions.

Integration of Autonomous Vehicle (AV) Features: Autonomous vehicle development requires BIW designs that accommodate sensors, cameras, and other autonomous driving components. This trend leads to specialized BIW frameworks that support integrated technology while maintaining safety and structural integrity.

Increased Use of High-Strength Steel (HSS) and Ultra-High-Strength Steel (UHSS): These materials offer excellent strength-to-weight ratios and are becoming popular in BIW construction. HSS and UHSS enable manufacturers to reduce weight without compromising safety, balancing cost-effectiveness with performance.

Sustainability and Eco-Friendly Materials: Environmental concerns and regulations around carbon emissions are encouraging the use of recyclable materials in BIW production. Eco-friendly production processes and the use of sustainable materials, like recycled aluminum, are gaining popularity as automakers seek to lower their carbon footprint.

Digitalization and Smart Manufacturing: Automation, robotics, and data-driven processes are increasingly used in BIW manufacturing to enhance precision, reduce waste, and optimize production. Technologies like digital twins and IoT-driven quality checks enable real-time monitoring and efficient assembly.

Growing Popularity of Mixed Material BIWs: Mixed material BIWs, which combine materials like aluminum, carbon fiber, and high-strength steel, are trending as they provide an optimal balance of weight, strength, and cost. These hybrid structures are especially relevant for performance vehicles, luxury segments, and EVs where weight reduction is crucial.

Segmentation

By Vehicle Type

Passenger Vehicles

Commercial Vehicles

By Propulsion Type

IC Engines

Electric Vehicles

By Material Type

Aluminium

Steel

Composites

Other Material Types

By Material Joining Technique

Welding

Clinching

Laser Brazing

Bonding

Other Material Joining Techniques

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Types and Characteristics of diode laser module

Diode laser module are devices that convert electrical energy into light energy. They are known for their small size, lightweight, high efficiency, and long lifespan. They are widely used in various fields such as industry, medicine, research, and military, including laser processing, optical communication, medical treatment, and laser ranging.

Types and Characteristics of diode laser module

Edge-emitting lasers (EELs): Mature technology, broad wavelength range, high electro-optical conversion efficiency, suitable for laser processing and optical communication.

Vertical-Cavity Surface-Emitting Lasers (VCSELs): Small size, suitable for the consumer electronics market, complementary to EELs in emerging applications.

High-power GaN-based lasers: Used for illumination, night vision, sensing, communication, etc., capable of long-distance detection and LiDAR imaging.

Fiber-coupled modules: Convenient for fiber transmission, suitable for solid-state laser pumping, material processing, medical treatment, etc.

Unpackaged bars and chips: Based on GaAs, InP, GaSb semiconductor structures, providing wavelengths from 750 nm to 2200 nm.

Application Examples

In the field of optical communication, EELs are typically used for long-distance and high-speed transmission, while VCSELs are used for short-distance and low-speed transmission.

In the consumer electronics market, VCSELs are widely used due to their small size and narrow wavelength, while EELs are suitable for long-range sensing and high-power processing.

In LiDAR applications, both EELs and VCSELs can be used for medium and short-range LiDAR, enabling features like blind spot detection and lane departure.

Technological Developments

With technological advancements, the performance of diode laser module in terms of power, reliability, and energy conversion efficiency has greatly improved.

High-power diode laser module are rapidly maturing in technology, with decreasing prices and expanding applications, such as laser welding and laser cutting.

Narrow linewidth diode laser module have broad applications in pump sources, Raman spectroscopy, laser-induced fluorescence, and other fields.

Market Prospects

It is expected that the edge-emitting laser market will grow to $7.4 billion by 2027, with a compound annual growth rate of 13%.

High-power semiconductor laser technology is rapidly maturing, with prices dropping and applications expanding.

In summary, diode laser module, due to their efficient, compact, and reliable characteristics, have a wide range of applications in various fields. With the continuous development of technology, their market prospects are broad.

Ceramic Matrix Composites Market - Latest Innovations by Industry Experts Till 2030

The global ceramic matrix composites (CMC) market was valued at approximately USD 3.40 billion in 2022 and is projected to grow at a compound annual growth rate (CAGR) of 12.8% from 2023 to 2030. The increasing demand for materials with high-temperature stability, reduced weight, and exceptional strength is a key driver for this market’s growth. These properties make CMCs highly valuable in demanding applications where traditional materials often fall short. The chemical industry experienced a significant shift in the first half of 2020, as companies were already facing complex, long-term challenges and were further impacted by the economic downturn associated with the COVID-19 pandemic and the concurrent oil price collapse, which influenced the entire CMC market landscape.

The high cost of ceramic fibers remains a significant factor impacting market growth. Unlike carbon fiber, commonly used in metal and polymer composites, ceramic fibers are produced in smaller quantities, which prevents them from benefiting from the economies of scale that reduce costs in high-volume production.

Gather more insights about the market drivers, restrains and growth of the Ceramic Matrix Composites Market

Ceramic matrix composites are finding increasing application in industries like electronics, thermal management, and high-performance sports equipment, where they offer advantages such as improved performance, enhanced comfort, and robust structural integrity. Over the forecast period, CMCs are anticipated to replace traditional alloys and other metals in various applications, particularly where their high thermal resistance allows them to function with minimal or no cooling requirements. This quality is particularly valued in the aviation industry, where demand for CMCs is expected to grow significantly.

The United States, as a global military leader, is a major consumer of CMCs. Additionally, the U.S. Department of Energy is researching CMC cladding for fuel rods in light-water nuclear reactors, which could boost CMC demand in the energy and power sectors. In North America, the CMC market is expected to grow as key players increase research and development efforts, expand manufacturing capacity, and broaden their product offerings.

Application Segmentation Insights:

In 2022, the aerospace segment led the CMC market, accounting for over 41.95% of the global revenue share. The demand for ceramic matrix composites in aerospace is driven by their use in manufacturing essential components like noses, rudders, fins, leading edges, body flaps, hot structures, tiles, and panels for aircraft. CMCs’ high impact strength and hardness make them ideal for these applications, as they enhance durability and safety in aerospace structures.

In addition to aerospace, CMCs are valued for their application in manufacturing bullet-proof armor and as insulators for small arms weapon platforms. Many ceramic materials are transparent to specific types of energy and light, making them suitable for infrared domes, sensor protection, and multi-spectral windows.

The energy and power sector is expected to be the fastest-growing application segment for CMCs during the forecast period. With their high-temperature stability, oxidation resistance, and radiation tolerance, CMCs are well-suited for applications in both fission and fusion energy technologies.

Ceramic matrix composites are also widely used as isolators in the electronics industry and are integral to electronic circuits due to their high thermal conductivity. Other CMC applications include laser diodes, LEDs, artificial teeth, and fuel cells, which further support market expansion. These diverse applications make CMCs a valuable material in various high-performance and emerging technological fields.

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Ceramic Matrix Composites Industry Overview, Challenges and Growth Opportunities Analysis till 2030

The global ceramic matrix composites (CMC) market was valued at approximately USD 3.40 billion in 2022 and is projected to grow at a compound annual growth rate (CAGR) of 12.8% from 2023 to 2030. The increasing demand for materials with high-temperature stability, reduced weight, and exceptional strength is a key driver for this market’s growth. These properties make CMCs highly valuable in demanding applications where traditional materials often fall short. The chemical industry experienced a significant shift in the first half of 2020, as companies were already facing complex, long-term challenges and were further impacted by the economic downturn associated with the COVID-19 pandemic and the concurrent oil price collapse, which influenced the entire CMC market landscape.

The high cost of ceramic fibers remains a significant factor impacting market growth. Unlike carbon fiber, commonly used in metal and polymer composites, ceramic fibers are produced in smaller quantities, which prevents them from benefiting from the economies of scale that reduce costs in high-volume production.

Gather more insights about the market drivers, restrains and growth of the Ceramic Matrix Composites Market

Ceramic matrix composites are finding increasing application in industries like electronics, thermal management, and high-performance sports equipment, where they offer advantages such as improved performance, enhanced comfort, and robust structural integrity. Over the forecast period, CMCs are anticipated to replace traditional alloys and other metals in various applications, particularly where their high thermal resistance allows them to function with minimal or no cooling requirements. This quality is particularly valued in the aviation industry, where demand for CMCs is expected to grow significantly.

The United States, as a global military leader, is a major consumer of CMCs. Additionally, the U.S. Department of Energy is researching CMC cladding for fuel rods in light-water nuclear reactors, which could boost CMC demand in the energy and power sectors. In North America, the CMC market is expected to grow as key players increase research and development efforts, expand manufacturing capacity, and broaden their product offerings.

Application Segmentation Insights:

In 2022, the aerospace segment led the CMC market, accounting for over 41.95% of the global revenue share. The demand for ceramic matrix composites in aerospace is driven by their use in manufacturing essential components like noses, rudders, fins, leading edges, body flaps, hot structures, tiles, and panels for aircraft. CMCs’ high impact strength and hardness make them ideal for these applications, as they enhance durability and safety in aerospace structures.

In addition to aerospace, CMCs are valued for their application in manufacturing bullet-proof armor and as insulators for small arms weapon platforms. Many ceramic materials are transparent to specific types of energy and light, making them suitable for infrared domes, sensor protection, and multi-spectral windows.

The energy and power sector is expected to be the fastest-growing application segment for CMCs during the forecast period. With their high-temperature stability, oxidation resistance, and radiation tolerance, CMCs are well-suited for applications in both fission and fusion energy technologies.

Ceramic matrix composites are also widely used as isolators in the electronics industry and are integral to electronic circuits due to their high thermal conductivity. Other CMC applications include laser diodes, LEDs, artificial teeth, and fuel cells, which further support market expansion. These diverse applications make CMCs a valuable material in various high-performance and emerging technological fields.

Order a free sample PDF of the Ceramic Matrix Composites Market Intelligence Study, published by Grand View Research.

The fiber laser market to grow from USD 7.7 billion in 2024 and is expected to reach USD 12.8 billion by 2029, growing at a CAGR of 10.8% from 2024 to 2029 according to a new report by MarketsandMarkets™. The key factors contributing to the growth of the fiber laser market include the Industrial automation boosts fiber laser adoption for their precision, efficiency, and reliability, growing demand for fiber lasers in medical and healthcare industries, rising adoption of fiber lasers in consumer electronics, expansion of 3D printing and additive manufacturing. Fiber lasers offer high energy efficiency, low maintenance, and long lifespan.