#Pulsed Laser Deposition Systems market Size
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Diode Laser Market - Forecast (2024-2030)
Diode Laser Market Overview:
Diode Laser Market size is estimated to reach US$18.3 billion by 2030, growing at a CAGR of 12.2% during the forecast period 2024-2030. Demand for high-power laser systems and expansion of the 3D sensing market are expected to propel the growth of Diode Laser market.
Additionally, the increasing integration of diode lasers with other technologies, such as photonics, optics, and electronics. This integration is driven by the demand for more sophisticated and multifunctional devices with enhanced performance and capabilities. By combining diode lasers with complementary technologies, manufacturers can develop innovative solutions that cater to the evolving needs of various industries. For example, integrating diode lasers with advanced optics enables the development of high-resolution imaging systems for medical diagnostics and industrial inspection applications. Similarly, incorporating diode lasers into photonics-based sensors enhances their sensitivity and precision for environmental monitoring and defense applications. This trend towards integration not only expands the range of applications for diode lasers but also fosters collaboration and cross-disciplinary innovation within the broader photonics industry.
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Diode Laser Market - Report Coverage:
The “Diode Laser Market Report - Forecast (2024-2030)” by IndustryARC, covers an in-depth analysis of the following segments in the Diode Laser Market.AttributeSegment
By Category
● Injection laser diode
● Optically pumped semi-conductor laser
By Wavelength
● Near infrared
● Red
● Blue
● Green
● Ultra-violet
● Violet
● Yellow
● Others
By Doping Material
● InGaN
● GaN
● AIGaInP
● GaAIAs
● InGaAs
● InGaAsP
● GaInAsSb
● Others
By Technology
● Double hetero structure lasers
● Quantum well lasers
● Quantum cascade laser
● Distributed feedback lasers
● Separate confinement hetero structure laser diode
● VCSEL
● VECSEL
● External cavity laser diode
● Distributed Bragg reflector laser
● Quantum dot laser
● Interband cascade laser diode
By Industry Vertical
● Automotive
○ Autonomous vehicles
▪ LIDAR
● Defense
○ Anti-aircraft missiles
○ Directed energy weapons
○ Range finding
● Medical
○ Aesthetics
○ Diagnostics
▪ Microcopy
▪ Spectroscopy
▪ Others
○ Surgical treatments
▪ Noninvasive surgeries
▪ Others
○ Photodynamic therapy
● Consumer electronics
○ CD/DVD Players
○ Laser printers
○ Barcode readers
○ Fiber optic communication
● Manufacturing
○ Pulsed laser deposition
○ Micromachining
○ Drilling
○ Welding
○ Others
● Data storage
○ Blu-ray disks
○ Magneto-optical disks
● Communications
● Displays
● Others
By Geography
● North America (U.S., Canada and Mexico)
● Europe (Germany, France, UK, Italy, Spain, Netherlands and Rest of Europe),
● Asia-Pacific (China, Japan, South Korea, India, Australia & New Zealand and Rest of Asia-Pacific),
● South America (Brazil, Argentina, Chile, Colombia and Rest of South America)
● Rest of the World (Middle East and Africa).
COVID-19 / Ukraine Crisis - Impact Analysis:
During the COVID-19 pandemic, the diode laser market experienced both challenges and opportunities. On one hand, disruptions in global supply chains and reduced manufacturing activities due to lockdowns and restrictions affected the production and distribution of diode lasers. Many end-user industries, such as healthcare and manufacturing, faced uncertainties, leading to delayed investments in new technologies, including diode laser systems. Additionally, the heightened focus on disinfection and sterilization in healthcare facilities led to increased demand for laser systems used in sterilization processes, further supporting the diode laser market.
In Ukraine, geopolitical tensions and instability have also impacted the diode laser market. Uncertainty surrounding trade relations and economic conditions may have deterred potential investments and hindered market growth. Additionally, disruptions in supply chains and logistics due to conflicts or political unrest could have affected the availability of raw materials and components necessary for diode laser production. Furthermore, the general atmosphere of uncertainty and risk may have led to cautious spending by businesses in Ukraine, potentially slowing down the adoption of diode laser technologies across various sectors.
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Key Takeaways:
APAC Dominated the Market
Geographically, in the Diode Laser market share, APAC region is analyzed to hold a dominant market share of 42% in 2023. Firstly, APAC countries, particularly China, Japan, and South Korea, are renowned for their strong manufacturing capabilities and technological advancements. These countries have robust semiconductor industries, which form the backbone of diode laser production. Additionally, the presence of a vast network of suppliers, skilled labor force, and supportive government policies has further fueled the growth of the diode laser market in the region. Furthermore, APAC's thriving telecommunications industry has been another key contributor to the growth of the diode laser market. With the rapid expansion of 5G networks and the increasing demand for high-speed internet connectivity, there has been a growing need for diode lasers in fiber-optic communications for data transmission. Countries like China and South Korea are at the forefront of 5G deployment, driving significant investments in telecommunications infrastructure and driving the demand for diode lasers.
Medical is the fastest growing segment
In the Diode Laser Market forecast, medical segment is estimated to grow with a CAGR of 5.5% during the forecast period, due to the increasing adoption of minimally invasive procedures and laser-based treatments in various medical specialties such as dermatology, ophthalmology, and dentistry has fueled the demand for diode lasers. Diode lasers offer precise control, minimal tissue damage, and faster recovery times, making them preferred tools for a wide range of medical applications. Moreover, technological advancements in diode laser systems, including improvements in power output, wavelength options, and beam delivery methods, have expanded their utility in medical procedures. For example, diode lasers are used for procedures such as hair removal, skin resurfacing, cataract surgery, and dental treatments, among others. As medical technologies continue to advance and demand for minimally invasive procedures rises, the growth trajectory of the medical segment is expected to remain strong in the coming years.
● GaAlAs to Hold Largest Market Share
According to the Diode Laser Market analysis, Gallium aluminum arsenide (GaAlAs) doping material segment is estimated to hold the largest market share of 28% in 2023. GaAlAs-based diode lasers exhibit excellent optical and electrical properties, including high quantum efficiency and wavelength stability. These characteristics make them ideal for various applications across industries such as healthcare, telecommunications, and manufacturing. GaAlAs doping material allows for precise control over the emission wavelength of diode lasers, enabling customization to meet specific application requirements. This versatility makes GaAlAs diode lasers suitable for a wide range of applications, from medical procedures to telecommunications infrastructure. Furthermore, advancements in GaAlAs fabrication techniques and production processes have led to cost reductions and improved manufacturing yields, making GaAlAs-based diode lasers more economically viable for widespread adoption.
Demand for High-Power Laser Systems
High-power diode lasers offer advantages such as faster processing speeds, increased cutting and welding depths, and improved productivity. These lasers are used in applications such as metal cutting, welding, surface treatment, and additive manufacturing. The demand for high-power diode lasers is driven by the need for greater efficiency, precision, and cost-effectiveness in industrial processes. Additionally, advancements in diode laser technology, such as improved cooling methods and beam shaping techniques, are further driving the adoption of high-power laser systems. In April 2022, Lumentum introduced the FemtoBlade laser system, which is the second generation of the company's portfolio of high-precision ultrafast industrial lasers. The new system features a modular design, which offers high power at high repetition rates, thus ensuring better flexibility and faster processing speed.
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Expansion of the 3D Sensing Market
The rapid expansion of the 3D sensing market is driving the demand for diode lasers used in applications such as facial recognition, gesture recognition, augmented reality (AR), and virtual reality (VR). Diode lasers are key components in 3D sensing systems, providing the light source for depth sensing and spatial mapping. The increasing integration of 3D sensing technology in smartphones, consumer electronics, automotive, and robotics is fueling the demand for diode lasers. Additionally, advancements in diode laser technology, such as wavelength-tunable lasers and compact laser modules, are enabling the development of smaller, more efficient, and cost-effective 3D sensing solutions. In March 2022, IPG Photonics unveiled LightWELD XR, its handheld laser welding and cleaning product. The LightWELD XR is the third offering from the company in the line and includes an expanded material range including aluminum 6XXX series, nickel alloys, titanium, and copper.
High Initial Investment Hinders the Market Growth
In terms of R&D, companies need to invest substantial resources in conducting research to innovate and improve diode laser technology. This includes funding for research personnel, equipment, materials, and facilities to develop next-generation diode lasers. Additionally, R&D efforts are necessary to adapt diode lasers to meet the evolving demands of different industries and applications, driving innovation and competitiveness in the market. Regulatory compliance is a critical aspect that contributes to the high initial investment in the diode laser market. Diode laser systems used in medical, industrial, and other applications must meet stringent regulatory requirements related to safety, efficacy, and quality assurance. Obtaining regulatory approvals and certifications from regulatory authorities such as the FDA (Food and Drug Administration) in various countries involves significant time, effort, and financial resources. Non-compliance with regulatory requirements can result in delays, fines, or even product recalls, posing financial risks to companies
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Key Market Players:
Product/Service launches, approvals, patents and events, acquisitions, partnerships and collaborations are key strategies adopted by players in the Diode Laser Market. The top 10 companies in this industry are listed below:
Coherent Corp.
Spectra-Physics, Inc. (MKS Instruments, Inc.)
Nichia Corporation
Lumentum Holdings Inc.
Sumitomo Electric Industries, Ltd.
Mitsubishi Electric Corporation
TRUMPF Inc.
Jenoptik AG
Osram Opto Semiconductors GmbH (OSRAM GmbH)
IPG Photonics
#Diode Laser Market#Diode Laser Market size#Diode Laser industry#Diode Laser Market share#Diode Laser top 10 companies#Diode Laser Market report#Diode Laser industry outlook
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Portable Handheld Laser Rust Removal Machine
Laser cleaning Machine is a new generation of industrial surface cleaning laser system. It adopts the advanced laser source, laser optical scanners and control system to meet the requirements of metal surface cleaning process.Laser cleaning offers multiple advantages over traditional approaches. It does not involve solvents and there is no abrasive material to be handled and disposed of. Compared with other processes , laser cleaning is controllable and can be applied only to specific areas of a part, can be easily automated to maximize productivity, and provides the guaranteed repeatability demanded by an increasing number of quality standards.
For a long time, the surface treatment capacity of the manufacturing industry lags far behind that of production, which has greatly restricted the process of manufacturing from large to strong. High-end manufacturing and energy saving emission reduction have higher and higher demand for advanced technology. In terms of surface treatment, the technology and process urgently need to be fully upgraded.The high value-added laser technology of hand held laser rust remover is accelerating the replacement of traditional processes, and industry chain companies are stepping up their layout.
Traditional laser cleaning rust removal, such as mechanical friction cleaning, chemical corrosion cleaning, strong impact cleaning, high frequency ultrasonic cleaning, has a long cleaning cycle. It is difficult to realize automation,harmful to the environment, and can not achieve the ideal cleaning effect.Laser cleaning is a more efficient and environmentally friendly process, with no pollution, no consumables, low cost, high efficiency, no contact, no stress, no damage, good controllability, optional precision cleaning, cleaning the dangerous area that difficult to reach . These advantages are challenging traditional processes.
Laser cleaning technology was born in the 1980s, and it didn't really enter industrial production until the early 1990s, and gradually replaced traditional cleaning methods. Due to the relatively limited investment in early technology and manpower, the overall development of the laser cleaning market has been slow. Since 1998, laser cleaning technology has ushered in the first wave of development, mainly led by European and American countries. During this period, laser cleaning applications focused on the surface of metal materials, such as aircraft fuselage paint removal, mold surface degreasing, engine internal carbon deposition, and pre-weld joint surface cleaning. At present, there are three main markets for hand held laser rust remover: one is to replace the existing industrial cleaning (chemical cleaning and ultrasonic), the market size is more than 100 billion, at least 30% can be replaced by laser cleaning, about 30 billion; the second is to replace manual polishing,which can be the standard equipment of every manufacturing workshop, about 10 billion; the third is the newly developed application areas: such as cultural relics cleaning, building cleaning, street cleaning, etc., the market size is about 20 billion.
Igolden laser cleaning machine can meet different application scenarios from pulse laser source and continuous laser source.Specifically, short pulse width can reduce heat input, reduce thermal effects, and improve the oxidation and discoloration of some substrates.pulse laser source can improve the ability to enhance the efficiency of paint removal. It is widely used in the fields of tire mold cleaning, parts oil removal, aero-engine blade thermal barrier coating and oxide film cleaning, metal derusting and varnishing, enamelled copper inductor stripping and so on.
Because the scenes involved in surface treatment are very complicated, and the composition and structure of the attachments on the surface of the object are different, the mechanism of the laser action is also different.laser cleaning is not as easy to promote as laser cutting and laser marking.Enterprises are required to have strong process research and development capabilities. In addition, laser cleaning also has a single nature. How to use a laser to clean different matrix materials is also a very big challenge for laser manufacturers.
The application of large-scale industrialization puts forward higher requirements on the stability and automation level of laser cleaning equipment.Igolden laser cleaning machine comprehensively considers the laser source, motion control, laser head and other links, continuously optimizes the design, and provides customers with more competitive product solutions.
The laser cleaning machine is easy to operate and low maintenance cost. It meets the requirements of environmental protection and has no harm to workers' bodies. And the labor cost is low,the benefits will be quickly obtained.
If you want to know more information about Igolden laser cleaning machine,just contact us.We can test the material according to your requirements.
WHAT CAN A FIBER LASER RUST REMOVER DO?
Fiber laser rust remover is not only a laser rust removal tool, it also used for laser paint removal, laser degreasing, laser removal of oxide layer, laser cleaning screw, laser derusting, laser weld-cleaning.Applied in shipbuilding industry, auto parts, rubber mold, high-end machine tools, tire mold, tracks, environmental protection industry and other industries.
#laser cleaning machine#Fiber laser rust remover#Igolden laser cleaning machine#laser cleaning equipment
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2018 Lumenis PiQo4 Laser Tattoo Removal & Pigmentation with Handpiece (jp/ben45s).
2018 Lumenis PiQo4 Laser Tattoo Removal & Pigmentation with Handpiece; Manufactured on 09/2018; Perfect Cosmetic & Operating Condition; Flash Counts: 1,043,872; 532nm Pulses = 1914, 585nm Pulses = 586, 650nm Pulses = 67, 1064nm Pulses = 81,390; FW: nlsFw v1.27, pdfw v0.07, SW: 1.1.30.0, Reason for Selling: Downsizing; Includes: Articulated Arm, Handpiece with Attachments & Accessories, Key, Interlock, Footswitch, (4) Patient Eyewear, Operator Manual & 90 Day Warranty.(jp/ben45s)
Wavelengths:1064nm,650nm, 585nm & 532nm
Pulse Energy:max. 2000mj
15 Spot Sizes:2-15mm
Laser:Class 4
Pulse Shape:True, Single Pulse (not a ‘pulse train’)
Fast Coverage:Up to 10 Hz
Interface:Tablet with Touchscreen
PicoFractional
Electrical:120 Volt, 10 Amp
Friendly User Interface:Microsoft Surface Table
PiQo4 treats a wide range of pigment colors and its versatile energy matrix ensures effective shattering of pigment deposits. It also has the largest spot size on the market, which allows you to deliver faster treatments. PiQo4’s ability to treat a wide variety of skin conditions, including tattoo removal, provides your customers an attractive range of aesthetic solutions to improve their lifestyle and sense of well-being.
$71,975.00
The PiQo4 brings unique technology with combination of unsurpassed advantages: Pico+Nano, High Energy, Deep Reach & 4 Wavelengths.
Pico+Nano for doubly effective Treatment
Clinical studies have shown that the optimal method for shattering pigment particles is to treat them with both Nano and Picosecond laser pulses*.
First, the Nanosecond pulses are used to deliver short bursts of energy that break down the larger and deeper pigment or ink particles. Then, the area is rescanned with Picosecond pulses that dismantle the smaller and shallower particles. This combination yields far better results than using either one of the technologies on its own.
High Energy very short laser pulses are absorbed into the target areas of the skin causing the conversion of light energy into acoustic waves that shatter the ink/pigment granules in a process that is fast and effective.The high energy levels of PiQo4 allow pigment/tattoo removal with fewer treatments compared with other competing laser systems. PiQo4 provides up to 10 times more energy for both 1064nm and 532nm (650mJ & 325mJ respectively) wavelengths. They can be set as either Nano or Pico, making them suitable for use with both, for dual pulse treatments. Compared to competitive systems
Deep Reach – for Deep Pigment Shattering with PiQo4, your customers will appreciate the faster treatment results with shorter treatment sessions. PiQo4 offers up to 15 spot sizes, ranging from 2mm to 15mm, the largest uniform spot size in today’s aesthetics industry and almost four times larger than that of the closest competitor.PiQo4’s larger spot sizes allow deeper maintenance of penetration into the dermis and better dispersal of the pigment or embedded ink particles. Studies have demonstrated that treatment with a large spot size at low fluences significantly decreases any occurrence of blistering, discoloration or scarring* on the skin’s surface, since the energy is being spread over a wider area.
4 Wavelengths – For effective shattering of the most popular pigment/ink colors.
Since each pigment color absorbs a specific wavelength, PiQo4 offers 4 wavelengths in order to treat the broadest range of pigment/tattoo colors, on the widest range of skin types. Its four wavelengths – 1064nm, 532nm, 650nm and 585nm – target 9 of the most frequently used tattoo colors ranging from light orange to dark black. With PiQo4 you can erase the rainbow. For more information visit our website details: https://www.rockbottomlasers.com/
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Distributed temperature sensors promote warning systems
If you are interested in DTS systems and want to learn more, please contact us at [email protected]
Temperature is a key safety indicator in any industry. The technology of distributed temperature sensors using optical fiber allows measuring the temperature at any point in the fiber, with an interval of 1 meter, resulting in the detailed temperature dependence of all required areas. The data obtained by this technique makes it possible to develop intelligent warning systems based on it, therefore, replacing outdated point-based monitoring systems.
The optical fiber itself acts like a fiber optic sensor, and the distributed nature of the DTS technology enables us to determine the temperature change at an arbitrary point, spreading many kilometers from it. Moreover, the measurement quality is not affected by electromagnetic radiation, thus, the distributed temperature technology is free from false alarms.
To be more precise, distributed temperature sensors (DTS) allow measuring the characteristics of an object along a fiber optic cable, while the fiber cable is a linear sensor, which is a continuously distributed sensing element throughout its entire length.
The operating principle is based on the reflectivity of stimulated Raman scattering of light (Raman effect). A semiconductor laser is also used to determine the location of temperature changes in a fiber optic cable. The fact is that the structure of the optical fiber changes when the temperature changes.
When laser beam light from the laser system enters the area of temperature change, it interacts with the changed structure of the optical fiber and in addition to direct light scattering, reflected light appears.
The main advantages of fiber optic sensors in comparison with classical analogs are the following:
• Compact size;
• Very fast response to parameter changes in the environment;
• Low weight;
• Multiple parameters can be registered simultaneously by a single distributed sensor;
• Reliability;
• Very wide operating temperature range of DTS;
• Small price per unit length of the sensing system;
• High sensitivity;
• Long operating time;
• The high spatial resolution of temperature sensors;
• Resistance to chemicals and aggressive environments;
• DTS is not affected by electromagnetic disturbances;
• The sensitive part of the fiber sensor does not require connection to power lines.
The processing unit measures the propagation speed and power of both direct and reflected light and determines where the temperature changes. For instance, at a wavelength of 1550 nm, a pulsed generation mode is used with a laser power limit of 10 mW.
There are several types of optical fibers, each of which meets certain requirements for its properties, depending on the application due to the fact that the properties of the optical fiber can be varied over a wide range.
Physical effects on the optical fiber, such as pressure, deformation, temperature change, affect the properties of the fiber at the point of exposure and it is possible to measure the environmental parameters by measuring the change in the properties of the fiber at a given point.
In general, a fiber optic sensor consists of two concentric layers: fiber core and optical coating. The fiber optic light guide part can be protected by a layer of acrylate, plastic, reinforced sheath, etc., depending on the application of this fiber cable.
Thus, distributed fiber optic sensors are perfect for industries related to combustible and explosive materials, such as coal, oil and gas production, etc. for use in fire alarm systems of various structures.
Application of distributed temperature sensors includes:
• fire alarm systems in the road, rail or service tunnels;
• thermal monitoring of power cables and overhead transmission lines to optimize production processes;
• improving the efficiency of oil and gas wells;
• ensuring the safe working condition of industrial induction melting furnaces;
• monitoring the tightness of containers with liquefied natural gas on ships in unloading terminals;
• detection of leaks in dams;
• temperature control in chemical processes;
• leak detection in pipelines.
In addition, DTS systems combined with other tools open completely new areas of application. For example, it is possible to design a specialized device - a fire detector based on a distributed fiber optic temperature sensor.
Detecting a fire in an industrial environment is not an easy task because of the large number of disturbing factors, many of which can be considered by detectors as carriers of fire signs. In addition, dust deposited on the DTS' sensitive elements makes it difficult to operate and it can disable them.
It is also necessary to take into account the possible smoldering of the deposited dust, which can also lead to false alarms. The presence of fumes and aerosols makes it impossible to operate smoke optical-electronic fire detectors. The presence of carbon monoxide will trigger gas fire detectors.
Industrial facilities and production are characterized by large volumes of premises, high ceilings, the presence of long tunnels, collectors, mines, inaccessible areas and premises with a complex configuration and geometry. And in these conditions, it is certainly possible to protect using traditional fire alarm systems, but this involves the use of a large number of detectors, and therefore they have high costs, including installation and maintenance of alarm systems and automation.
It is difficult to select detectors for explosive zones, especially for use in underground operations and mines. Aggressive media are often present in chemical industries. There are also objects of sea and river transport, characterized by the aggressive salt fog.
The use of non-electric sensing devices, the use of fiber optic cable allows the DTS to be applied in enterprises of the oil and gas complex, mines, underground operations, chemical industries (including those with aggressive environments), and metallurgy and energy enterprises.
As for oil companies, the active development of high-viscosity oil fields, which imposes strict requirements on the production equipment, and the severe depletion of most oil and gas fields require mining organizations to conduct prospecting and exploration operations, change production technologies and control the technical condition of wells.
The main task for mining companies to increase the well's production capacity in real-time is to track information about the processes occurring in wells and fields. Solutions based on standard temperature sensors suggest well logging using point measuring instruments, which leads to the inaccuracy of the data obtained.
The disadvantages of such sensing devices include the inability to fix the distribution of one of the most important parameters of the well – the temperature profile in real-time, as well as the need for power supply, the impact on the measurement results of external electromagnetic fields, labor and time costs required for the departure of the team and performing various operations, including the immersion of the fiber sensor element and its movement along the well, data processing, etc.
The fiber optic sensing system consists of distributed temperature sensors designed to measure temperature along the borehole, and point-to-point fiber pressure sensor. Optical fibers of a distributed temperature sensing system and pressure sensors can be structurally installed in a single fiber cable.
The fiber optic cable is resistant to mechanical damage. Additional fiber optic cable protection is not required during descent and lifting operations, but the protection of the fiber cable from mechanical damage during descent and lifting operations can be provided by the use of protective coatings.
If you want to obtain a highly efficient distributed temperature sensing system, you should choose the Optromix company. Optromix is a manufacturer of innovative fiber optic products for the global market. The company provides the most technologically advanced fiber optic solutions for monitoring worldwide. Optromix is a fast-growing vendor of fiber Bragg grating (FBG) products line such as fiber Bragg grating sensors, FBG interrogators and multiplexers, distributed acoustic sensing (DAS) systems, distributed temperature sensing (DTS) systems.
Distributed temperature system provides continuous underground power lines monitoring of temperatures, detecting hot spots, delivering operational status, condition assessment, and power circuit rating data. This helps operators to optimize the transmission and distribution networks, and reduce the cost of operation and capital.
Usually, the DTS systems can detect the temperature to a spatial resolution of 1 m with precision to within ±1°C at a resolution of 0.01°C. Measurement distances of greater than 30 km can be monitored and some specialized systems can provide even tighter spatial resolutions.
The advantages of working with Optromix:
Our DTS system has the superior quality, however, its price is one of the lowest in the market;
Optromix is ready to develop DTS systems based on customer’s specifications.
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Fiber Laser Market to increase at a CAGR of 9.8% through 2027
Future Market Insights (FMI), a multinational market intelligence firm, in its recently released report on the global fiber lasers market gives a comprehensive analysis of the future demand scenario of fiber lasers along with insights into the key dynamics shaping the growth trajectory, overcast period of 2019-2028.
Given the progressive developments made by fiber lasers, in terms of spectral coverage, output power, and ultrashort pulse width, the application of fiber lasers has extended in a host of high-power and low-power end-use markets including healthcare, defense and security, and research and development. In addition, with new advancements in fiber lasers such as the quasi continuous wave (QCW) fiber lasers, the demand fiber laser is projected to grow at a promising rate of 8.8 percent, annually through 2019. Nearly 68,400 sq. meters of fiber lasers are expected to be sold in 2019, equaling a market value of approximately US$ 2.4 Billion, as per the market analysis.
According to a senior analyst at FMI, “Superior advantages of fiber lasers over conventional lasers including higher performance, low cost, ease of use, compact size, and choice of wavelengths and precise control of beam will further push the sales of fiber lasers in the coming years. In addition, the on-going demand for fiber laser is also driven by high process speeds, when working with thicker sheets of certain materials.”
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Over the last decade, the overall fiber laser landscape had witnessed a range of new devices, with exception beam quality, output power, and overall efficiency and flexibility in terms of radiation arrangements and operating wavelength. Such developments can largely be attributed to fiber laser’s geometry which offers notable flexibility to the effects of heat generation in the core, thereby translating into high-brightness laser output”, the analyst explains further.
Swelling demand in the aerospace and automotive industries to address manufacturing challenges, considering the product’s superior beam quality for various material processing applications, will drive up the sales of fiber lasers.
Moreover, energy efficient processes with minimized material and operational costs remains a key advantage of fiber lasers over conventional laser welding. For the aerospace industry, technical advancements in fiber lasers has opened doors for application in 3D printers for material deposition.
Fiber laser welding technology is likely to foster an environment for lower cost and higher reliability batteries—used in the new-age electric vehicles. While automotive and aerospace industries will remain the two prominent large-scale end-users of fiber laser, FMI foresees substantial demand in medical applications, including urology.
Key Trends Identified:
Companies have been successful in reducing the cost of manufacturing with fiber lasers. Use of high-strength steel in automotive manufacturing and decreasing the weight of vehicles are driving the use of fiber lasers over other manufacturing methods such as stamping, non-laser welding, riveting and adhesives.
Miniaturization of electronics and parts is projected to contribute to the increasing sales of fiber lasers.
Prominent companies continue to expand sales of specialized laser-based systems to meet the specific needs of manufacturing end users.
Newer generations of fiber lasers are now being equipped with additional sensors, allowing more advanced functions to be performed.
Segmental Insights at a Glance
FMI’s in-depth analysis of the global fiber laser market offers key insight on the various market segments, including key regional pockets, laser type, output power, and application.
In terms of laser type, Continuous Wave (CW) fiber laser is estimated to account for approximately 76.4 percent revenue share, through 2019, given its ability to work with reflective metals. The largest share is contributed by China region in CW fiber lasers market.
On the basis of output power, use of high power (More than 2000 W) fiber laser will increase in the coming years.
Welding and other high power applications will display maximum adoption of fiber laser, through the forecast period.
Regionally, China will remain the most lucrative market for fiber lasers manufacturers, given the expanding manufacturing capabilities of the region.
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The global fiber laser market showcases a consolidated market structure, with top 5-6 key manufacturers accounting for more than 4/5th of the global fiber laser market. Key differentiation strategies include, acquisitions, regional expansion, and new product innovations.
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Fiber lasers: unique tools for automotive & aerospace manufacturing
by Dr Nilushi Wijeyasinghe, Technology Analyst, IDTechEx
Automotive and aerospace manufacturers are increasingly turning to fiber lasers to resolve their manufacturing challenges. Fiber lasers are very stable and reliable instruments, which offer the best beam quality for material processing applications where precision is important. Compared to traditional manufacturing processes such as resistance spot welding or conventional laser welding (gas and solid-state), fiber lasers offer improved energy efficiency, smaller machine footprint, lower maintenance requirements, improved machine lifetime and faster cycle times for high-volume production. Consequently, process speed is maximized; material costs and operation costs are minimized.
The superior precision provided by fiber lasers is particularly useful for manufacturers switching to electric and lightweight vehicle designs. Significant weight reduction is achieved by minimizing the size of flanges via fiber laser welding, while the safe engineering of batteries is enabled by wobble-beam fiber welding. Key players developing fiber lasers for automotive manufacturing include Trumpf (Germany) and the fiber laser market leader IPG Photonics (USA). While laser processing is less common in the aerospace industry, activities such as the Innovate UK OLIVER project that explores game-changing technologies for aerospace aim to improve this with support from IPG Photonics. 94.6% of the $1.409 billion revenue IPG Photonics reported for 2017 originated from material processing. End-users of IPG Photonics fiber lasers include Volkswagen, BMW, Ford and Boeing.
Inside a fiber laser, rare-earth metal elements doped into an optical fiber function as the gain medium and determine the infra-red output wavelength. Fiber lasers can easily achieve average output power in the range of 1 W to >10 kW, or function as ultrafast pulsed energy sources. Many fiber-based machines utilize back reflection protection protocols for optimized processing of reflective metals.
Technical advances and price reduction in fiber laser systems have also led to their utilization in 3D printers for metal deposition, which are primarily targeted at the aerospace industry. Products available range from metal printers using powder bed fusion processes to those employing wire-fed deposition. The latter enables dual functionality in additive manufacturing and laser brazing. Examples of cost-effective, fiber-based 3D printers include those offered by Xact Metal (USA), which spun out from Penn State University & established itself as a new player in the 3D printer market in 2017. Xact's selective laser melting machines can print several metals including aluminium, titanium, stainless steel & superalloys. The key innovation is the patented gantry system with lightweight mirrors that move the laser beam in X-Y motion. The absence of complex optics present in conventional metal printers reduces system cost.
An unbiased analysis of these technologies and markets is available in a report titled Fiber Lasers 2018-2028: Technologies, Opportunities, Markets & Forecasts, which was recently published by technology consulting company IDTechEx. The report provides an independent assessment of fiber laser innovations that will have a major impact on the automotive and aerospace industries within the next decade. It also contains company profiles and product overviews of 22 fiber laser suppliers, which includes all major fiber laser suppliers based in Europe, USA and Asia. IDTechEx forecast the global fiber laser market to reach a size of $8.9 billion in 2028.
To find out more about the IDTechEx report "Fiber Lasers 2018-2028: Technologies, Opportunities, Markets & Forecasts", visit http://www.IDTechEx.com/fiber
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Photo captions:
1. Fiber laser processing enables fast, high-quality, precision engineering of lightweight bodies, batteries and power electronics. Image source: Trumpf
2. Fiber lasers are based on metal doped optical fibers. Image source: Fraunhofer ILT
3. 3D printing of metals enabled via selective laser melting with a fiber laser system. Image source: Xact Metal.
4. Preview of the global fiber laser market forecast based on original research by IDTechEx. Source: IDTechEx
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Summary: The Global Pulsed Laser Deposition Systems Market report basically gives the Market share of more than 10 top key players like AdNaNoTek, PVD Products, BlueWave Semiconductors, SVT Associates (SVTA), DE Technology, Scienta Omicron, O.R. Lasertechnology, Neocera, Henniker Scientific, Solmates, GermanTech, NBM Design, Beijing HONKON Technologies, Plasmionic Technologies, LJ UHV Technology etc
Market Overview of Global Pulsed Laser Deposition Systems Industry: This report gives us an overview of the Global Pulsed Laser Deposition Systems Market which is classified on the basis of product and its various applications. It also mentions the key area where the demand for Pulsed Laser Deposition Systems products is going to have. Also based on the type of the product the market is divided into various sections such as what are the current trends also, what are the end-users and the technology.
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The various products in the Global Pulsed Laser Deposition Systems market along with their numerous applications are also examined in the report. It gives researchers a well-charted map as to where the potential investments need to be done. Also, there are some precautionary factors to be looked at to have an idea of which market route to take. It also mentions the various insights and parameters which will help propel the growth of the Pulsed Laser Deposition Systems market and bring to forth the various opportunities available in the market.
This Pulsed Laser Deposition Systems Market Report scrutinizes the competition subtitles and keeps you in the forefront. It offers an in-depth analysis of the different verticals which brings to the spotlight the working of the Pulsed Laser Deposition Systems Market.
Scope of the Report
The Pulsed Laser Deposition Systems market is characterized by constant technological innovation to keep pace with the changing industrial needs. This Market report provides a detailed analysis of worldwide markets for Pulsed Laser Deposition Systems from 2012-2018 by top Key manufacturers analysis, region, Types, and Market segment by Applications.
The Report can be customized according to your needs. Contact our expert team today along with your requirements:
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Key Question for this Market Report
What are the most important aspects driving the worldwide Pulsed Laser Deposition Systems Market?
What are the necessary trends impacting the build-up of the worldwide Pulsed Laser Deposition Systems Market?
What is going to the industry size as well as growth rate be in 2025?
Who will be the key manufacturers in this particular Market space?
What are the trending factors influencing the Market shares in next few years?
Table of Content
1 Market Overview
1.1 Product Overview and Scope of Pulsed Laser Deposition Systems
1.2 Pulsed Laser Deposition Systems Segment by Type (Product Category)
1.2.1 Global Pulsed Laser Deposition Systems Production and CAGR (%) Comparison by Type (Product Category)(2018-2025)
2 Global Pulsed Laser Deposition Systems Market Competitions by Manufacturers
3 Global Capacities, Production, Revenue (Value) by Region (2012-2018)
Continued…
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We at Reports Monitor provide an in-depth analysis and key data on the specific Pulsed Laser Deposition Systems Market you are looking for. Our Reports are thoroughly researched and a valuable source of guidance for companies and individuals looking for information for the same.
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