|
市場調査レポート
商品コード
1126419
世界の超高速レーザー市場規模、シェア、産業動向分析レポートパルス時間別、エンドユーザー別、タイプ別(ファイバーレーザー、モードロックレーザー、チタンサファイアレーザー、その他)、アプリケーション別、地域別展望・予測、2022年~2028年Global Ultrafast Lasers Market Size, Share & Industry Trends Analysis Report By Pulse Duration, By End User, By Type (Fiber Lasers, Mode-Locked Lasers, Titanium-Sapphire Lasers, and Others), By Application, By Regional Outlook and Forecast, 2022 - 2028 |
||||||
世界の超高速レーザー市場規模、シェア、産業動向分析レポートパルス時間別、エンドユーザー別、タイプ別(ファイバーレーザー、モードロックレーザー、チタンサファイアレーザー、その他)、アプリケーション別、地域別展望・予測、2022年~2028年 |
出版日: 2022年08月31日
発行: KBV Research
ページ情報: 英文 286 Pages
納期: 即納可能
|
超高速レーザーの世界市場規模は、2028年には37億米ドルに達し、予測期間中にCAGR15.3%の市場成長率で上昇すると予測されています。
パルスの強度を上げるために、パルスストレッチャー、アンプ、コンプレッサーで構成されるチャープパルス増幅が一般的に使用されています。増幅の際、パルスの持続時間や位相は変化しないです。最初に非線形材料でパルスをチャープし、スペクトルを広げることで、パルス圧縮(パルス長を短くすること)が可能になります。
そして、そのチャープを補正するためにコンプレッサーを使用します。このとき、一般的にはファイバーコンプレッサが利用されます。レーザ光をフーリエ変換する光変調器をパルスシェイパーと呼びます。変調器は、光のどの面を制御するかによって、強度変調器、位相変調器、偏光変調器、空間光変調器などとも呼ばれます。
光変調器は、変調方式により、音響光学変調器、液晶変調器、電気光学変調器などに分類されます。それぞれ用途が異なります。電子をイオン化して衝突させ、非線形プロセスである高次高調波発生(HHG)により、強いレーザーエネルギーをある単一周波数からその周波数の高次高調波へと変換します。
COVID-19影響度分析
数々のルールの導入により、消費者の需要も減少し、超高速レーザー市場の潜在的な収益だけでなく、そのサプライチェーンも混乱させています。超高速レーザー市場動向の普及を促進するために、政府と主要な市場関係者が協力し、研究開発に投資しています。さらに、企業は市場シェアを高め、現在の予測期間を通して超高速レーザー市場の期待される成長に貢献する合併や買収に関心を示しています。
市場成長要因
より正確な寸法測定
小型で信頼性の高い電子デバイスのニーズは、家電、コンピュータ、ネットワーキングとテレコム、輸送、ヘルスケア、民生用電子機器の技術的進歩によって生まれました。このような携帯電子機器では、ディスプレイなどの部品に大きな寸法精度が要求されます。高性能な半導体部品を作るために必要な加工材料の需要が高まることが予想されます。また、航空宇宙や一部の家電製品など、高速で完全に集積化されたアプリケーションでは、装置の小型化に対する要求が飛躍的に高まっています。
技術革新と様々な産業分野での超高速レーザーの利用
COVID-19の大流行で多くの産業が影響を受けていることは間違いありませんが、平常に戻れば経済は回復すると予想されます。例えば、自動車業界では電気自動車(EV)への移行が進み、超高速レーザーシステムの需要が高まると予想されます。家電業界も医療業界も同じような動向です。超高速レーザは、その多くの利点から多くの分野で採用されています。
市場抑制要因
複雑な製造プロセス
超高速レーザーの市場は、寸法精度の向上に対するニーズとそれをサポートする政府の政策によって拡大していますが、製造上の課題など他の問題が市場の成長を制限すると予想されます。これらのシステムを産業環境で取り扱うには、その技術的な複雑さ、ビーム伝播中の非線形効果、相互作用のプロセスにより、技術的な熟練が必要です。そのため、この技術が提供する多くの利点にもかかわらず、一般に、繊細で高価、かつ時間がかかるという批判があり、生産工程への導入が困難です。
タイプ別の展望
超高速レーザー市場は、タイプによってチタンサファイアレーザー、ファイバーレーザー、モードロックレーザー、その他に分けられます。ファイバーレーザーセグメントは、2021年に超高速レーザー市場で最も高い収益シェアを獲得しました。それは、溶接、切断、付加製造などの様々な産業製造作業にとって、ファイバーレーザは多用途で強力な機器であるからです。超高速ファイバーレーザ技術を使用している多数のヘルスケアシステムのために、医療用レーザシステム市場は拡大しています。
パルス幅の展望
パルス持続時間に基づいて、超高速レーザ市場はピコ秒とフェムト秒に区分されます。フェムト秒セグメントは、2021年に超高速レーザー市場で最大の収益シェアを調達しました。それは、これらのレーザーがポータブルエレクトロニクスの分野でより頻繁に使用されているためです。携帯電話、マイクロプロセッサ、メモリチップ、ディスプレイパネルなどは、極めて複雑なコンポーネントの一例です。
アプリケーションの展望
超高速レーザ市場は、アプリケーション別に、マイクロマシニング、バイオイメージング、科学研究、医療機器製造、心臓血管ステント製造、その他に分類されます。バイオイメージングセグメントは、2021年に超高速レーザ市場で大きな収益シェアを登録しました。バイオイメージングは、生物学的プロセスの非侵襲的なリアルタイム可視化を可能にする技術を指します。バイオイメージングの目標は、生物学的プロセスにできるだけ干渉しないようにすることです。また、物理的な妨害なしに、観察された試料の3D構造を知るために頻繁に使用されます。
エンドユーザーの展望
超高速レーザー市場は、エンドユーザーに基づき、家電、医療、自動車、航空宇宙・防衛、産業、その他に二分化されます。民生用電子機器セグメントは、2021年の超高速レーザー市場においてかなりの収益シェアを登録しました。エレクトロニクスの製造は、まだ非常に活発な分野です。民生用電子機器の需要増と急速に進化する技術的ブレークスルーが、定期的に新製品を市場に出すようOEMに圧力をかけており、これがこの産業の主な推進要因となっています。
地域別展望
地域別では、超高速レーザー市場は、北米、欧州、アジア太平洋、LAMEAで分析されています。アジア太平洋地域は、2021年に超高速レーザー市場で有望な収益シェアを調達しました。それは、エレクトロニクスや自動車産業がフェムト秒ファイバーレーザのニーズを高めているからです。この地域、特に中国や日本などの国では、技術的な改善と多数のエレクトロニクスOEMが存在するため、この地域は予測期間中に大きく成長すると予測されています。
List of Figures
The Global Ultrafast Lasers Market size is expected to reach $3.7 billion by 2028, rising at a market growth of 15.3% CAGR during the forecast period.
spectroscopic method called ultrafast laser spectroscopy uses ultrashort pulse lasers to analyze dynamics on very short time scales (attoseconds to nanoseconds). The behavior of charge carriers, atoms, and molecules is studied using various techniques. There are several aspects of the laser pulse that must be understood to perform reliable spectroscopic measurements, including pulse duration, pulse energy, spectral phase, and spectral shape.
Through measurements of autocorrelation or cross-correlation with another pulse that has been thoroughly characterized, information regarding pulse duration can be obtained. Frequency-resolved optical gating (FROG) and spectrum phase interferometry for direct electric-field reconstruction are two techniques that allow for a thorough analysis of pulses (SPIDER). The goal of pulse shaping is to precisely alter the pulses coming from the source, including their amplitude, phase, and length.
To increase the intensity of a pulse, chirped pulse amplification which consists of a pulse stretcher, amplifier, and compressor is typically used. During the amplification, it won't alter the pulse's duration or phase. By initially chirping the pulse in a nonlinear material and broadening the spectrum, pulse compression (shortening the pulse length) is made possible.
A compressor is then used to compensate for the chirp. In this situation, a fiber compressor is typically utilized. Optical modulators that subject a laser beam to Fourier transformations are referred to as pulse shapers. Modulators are also known as intensity modulators, phase modulators, polarization modulators, and spatial light modulators depending on which aspect of light is regulated.
Optical modulators are classified as Acoustic-optic modulators, Liquid crystal modulators, Electro-optic modulators, etc. depending on the modulation method. Each is devoted to a separate set of uses. By ionizing and collisional an electron, high harmonic generation (HHG), a nonlinear process, transforms intense laser energy from one single frequency to high harmonics of that frequency.
COVID-19 Impact Analysis
The introduction of numerous rules has also caused consumers to reduce their demand, which is disrupting the market for ultrafast lasers' potential revenue as well as its supply chain. To promote the widespread use of ultrafast laser market trends, the government and the major market players are working together and investing in research and development. Additionally, businesses are expressing an interest in mergers and acquisitions that will boost their market share and contribute to the ultrafast laser market's expected growth throughout the current forecast period.
Market Growth Factors
More Accurate Measurement Of Dimensions
The need for a small, dependable electronic device was created by technological advancements in consumer electronics, computers, networking and telecom, transportation, healthcare, and consumer electronics. Such portable electronic devices demand great dimensional accuracy for components like displays. It is projected that there would be a rise in demand for the fabrication materials required to make high-performance semiconductor components. In high-speed, completely integrated applications like aerospace and some consumer electronics, the demand for compact equipment has expanded dramatically.
Innovation In Technology And Use Of Ultrafast Lasers In Various Industry Applications
Numerous industries are undoubtedly impacted by the COVID-19 pandemic, but if things return to normal, it is anticipated that the economy will recoup. For instance, there will be a considerable change in the automotive industry toward electric vehicles (EVs), which will lead to a demand for ultrafast laser systems. Both the consumer electronics industry and the medical industry are seeing a similar trend. Many sectors are adopting ultrafast lasers due to their many benefits.
Market Restraining Factors
Complicated Manufacturing Processes
The market for ultrafast lasers is growing because of the need for increased dimensional accuracy and government policies that support them, but other issues, such as manufacturing challenges, are anticipated to limit the market growth. Handling these systems in an industrial setting needs technical proficiency due to their technological complexity, nonlinear effects during beam propagation, and interaction process. Therefore, despite the numerous benefits this technology claims to offer, it is commonly criticized for being delicate, expensive, and slow, which makes it difficult to implement into production processes.
Type Outlook
Based on the Type, the Ultrafast Lasers Market is divided into Titanium-Sapphire Lasers, Fiber Lasers, Mode-Locked Lasers, and Others. The fiber lasers segment acquired the highest revenue share in the ultrafast lasers market in 2021. It is because, for a variety of industrial manufacturing operations, such as welding, cutting, and additive manufacturing, fiber lasers are versatile and potent instruments. Due to the numerous healthcare systems that are using ultrafast fiber laser technology, the market for medical laser systems is expanding.
Pulse Duration Outlook
On the basis of Pulse Duration, the Ultrafast Lasers Market is segmented into Picosecond and Femtosecond. The femtosecond segment procured the largest revenue share in the ultrafast lasers market in 2021. It is because these lasers are being used more frequently in the field of portable electronics. Mobile phones, microprocessors, memory chips, and display panels are some examples of extremely complicated components.
Application Outlook
By Application, the Ultrafast Lasers Market is classified into Micromachining, Bio-Imaging, Scientific Research, Medical Device Fabrication, Cardiovascular Stent Manufacturing, and Others. The bio-imaging segment registered a significant revenue share in the ultrafast lasers market in 2021. Bioimaging refers to techniques that allow non-invasive real-time visualization of biological processes. The goal of bioimaging is to interfere with biological processes as little as possible. Additionally, it is frequently used to learn about the 3-D structure of the viewed specimen without physical disturbance.
End-User Outlook
Based on the End-User, the Ultrafast Laser Market is bifurcated into Consumer Electronics, Medical, Automotive, Aerospace & Defense, Industrial, and Others. The consumer electronics segment registered a substantial revenue share in the ultrafast lasers market in 2021. The manufacturing of electronics is still a very active sector. Rising consumer electronics demand and quickly evolving technical breakthroughs, which put pressure on OEMs to regularly produce new products on the market, are the main drivers of this industry.
Regional Outlook
Region-wise, the Ultrafast Lasers Market is analyzed across North America, Europe, Asia Pacific, and LAMEA. The Asia Pacific region procured a promising revenue share in the ultrafast lasers market in 2021. It is because the electronics and automobile industries have a greater need for femtosecond fiber lasers. Due to technical improvements and the presence of numerous electronics OEMs in the region, particularly in nations like China and Japan, this region is predicted to have significant growth during the projection period.
The market research report covers the analysis of key stake holders of the market. Key companies profiled in the report include Lumentum Holdings, Inc., NKT Photonics A/S (NKT A/S), TRUMPF GmbH + Co. KG, Coherent, Inc.(II-VI Incorporated), IMRA America, Inc. (Aisin Corporation), Amplitude Systemes, Clark-MXR, Inc., DPSS Lasers Inc., and Wuhan Huaray Precision Laser Co., Ltd.
Strategies Deployed in Ultrafast Lasers Market
Aug-2022: Lumentum took over NeoPhotonics Corporation, a leading manufacturer and developer of lasers and optoelectronic solutions. With this acquisition, Lumentum position itself for engaging growth possibilities produced by the digital transformation of life and work, which is effective relentless growth in the required volumes and performance of network and cloud infrastructure.
May-2022: Amplitude Laser came into a partnership with New Technology S.K., a foremost supplier of Lasers, Electro-Optics, and Optical Components. With this partnership, Newtech would be circulating nanosecond products developed by Amplitude in the US.
Apr-2022: Amplitude completed the acquisition of MW Technologies, a developer of optical fiber lasers in Portugal. This acquisition would allow Amplitude to advance its production ability and deliver an adequate response to international consumers. Additionally, MW Technologies' name switches to Amplitude Portugal, evolving the organization's 4th manufacturing area and R&D center across the world.
Apr-2022: Lumentum Holdings launched FemtoBladeTM, a new femtosecond laser system. The new FemtoBlade laser utilizes a modular structure that provides improved flexibility and high power at high recurrence rates which would allow faster processing and enhanced throughput for micromachining applications, such as engraving, OLED, ceramic, and glass cutting, PCB, and solar cell processing.
Feb-2022: Trumpf completed the acquisition of Active Fiber Systems, the fiber laser business located in Jena. This acquisition, would expand and achieve Trumpf's living fiber laser portfolio, which is mostly focused on industrial applications such as precision welding and additive manufacturing.
Jan-2020: NKT Photonics introduced the SuperK FIANIUM range of pulsed supercontinuum lasers. The new SuperK FIANIUM is produced on the World's best-selling supercontinuum laser and has elevated electronics and new fiber technology delivering improved performance and dependability.
Jun-2019: Amplitude launched Tangor 300, its brand-new high-performance laser. The new Tangor 300 is qualified for delivering energy of up to 1000µJ per pulse and a recurrence rate of up to 40MHz. Additionally, the new ultrafast laser would allow customers to multiplicate machining techniques through the perfect productivity and quality combination.
Apr-2018: NKT Photonics joined hands with RISE Acreo, Sweden's research institute, and innovation partner. Through this collaboration, the companies focused on the expansion of silica glass for fiber lasers for more than a decade. Additionally, silica glass is a crucial element in high-performance optical fibers and fiber lasers.
Market Segments covered in the Report:
By Pulse Duration
By End User
By Type
By Application
By Geography
Companies Profiled
Unique Offerings from KBV Research