市場調査レポート
商品コード
1562508
シリコンフォトニクスの市場規模、シェア、成長分析、コンポーネント別、導波路別、用途別、製品別、地域別 - 産業予測、2024年~2031年Silicon Photonics Market Size, Share, Growth Analysis, By Component, By Waveguide, By Application, By Product, By Region - Industry Forecast 2024-2031 |
シリコンフォトニクスの市場規模、シェア、成長分析、コンポーネント別、導波路別、用途別、製品別、地域別 - 産業予測、2024年~2031年 |
出版日: 2024年09月11日
発行: SkyQuest
ページ情報: 英文 157 Pages
納期: 3~5営業日
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シリコンフォトニクスの世界市場規模は、2022年に12億米ドルと評価され、2023年の15億米ドルから2031年には113億米ドルに成長し、予測期間中(2024年~2031年)のCAGRは28.30%で成長する見通しです。
世界のシリコンフォトニクス市場は、堅調なCAGRに牽引され、2024年から2031年にかけて大幅な成長が見込まれます。通信技術における半導体デバイスやマイクロチップの使用増加が、この期間の市場拡大を後押しすると予測されています。シリコンフォトニクス技術は、光信号を使用してマイクロチップ間でデータを転送する能力で支持を集めており、従来の電気伝導体と比較して優れた速度と効率を提供しています。欧州連合(EU)の第3回フォトニクス報告書によると、世界のフォトニクス部門は、約6,000億米ドルから大幅に増加し、9,900億米ドルを超えると予測されています。市場の成長は、クラウドコンピューティング・データセンターにおける性能要求の高まり、インターネットトラフィックの急増、機械設備における広帯域化の必要性によってさらに支えられています。さらに、バイオ医療技術、自律走行車、データ転送、通信、人工知能などの分野でのシリコンフォトニクスの用途拡大が、2031年までの市場進展をさらに推進すると予想されます。
Global Silicon Photonics Market size was valued at USD 1.20 billion in 2022 and is poised to grow from USD 1.50 billion in 2023 to USD 11.30 billion by 2031, growing at a CAGR of 28.30% during the forecast period (2024-2031).
The global silicon photonics market is expected to experience substantial growth between 2024 and 2031, driven by a robust compound annual growth rate (CAGR). The increasing use of semiconductor devices and microchips in communication technologies is anticipated to boost market expansion during this period. Silicon photonics technology is gaining traction for its ability to transfer data between microchips using optical signals, which offers superior speed and efficiency compared to traditional electrical conductors. According to the European Union's third Photonics report, the global photonics sector was projected to exceed USD 990 billion, a significant increase from approximately USD 600 billion. The market growth is further supported by rising performance demands in cloud computing data centers, the rapid increase in internet traffic, and the need for higher bandwidth in machinery and equipment. Additionally, the expanding applications of silicon photonics in fields such as biomedical technology, autonomous vehicles, data transfer, telecommunications, and artificial intelligence are expected to drive further market development through 2031.
Top-down and bottom-up approaches were used to estimate and validate the size of the Global Silicon Photonics market and to estimate the size of various other dependent submarkets. The research methodology used to estimate the market size includes the following details: The key players in the market were identified through secondary research, and their market shares in the respective regions were determined through primary and secondary research. This entire procedure includes the study of the annual and financial reports of the top market players and extensive interviews for key insights from industry leaders such as CEOs, VPs, directors, and marketing executives. All percentage shares split, and breakdowns were determined using secondary sources and verified through Primary sources. All possible parameters that affect the markets covered in this research study have been accounted for, viewed in extensive detail, verified through primary research, and analyzed to get the final quantitative and qualitative data.
Global Silicon Photonics Market Segmental Analysis
Global Silicon Photonics Market is segmented by Component, Waveguide, Application, Product, and region. Based on Component, the market is segmented into Lasers, Modulators, and Photodetectors. Based on Waveguide, the market is segmented into 400-1,500 NM, 1,310-1,550 NM, and 900-7,000 NM. Based on Application, the market is segmented into Data Centers and High-performance Computing, Telecommunications, Military, Defense, and Aerospace, Medical and Life Sciences, Other Applications. Based on Product, the market is segmented into Transceivers, Variable Optical Attenuators, Switches, Cables, Sensors. Based on region, the market is segmented into North America, Europe, Asia Pacific, Latin America and Middle East & and Africa.
Drivers of the Global Silicon Photonics Market
Accommodating the growing demand for high-speed data transfer with traditional copper lines presents significant challenges. Optical interconnects using silicon photonic transceivers effectively address the limitations of spectral range. Additionally, silicon photonics components such as transceivers, interconnects, and switches are designed to consume less power. Companies like Cisco and Intel have introduced optical switches that operate with minimal power consumption-around 0.6 mW-and achieve switching speeds of 6 nanoseconds. While traditional solutions often depend on board-to-board and computer-to-computer integrations, silicon photonics leverage on-chip integration. This approach not only reduces the size of the products but also decreases power consumption. Consequently, the increasing demand for high-power data transfer semiconductors is anticipated to drive market growth in the sector.
Restraints in the Global Silicon Photonics Market
Lasers are essential for high-performance optical data transfer due to their ability to produce pure light with precise frequency and color. In silicon photonics, light sources can be either on-chip or off-chip. On-chip light sources offer higher integration density and a smaller footprint compared to off-chip sources, and they are more energy-efficient and proportional in their energy consumption. However, integrating laser sources directly onto a silicon chip presents significant challenges. This process increases complexity and is hindered by the variations in light sources, making the integration of on-chip lasers a difficult task. These complexities contribute to the challenges in advancing the silicon photonics market.
Market Trends of the Global Silicon Photonics Market
A significant trend in the silicon photonics market is the adoption of hybrid silicon lasers, which combine silicon with group III-V semiconductors. This approach addresses mass production challenges associated with silicon lasers by leveraging the light-emitting properties of III-V semiconductor materials alongside the established manufacturing processes of silicon. The hybrid method enables the creation of electrically driven lasers that can be integrated into silicon wafers, facilitating their use in various silicon photonic devices. This integration capitalizes on the advanced capabilities of III-V materials while benefiting from the robust process maturity of silicon technology.