直击2026上海光博会，解锁后摩尔时代创新密码

Core Viewpoint - The integration of semiconductor and optoelectronic technologies is becoming a central theme in industry development, driven by the post-Moore era and the explosive demand for AI computing power, emphasizing the importance of collaboration across the entire industry chain [1][3]. Group 1: Forum Insights - The "Industry Collaboration and Communication Upgrade" forum gathered top experts and industry leaders to discuss core topics across the semiconductor and optoelectronic fields, sharing cutting-edge technological achievements and insights into industry development opportunities [3]. - The forum highlighted the need for collaborative innovation across materials, devices, packaging, testing, and system applications to inject new ideas and directions for high-quality industry development [3]. Group 2: Two-Dimensional Semiconductors - Two-dimensional semiconductors are identified as a key technology in the post-Moore era, offering significant advantages over silicon-based semiconductors, including reduced difficulty and cost in advanced processes [6][7]. - Major companies like TSMC, Intel, and Samsung are actively investing in two-dimensional semiconductor technology, which is expected to be integrated into heterogeneous systems after the 1nm node, with potential low-power applications by 2029 [6][7]. - Original Microelectronics has launched China's first engineering demonstration line for two-dimensional semiconductors, with plans for small-batch production of 90nm CMOS processes by September this year [7]. Group 3: Silicon Photonics - Silicon photonics technology is poised for explosive growth, driven by the demand for high-speed AI interconnects, with the market for 1.6T products expected to reach $4.5 billion by 2028 [10]. - The establishment of an 8-inch low-loss silicon nitride production platform has enabled the mass production of silicon photonic chips, addressing key challenges in traditional silicon photonics [10][11]. Group 4: Capacitor Innovations - Silicon capacitors are emerging as a solution to energy integrity challenges in AI applications, with a projected market size of $11.7 billion by 2027 [14]. - Their superior temperature stability and long lifespan make them ideal for high-density power delivery networks in AI chips and optical modules [14]. Group 5: Optical Interconnects - Optical interconnects are seen as a solution to the bandwidth, power, and topology challenges faced by traditional electrical interconnects, with the optical interconnect market expected to exceed $23 billion by 2025 [21]. - Companies are developing integrated optical solutions to enhance bandwidth and reduce power consumption, with significant advancements in optical computing technologies [21][22]. Group 6: Advanced Packaging - The "EDA+" paradigm is proposed to address the limitations of traditional EDA tools in advanced packaging, enabling collaborative design across multiple chiplets and layers [24][25]. - This new approach supports various packaging forms and integrates multiple physical field analyses, enhancing the efficiency of heterogeneous integration in chip design [24][25]. Group 7: Photonic Chips for AI and Quantum Computing - Photonic chips are positioned as a core hardware support for AI and quantum computing, with significant advantages in bandwidth and energy efficiency [36][37]. - The development of a fully controllable technology system based on lithium niobate thin films aims to facilitate the mass production of photonic chips for various applications [36][37]. Group 8: Testing Innovations - The transition from hardware to software-defined testing solutions is reshaping the testing and measurement industry, with platforms like Moku enabling customizable instrument solutions [28][29]. - High-speed oscilloscopes are being developed to meet the rigorous testing demands of optical communication technologies, ensuring reliable performance in high-speed applications [40][41]. Conclusion - The forum underscored the importance of collaborative innovation across the semiconductor and optoelectronic industries, addressing the core demands of computing power and communication upgrades in the post-Moore era, while outlining a clear blueprint for future industry development [42].