Core Viewpoint - The article emphasizes the urgent need for the manganese industry to overcome resource bottlenecks, accelerate technological innovation, and build a green circular industrial system in response to profound changes in the energy sector and intense competition in the materials industry [1][11]. Group 1: Industry Insights - The National Manganese Industry High-Quality Development Conference was held on August 28, focusing on the future direction of the manganese industry [1]. - Longyang County is recognized as a significant manganese resource area in China, highlighting its importance in the national manganese industry landscape [3]. - The future development of manganese mining in China will focus on breakthroughs in low-grade ore utilization and exploration in potential areas such as Xiangdong, Chuanxi, and Hebei over the next 10-15 years [3]. Group 2: Technological Developments - Manganese-based cathode materials are identified as a crucial direction for future battery development, necessitating collaboration between industry, academia, and research to expand their application in power and energy storage batteries [3]. - The advantages of manganese-based materials include safety, low-temperature performance, and high cost-effectiveness, making them a new trend in the power battery industry [4]. - The global first manganese-based semi-solid-state battery was launched by SAIC on August 5, 2025, showcasing the potential of manganese-based batteries in various applications [4]. Group 3: Environmental Solutions - The treatment of manganese slag, a solid waste from electrolytic manganese production, poses a significant challenge for sustainable development in the manganese industry [7]. - A comprehensive solution for harmless treatment of manganese slag includes multiple processes such as multi-stage countercurrent washing and chemical stabilization techniques [7]. Group 4: Collaborative Discussions - A roundtable discussion featured industry leaders discussing breakthroughs in technological bottlenecks and market trends, fostering a consensus on development strategies [9]. - The conference served as a high-level platform for industry professionals to exchange ideas, igniting enthusiasm for technological innovation and resource optimization [11]. Group 5: Future Outlook - The successful conclusion of the conference marks a new development stage for the manganese-based new energy industry, with leading companies like Anhui Boshik High-Tech setting benchmarks for enhancing battery performance and expanding application fields [11]. - As technologies mature and commercialization accelerates, manganese-based batteries are expected to play a significant role in the green energy revolution, particularly in new energy vehicles and energy storage systems [11].

Core Viewpoint - The conference held in Hegang, Heilongjiang, focused on transforming China's advantageous mineral resources, particularly graphite, into strategic emerging industries through high-quality development and collaboration among various stakeholders [1][5][8]. Group 1: Industry Development - The "China Graphite City" was officially named in Luobei County, which is home to the world's largest single crystalline graphite mine, the Yunshan Graphite Mine [3]. - The conference emphasized the importance of resource endowment and the transformation of resource advantages into industrial strengths, highlighting the role of leading companies like China Minmetals in this process [5]. - Hegang has established a comprehensive "1+N" graphite new materials industry development system, focusing on natural graphite resources and extending into various applications such as new energy materials and graphene [7]. Group 2: Technological Innovation - A joint technology research and demonstration center was established, marking a new phase of deep integration between production, education, and research in the graphite industry [5][7]. - The focus is on overcoming "bottleneck" technologies and achieving full-chain domestic production from raw materials to end products, with several high-end graphite products already launched [5][7]. Group 3: Environmental and Economic Goals - Hegang aims to create a national-level zero-carbon park, promoting the synergy between industrial development and ecological protection [8]. - The city is positioning itself to adapt to international green trade rules while enhancing its energy structure and supporting regional coordinated development [8].

活动中，市区两级相关部门、产业园区负责人及企业代表等，与长三角地区电子信息、智能科技、射频 微波等产业领域的企业家，围绕各自的产业优势与机遇、布局与需求进行分享。当前，成都正着力推动 特色优势产业提能级、战略性新兴产业上规模，郫都区作为成都电子信息、绿色氢能、绿色食品的重要 承载地，主导产业蓬勃发展，在2025年赛迪中国百强区排名位列第82位。 活动现场，郫都区用"政策大礼包"与"产业路线图"双向发力：一方面系统解读在产业链布局、专项政策 扶持、生产要素保障等方面的差异化优势，另一方面通过华为、京东方等龙头企业落地发展案例，具象 化展现"芯片—屏幕—终端—软件"电子信息全产业链生态的构建成果，让在场企业家直观感受到这片土 地的产业潜力。 在场企业家围绕自身投资布局与技术合作需求，与郫都区招商团队展开"一对一"深度洽谈。从项目落地 的配套服务，到产业链上下游的协同可能性，再到高校科研资源的转化路径，企业的疑问和需求现场得 到回复，不少企业当场表达了进一步考察合作的意向，"通过交流后感觉到成都郫都区的发展超出预 期，尤其在电子信息产业领域的集群优势，有信心进行投资布局，依托当地头部企业的产业牵引力和高 校科研资源 ...

Core Viewpoint - Quantum technology is not an abstract concept; it heavily relies on advanced scientific instruments for development, as emphasized by Professor Yu Dapeng, a leading figure in China's quantum technology field [4][6]. Group 1: Current State of Quantum Technology - China's quantum technology is experiencing differentiated development across three main areas: quantum communication, quantum computing, and quantum precision measurement [7]. - In quantum communication, China has transitioned from a follower to a leader, exemplified by the "Mozi" quantum satellite [7]. - The quantum computing sector has seen China achieve a "catching up" status, with significant advancements in superconducting and photonic quantum computing [7]. - However, in quantum precision measurement, China still lags behind the U.S. due to high precision requirements for scientific instruments [7][8]. Group 2: Challenges in Scientific Instrumentation - The development of quantum technology is constrained by the lack of advanced scientific instruments, which are crucial for breakthroughs [8]. - Key challenges in the autonomous development of scientific instruments include a weak industrial foundation, market environment issues, external technology blockades, and user perception problems [9]. - The reliance on imported high-end equipment poses risks, including high costs and supply chain vulnerabilities [8][9]. Group 3: Solutions for Innovation - Professor Yu proposes a "three-in-one" innovation system to address these challenges, focusing on talent cultivation, policy support, and optimizing the innovation ecosystem [9]. - The need for a talent cultivation system that produces professionals skilled in both quantum physics and engineering is emphasized [9]. - Establishing special funds for high-end instrument development and improving government procurement policies for domestic products are recommended [9]. Group 4: Innovations at Shenzhen International Quantum Research Institute - The Shenzhen International Quantum Research Institute has made significant strides in quantum technology, achieving national laboratory standards within five years [12]. - The institute focuses on solid-state quantum computing and has successfully developed domestic scientific instruments, including dilution refrigerators [12][13]. - Future plans include tackling high-end equipment such as transmission electron microscope aberration correctors and multi-beam lithography machines, which are vital for quantum research and semiconductor industries [13][14]. Group 5: Future Outlook and Talent Development - Quantum technology is viewed as a critical area for national competition, with confidence in achieving breakthroughs supported by government initiatives [14]. - The relationship between scientific instruments and quantum technology is highlighted as mutually beneficial, where advancements in one area drive progress in the other [14]. - Innovative approaches to talent development are suggested, including reforming evaluation systems and fostering interdisciplinary education [14].

Core Viewpoint - The new export control policy in 2024 marks a new stage of technological protection for the industry, shifting the policy focus from scale expansion to the construction of an innovation ecosystem through collaboration between industry, academia, and research [1]. Policy Evolution and Development Planning - The development of superhard materials in China can be divided into four stages: initiation, growth, accelerated development, and transformation breakthrough. The initiation phase began with the inclusion of superhard materials in the national strategic emerging industries during the "12th Five-Year Plan" in 2012. The growth phase was marked by the clear distinction of superhard materials in "Made in China 2025," which emphasized the need to overcome high-performance diamond and cubic boron nitride (CBN) preparation technologies. The accelerated development phase saw the emergence of "bottleneck" risk awareness from 2018 to 2020, leading to multiple regulations and guidelines that clarified the project's status and encouraged development. Since the "14th Five-Year Plan" in 2021, the industry has entered a transformation breakthrough phase, aiming to overcome high-end production technology challenges with the help of the existing upstream supply chain [2][3]. Differentiated Development Pattern Led by Henan - Henan Province has prioritized the development of the superhard materials industry, implementing policies such as "Six New Breakthroughs in Manufacturing" and "High-end Materials Cluster Construction Action Plan." The province focuses on high-end products like gem-grade and functional diamonds, supporting enterprises in increasing technological innovation and R&D investment. Comprehensive measures, including the establishment of national and provincial innovation platforms, collaboration among leading enterprises, and financial subsidies, are enhancing the overall industry chain cooperation level. Henan aims to transition from "quantity leading" to "quality leading" and "high-end application breakthroughs," solidifying its core position in the superhard materials industry both nationally and globally [5]. Industry Development Goals and Strategies - By 2025, the goal is to form a trillion-level industry chain and establish the world's largest superhard materials R&D and production base, cultivating a national-level industry cluster and striving for an internationally leading industry chain. The industry is expected to upgrade from traditional manufacturing to high-end, intelligent, and green production, promoting vertical extension (from raw materials to end products) and horizontal expansion (cross-industry integration with 5G, chips, medical, and biological fields) [6]. Innovation-Driven Strategy Upgrade - In recent years, Henan has emphasized technological innovation and high-end breakthroughs in the superhard materials industry, focusing on composite superhard materials, high-end diamond products, and polycrystalline diamond composites. The province is increasing policy and financial support, promoting technological breakthroughs and the transformation of results. Additionally, Henan is facilitating deep integration of superhard materials with high-value industries such as chip manufacturing, 5G communication, and biomedical fields, enhancing the innovation ecosystem and strengthening intellectual property protection and standard system construction [7]. Funding-Driven Market Ecosystem Integration - In response to rapid global technological advancements and the trend of high-quality industrial development, Henan's superhard materials industry policy will further deepen towards intelligent manufacturing, digital transformation, and green low-carbon directions. Future focus areas include intelligent equipment and automation production, cross-industry applications of superhard materials in new energy, semiconductors, and healthcare, as well as the promotion of green low-carbon processes. The policy is expected to strongly promote international cooperation and standardization, supporting leading enterprises in participating in international rule-making and integrating into the "Belt and Road" industrial network [9]. Policy Support Trends - The policy content is shifting from broad industry scale support to precise technological breakthroughs and support for high-end segments of the industry chain, emphasizing the construction of an industrial ecosystem. The government-led industry support is gradually integrating market mechanisms, encouraging social capital participation in the construction of the innovation ecosystem. Future policies will highlight the deep integration of intelligent manufacturing, digital transformation, and low-carbon green manufacturing with the superhard materials industry, promoting cross-industry innovation with cutting-edge technologies [10].

Core Insights - The prevalence of malocclusion in China is reported at 74%, leading to a growing demand for orthodontic treatments as public health awareness increases [1] - Zhengya Dental Technology (Shanghai) Co., Ltd. has made significant advancements in invisible orthodontics, breaking foreign technological monopolies through independent research and development [1][7] - The collaboration between Zhengya and Professor Shen Gang's team has established a comprehensive innovation system that transitions China from following to leading in the field of invisible orthodontics [1][4] Group 1: Technological Innovations - Shen Gang's innovative classification system for malocclusion focuses on facial shape, addressing the unique characteristics of Chinese patients, which has evolved from merely adopting foreign solutions to localized innovations [2][3] - The GS jaw position reconstruction technology integrates advanced digital technologies and algorithms, enhancing treatment efficiency and patient comfort by optimizing overall facial shape rather than just aligning teeth [3][4] - As of August 2025, the GS technology has received 64 domestic and 59 international patents, creating a technological "moat" for Zhengya [3] Group 2: Production and Market Expansion - Zhengya's automated manufacturing base in Jiaxing, covering 100,000 square meters, is set to produce over 20 million invisible aligners annually, supporting local production for the European market with a facility in Madrid [6] - The company has successfully entered 57 countries and regions with its brand Smartee, establishing subsidiaries in key markets, thus shifting from product output to standard-setting in the global orthodontic landscape [7] - Zhengya has accumulated 729 domestic and international patents by August 2025, showcasing its strength in technological innovation and ongoing research and development capabilities [7]

Core Insights - The company, Xulun Technology, has developed a new material, UV release film, which is crucial for semiconductor packaging, breaking foreign monopolies in technology [1][2] - The company has established a comprehensive product innovation system covering all aspects from basic resin research to mass production, achieving a precision control of adhesive layer thickness to within 1 micron [2] - The domestic packaging market accounts for over 60% of the global market, and the company aims to meet domestic demand while expanding its market potential [3][4] Company Overview - Xulun Technology, originally founded in 1997, relocated to Zhenjiang Economic Development Zone in 2022, establishing a 10,000 square meter semiconductor tape factory [1] - The company has a production capacity of 10 million square meters of UV film annually, positioning itself as a leading manufacturer in the domestic wafer grinding and cutting tape sector [1] Market Context - The semiconductor packaging materials sector has been dominated by Japanese companies, with imported products holding a market share of 70%, indicating significant room for domestic players [2] - The company's innovative materials are also expected to find applications in consumer electronics, enhancing production efficiency compared to traditional methods [2]

Core Points - The conference held on August 5 announced the list of outstanding enterprise technology commissioners for 2024 and the re-deployment of 1,034 new technology commissioners [1] - In the past year, 1,003 technology commissioners served 955 enterprises across 22 key industrial clusters, addressing 1,546 innovation needs related to technology breakthroughs, process optimization, talent training, and technology finance [1] - The technology commissioners established 186 technology innovation platforms and over 40 talent bases, helping to recruit 2,542 urgently needed talents for enterprises [1] - They assisted in securing 140 million yuan in technology loans, alleviating the financial pressure on enterprises for innovation [1] - A total of 91 enterprises completed technology achievement transformations, with a conversion amount of 12 million yuan, accelerating the transformation of innovative results into productive forces [1] Government and Policy Support - The government is urged to continue providing platforms, strengthen collaborative mechanisms, improve the precision selection system, and optimize the service guarantee environment to foster innovation [1] - The emphasis is on creating a fertile ground for innovation and ensuring the stability and sustainability of special actions [1] Role of Technology Commissioners - Technology commissioners are encouraged to continue their efforts as "problem solvers," "seed planters," "talent cultivators," and "think tanks," contributing to the collaborative advancement of industry, academia, and research [1]

Group 1: Digital Infrastructure Financing - The central bank and seven departments issued guidelines to support the integration of the digital economy with the real economy, emphasizing the use of technologies like big data, blockchain, and AI to streamline processes and enhance service efficiency for manufacturing, especially SMEs [1] - The guidelines propose strengthening long-term loan support for digital infrastructure projects such as 5G, industrial internet, and data centers, while also promoting diverse financing methods like leasing and asset securitization to address the substantial funding needs [1] - The policy is expected to stimulate demand for upstream hardware like servers and optical modules, while also facilitating the implementation of industrial internet platforms and AI applications [1] Group 2: Commercial Aerospace Development - The successful launch of the low Earth orbit satellite by the Long March 12 rocket from the Hainan commercial space launch site demonstrates the site's high-density launch capability, achieving consecutive launches within five days [2] - This milestone is anticipated to accelerate the satellite internet constellation deployment, with potential market interest in rocket reuse technology, ground support systems, and the satellite manufacturing supply chain [2] - The increased launch efficiency positions China to gain an advantage in near-Earth orbital resources amid intensifying global competition in low Earth orbit satellites [2] Group 3: AI in Healthcare - The National Development and Reform Commission approved the establishment of a national AI application pilot base in clinical medicine, led by Zhongshan Hospital affiliated with Fudan University, focusing on addressing industry pain points and creating an innovative support platform [3] - The pilot base aims to bridge the gap between research outcomes and clinical applications, potentially shortening the product deployment cycle for AI technologies in healthcare [3] - This initiative may enable top-tier hospitals to evolve from technology users to standard setters, with the effectiveness of the platform hinging on establishing a regulatory sandbox that balances medical ethics and technological experimentation [3]

当前，深化产学研协同，优化完善科技创新人才培养机制，是实现人才链、产业链、创新链对接，促进 高水平科技自立自强的关键一招。《2024年中国专利调查报告》显示，我国企业发明专利中的41.0%与 高校或科研单位合作完成，其中战略性新兴产业和未来产业产学研合作比例突破60%，显著高于总体水 平。如何深刻把握教育对科技和人才的支撑作用，持续形成人才辈出、人尽其才、才尽其用的生动局 面，成为题中应有之义。 近年来，我国产学研融合成效显著，在联合培养、技术攻关、成果转化等方面取得突破进展。例如， 2019年北京大学与华为共同成立"大一华为数学联合实验室"，在数学及相关基础研究领域内联合创新， 为企业的原始创新驱动提供了有力支撑；2020年复旦大学联合广州市人民政府建立粤港澳大湾区精准医 学研究院，推动精准医学前沿尖端研究和重大成果应用转化；2023年北京航空航天大学与中国商飞共建 大飞机研究院，打造大飞机前沿探索领域的高端人才培养基地。不过，目前仍然面临人才流动不畅、主 体职责不清、培养定位模糊等难题，因此要从打破人才流动限制、创新人才培养模式等方面施策。 打破地域、身份、年龄限制，处理好高校教师、科研院所研究员、企业技 ...