近年来，山东省日照市深入实施工业倍增"头号工程"，充分依托临港涉海优势，通过优化产业结 构，激活民资动能，强化服务保障，不断激发企业投资意愿，构建了持续高效、动能澎湃的"工业引 擎"。今年1月至11月，其规上工业增加值增长8%，工业投资增长28.8%，增速均居山东省前列。 持续优化产业结构 在日照市岚山区的雷英精工科技有限公司智能化车间里，机械臂精准抓取钢材，经过拉丝、冷镦、 热处理等20余道精密工序，最终变身为一批批高性能紧固件。"这些看似普通的螺丝、螺母，其实是用 于重型机械和新能源汽车等装备制造的高性能紧固件。"该公司总经理张明付说。 在岚山区，传统钢铁正被重新定义。"我们通过引进精深加工项目，推动钢铁产品向家电板材、汽 车零部件、轮船制造、航空航天用品等领域延伸，本地消化率持续提升，实现附加值倍数增长。"日照 市岚山区钢铁服务中心副主任傅志强说。 依托港口优势，日照市把发展重心聚焦大宗原材料加工，造纸、钢铁等传统产业成为工业发展的坚 实支柱。近年来，当地持续加大设备更新和技术改造力度，聚焦钢铁、化工等传统产业，逐个制定改造 提升方案，系统推进传统产业向高端化、智能化、绿色化转型。今年5月，当地发布《2 ...

依托港口优势，日照市把发展重心聚焦大宗原材料加工，造纸、钢铁等传统产业成为工业发展的坚实支 柱。近年来，当地持续加大设备更新和技术改造力度，聚焦钢铁、化工等传统产业，逐个制定改造提升 方案，系统推进传统产业向高端化、智能化、绿色化转型。今年5月，当地发布《2025年加力扩围实施 大规模设备更新和消费品以旧换新工作方案》，明确年内滚动实施400个以上投资500万元以上的工业技 改项目。 在创新驱动发展战略引领下，日照市钢铁产品结构持续优化：日钢集团1.0毫米ESP花纹板填补国内空 白，高磁感取向硅钢实现省内首创；山钢日照公司油罐钢、高强钢产品市场占有率居全国首位，并实现 LNG储罐用9镍钢规模化量产；昱岚新材料有限公司突破0.1毫米"手撕钢"量产技术，标志着企业在高端 钢材领域取得重大突破。 通过前瞻性的产业规划和布局，日照市还积极培育战略性新兴产业，使增长建立在更优的产业结构之 上。结构的调整，既让投资吸引力持续增强，也为未来工业经济提供源源不断的新增长点。前三季度， 日照市新增投资项目546个，同比增加36个，计划总投资高达664.1亿元。 今年1月至11月，日照市制造业多个重点领域呈现出强劲增长态势。其中 ...

农田里的秸秆可以做成新能源汽车电池的核心零部件，不能吃的玉米芯可以产出高性能纺织品，棉 花可以合成液晶显示器偏光片的重要原料.... 中美都在加速布局的非粮生物基材料产业，其实源于20世纪70年代末的一场石油危机。 当时，世界第二大石油出口国伊朗因政局动荡，连续60天停止对外输出石油，导致全球油价从每桶 13美元暴涨至34美元。一夜之间，美国诸多工厂因缺油停产，制造业哀嚎一片。 这场危机也让全球各国意识到过度依赖石油能源的致命缺陷，纷纷开始寻找化石资源的替代品。 所谓化石资源，广泛地应用于老百姓的日常生活。无论是开车用的汽油，还是做饭用的天然气，乃 至穿的化纤衣服、购物用的塑料袋，它们的原材料都是几亿年间形成的化石。 这些科幻小说般的"炼金"场景，今天你在工信部发布的文件中就能见到。 12月8日，工信部发布《非粮生物基材料产业创新发展典型案例入围名单》（后简称《名单》），全 国12个省市35个项目入选。山东、安徽两省位居前二，共上榜15项。 湖北也有1项技术入围——由武汉睿嘉康生物科技有限公司掌握的非粮生物基材料高产稳产工业菌株 制备技术，它可以让秸秆、玉米芯变成乙醇，成为汽车燃料。 尽管非粮生物基材料，听起 ...

Core Viewpoint - The company is focusing on the research and development of fine chemical additives, bio-based biodegradable materials, and new energy battery materials over the next three years [2] Group 1 - The company has signed a technical promotion cooperation agreement with Dalian Jiangda Industrial Catalysis Co., Ltd. for the promotion of new production processes and catalyst technologies for carbonate solvents used in electrolytes [2] - The company will disclose any significant progress in this collaboration in a timely manner [2]

Group 1 - The article emphasizes the dual drivers of carbon neutrality and the Fourth Industrial Revolution as catalysts for a materials revolution [7][72] - Global policies are accelerating the low-carbon and high-end transformation of the new materials industry, exemplified by the EU's Carbon Border Adjustment Mechanism and China's 14th Five-Year Plan for new materials [9][10][72] - Technological convergence across disciplines is leading to unprecedented breakthroughs in new materials development, such as AI and quantum computing applications [11][14][15] Group 2 - Six core tracks of new materials are identified: solid-state battery materials, superconducting materials, bio-based biodegradable materials, wide bandgap semiconductor materials, smart responsive materials, and metamaterials [18][24][28][31][35][39] - Solid-state batteries are highlighted as a key technology for electric vehicles, with significant advancements in electrolyte materials expected by 2025 [18][19][20] - Superconducting materials are crucial for energy networks and quantum computing, with notable advancements in high-temperature superconducting wires [24][26] Group 3 - The strategic focus for 2025 includes materials nearing commercialization, such as solid electrolytes and perovskite solar materials, which are expected to drive industry growth [42][45] - Technologies that may lead to industry chain restructuring include molecular self-assembly materials and hydrogen embrittlement-resistant alloys [46][48] - Geopolitically sensitive materials like extreme ultraviolet photoresists and high-purity quartz sand are becoming focal points for national security and economic stability [49][50][52] Group 4 - Companies are advised to build ecosystems, exemplified by CATL's closed-loop system for materials, cells, and recycling, enhancing competitiveness and sustainability [55][59] - Dow Chemical's use of digital twin technology in materials development significantly improves R&D efficiency and market responsiveness [60][62] - The China Graphene Alliance's role in international standard-setting enhances China's global competitiveness in the graphene sector [64][66] Group 5 - The conclusion posits that the materials revolution will reshape human civilization, driving cleaner energy, smarter transportation, and advanced medical solutions [69][75] - The article underscores the importance of new materials in achieving sustainability and technological advancement, suggesting a bright future for the industry [72][75]

Core Viewpoint - The petrochemical industry in China is undergoing a low-carbon transition, focusing on the coupling of renewable energy with petrochemical production systems to achieve technological transformation towards oil conversion, high-end products, and green processes [1][2]. Group 1: Industry Transformation - The petrochemical sector is encouraged to accelerate the development of green low-carbon and new energy businesses as part of its transformation strategy [1]. - The industry faces significant energy and resource consumption, as well as high carbon emissions, necessitating a push towards green low-carbon transformation for high-quality development [1][2]. - The emphasis is on developing green competitiveness by utilizing green hydrogen and coupling various chemical industries with renewable energy sources [1][2]. Group 2: Technological Pathways - Key technological directions include converting crude oil into chemicals, producing high-value-added chemicals, and developing green processes [2]. - Specific pathways involve utilizing by-products from refining for chemical production, recycling waste plastics, and employing advanced low-carbon technologies [2]. - The industry is urged to focus on energy-saving and carbon-reduction modifications in key areas, enhancing efficiency benchmarks, and promoting the construction of environmentally friendly facilities [2]. Group 3: Case Studies and Recognition - The conference highlighted exemplary cases in the petrochemical industry for pollution reduction and carbon emission control, recommending eight units as benchmark cases [3]. - Notable examples include the Shanghai Chemical Industry Park and Sinopec's Jiujiang branch, recognized for their outstanding practices in the sector [3].