2023年4月10日，研究生院与学指委联合召开联培基地学生管理工作协调交流会，会议采取线上线下同步进行。学生处副处长、校团委书记李劲湘、国家卓越工程师学院副院长张小丽、学指委思政室主任梁茂宗，以及研究生院专业学位办、宁波研究院、四川研究院、三亚研究院、相关招生院系思政教师等参加了会议。

根据全国工程专业学位研究生教育指导委员会网站信息，我校杜朝辉教授任第五届工程专业学位研究生教育指导委员会委员，归琳教授任工程专业学位研究生教育指导委员会华东区域协作组委员，熊振华教授为工程专业学位研究生教育指导委员会工程博士专项工作组专家，孔令体教授为工程专业学位研究生教育指导委员会课程建设专项工作组专家，杜朝辉教授兼任工程专业学位研究生教育指导委员会质量标准专项工作组专家。

2021年12月，教育部网站发布了关于全国金融等30个专业学位研究生教育指导委员会换届的通知，公布了全国30个专业学位研究生教育指导委员会新一届委员名单。我校11名教授被聘为新一届专业学位研究生教育指导委员会委员。

为进一步提高我校工程类专业学位研究生培养质量，完善研究生教育治理体系，上海交通大学决定成立工程专业学位研究生教育指导委员会，组成人员如下：

2015年，国务院学位委员会、教育部发布了《专业学位类别（领域）博士、硕士学位基本要求》。学术学位《一级学科博士、硕士学位基本要求》已于2013年发布。

为深入贯彻党的十九大关于实现高等教育内涵式发展的要求，落实全国研究生教育会议精神，加强研究生课程建设，提高研究生培养质量，国务院学位委员会办公室组织公开出版《学术学位研究生核心课程指南（试行）》和《专业学位研究生核心课程指南（试行）》（以下均简称《指南》）

许多酶现已被证实是高效的电催化剂。本次讲座将介绍一个强大的生物催化新平台，它将多种酶构成的“级联反应”体系 (用于实现高效串联催化) 纳米限域在多孔电极材料中。其核心组分（E1）是铁氧还蛋白-NADP⁺还原酶（FNR）——一种普遍存在的光合酶，在绿色植物中负责再生可交换的携氢辅因子NADPH，从而启动有机化学转化（因此得名“电化学叶（e-Leaf）”）。e-Leaf技术使我们能够研究酶在纳米限域条件下的协同作用。这种被称为“级联电子学”的研究成果，对于理解活细胞的运行机制具有重要意义。由于e-Leaf能利用种类繁多的酶，该平台也为酶制剂开发、即插即用型生物传感，以及复杂化合物 (包括药物) 的合成开辟了新的道路。

压力是物质科学研究的崭新维度。高压极端条件下的物质科学——压缩科学，正孕育着巨大的原始创新，拥有广阔的应用前景。报告将阐述压缩科学在前沿基础学科领域和国家安全领域的价值，以及实现其价值的能力需求，厘清压缩科学体系化发展态势，总结国际上压缩科学发展经验。报告也将分析中国前期探索实践情况和存在的差距，提出后续发展的思考。

通过今年的两个具体例子——分别针对晶态合金与非晶态合金，展示材料科学通过结构设计实现前所未有性能的强大能力。第一个例子探讨如何实现‌2GPa的屈服强度‌与‌30%均匀拉伸率‌的结合、填补强度-塑性的空白。合金的“鱼和熊掌兼得”，还可以表现为易加工（室温大塑性）却能在超高温承载（>2000℃时仍有200 MPa强度）。第二个例子则用来说明，“结构决定性能”这一原理同样适用于非晶态固体。通过设计单一类型的稳定基元，抑制非晶Cr-Te合金中的结构弛豫，从而解决了多值识别中稳定性与可靠性的问题，为非易失存算提供了无漂移的材料方案。

When an intense laser interacts with a gas of atoms, high-order harmonics are generated. In the time domain, this radiation forms a train of extremely short light pulses, of the order of 100 attoseconds. Attosecond pulses allow the study of the dynamics of electrons in atoms and molecules, using pump-probe techniques. This presentation will highlight some of the key steps of the field of attosecond science.

Phosphines are key ligands to create the catalytic activity of molecular metal complexes for numerous catalytic reactions useful in industry. Fast modifications of phosphines via catalyticC-H bond activation/functionalisation can easily lead to more active catalysts. Interrupted hydrogenation of N-heteroarenes or nitroarenes allow fast reactions of reduction intermediates, depending on catalyst nature, leading to innovations in syntheses.The lecture will present innovations processes recently discovered on these two topics. 1.Phosphines and improved Phosphine-Metal catalyst activity Ruthenium(II) catalysts promote sp²C-H bond activation and functionalisations ofarylphosphine oxides. Whereas Rhodium(I) catalysts allow the regioselective difunctionalisation of phosphine biaryl group C-H bonds leading to increased activity of Metal-Phosphine catalysts. 1.Reactions of interrupted hydrogenation intermediates and innovations in synthesis homogeneous Ruthenium(II) catalysts in methanol and formaldehyde can be driven for partial hydrogenation of N-Heteroarenes for diastereoselective annulation of azaarenes, whereas heterogeneous Iridium based catalyst allows partial hydrogenation of N-heterocycles leading to γ-AminoAcids in the presence of 1,2-Dicarbonyls, By contrast Homogeneous Manganesecatalyst in the presence of Lewis Acid can offer the fast access to 2-Azabicyclo[2.1.1]hexanes. Simply made supported Cobalt catalysts allow selective first step hydrogenation, with HCO₂H,of abundant Nitroarenes, leading to 1,3-diaryl imidazolines, the NHC precursors. By contrast single atom Cobalt catalyst allows the formation, from Nitroarenes and HCO₂H, ofhydroxylamines which can be trapped by alhehyde and alkyne to offer γ-Lactams synthesis. Supported Cobalt catalyst also allows the formation of hydroxylamine which can be trappedwith formaldehyde and acrylates to produce functional aminoacids.

Most current climate models suggest that limiting warming to <2°C will require large scale deployment of carbon dioxide removal (CDR) technologies. CDR may be natural or technological, with one of the most scalable technological approaches being the direct capture of CO2 from the air, or “direct air capture” (DAC) coupled with geologic storage. Because of the ultra-dilute nature of air, the separation of CO2 from this mixture presents a significant engineering challenge. Today, DAC technologies are very expensive ($500-1000/tCO2). In this lecture, I will describe the unique challenges associated with designing molecules, materials, devices and ultimately processes for DAC. Specifically, I will describe the design and synthesis, characterization and application of porous oxide-supported amine materials that we have developed as cornerstones of new technologies for the removal of CO2 from air. These materials are incorporated into customized air/solid contactors designed specifically as key components of DAC technologies. DAC offers an interesting case study for the parallel and integrated design of materials, unit operations, and processes in chemistry and chemical engineering.

Functional MRI has been used for over 35 years to detect neural activity in the cortex by exploiting the blood oxygenation-level dependent (BOLD) effect, and has become an essential tool for mapping brain function. In addition, correlations between BOLD signals from different regions in a resting state are interpreted as depicting functional connectivity and reveal neural circuits. However, BOLD signals have rarely been reported from white matter (WM), which constitutes over half the brain and encompasses the communication networks between cortical areas and between the brain and the spine. Despite this oversight, it is clear BOLD signals are robustly detectable in WM if appropriate analyses are used, WM BOLD responses can be evoked by stimulation in task-specific tracts or regions, and at rest, signals within WM tracts show reproducible patterns of correlations with gray matter (GM). Moreover, these WM-GM relations are altered in various pathologies including Alzheimer’s disease in a manner that correlates with behavioral measures. BOLD signals may also be detected and analyzed in WM tracts in the spinal cord. By integrating multimodal data from various sources the relationships of BOLD signals in WM to glial cell density, vascular properties, tissue microstructure and degree of myelination have been established, which suggest the biophysical basis of BOLD in WM is similar but different from GM in important ways. This presentation will summarize some of our recent studies that provide evidence that BOLD signals in WM are related to brain functional activity and deserve greater attention by the neuroimaging community.

我将介绍近年来我们在应用数学落地方面的一些体会和成果，包括我们与华为合作在5G极化码研究方向的进展，以及我们用AI解偏微分方程的一些研究。我也简单谈谈我对科研新范式和人工智能的理解。