已发表论文50余篇,包括Nature Photonics、Science Advances、Nature Communications、Advanced Materials、Matter、ACS Energy Letters、Advanced Functional Materials、Research、ACS Applied Materials & Interfaces等多篇高水平论文,其中3篇入选高被引论文。申请中国发明专利20项,授权11项。相关研究成果“钙钛矿X射线探测器”入选“2017年度中国光学十大进展(应用研究类)”。博士学位论文“铯银铋溴X射线探测器性能研究和成像初探”入选2022年度中国光学学会郭光灿光学优秀博士学位论文。作为主要成员,获得2023年中国核学会自然科学二等奖。先后主持国自然基金、博士后面上一等资助和博士后特别资助等项目,作为核心成员参与国自然重点、科技部重点研发计划等项目。

  研究工作被国内与国际同行广泛认可,代表论文Cs2AgBiBr6 single-crystal X-ray detectors with a low detection limit. Nature Photonics, 2017, 11, 726。ESI高被引论文。Science Bulletin专栏评述本工作为X射线探测器领域“game changer”。该工作获得2017年度中国光学十大进展(应用研究类)。后续工作Heteroepitaxial passivation of Cs2AgBiBr6 wafers with suppressed ionic migration for X-ray imaging发表在Nature Communications,再次成为ESI高被引论文。

  研发新型铜基闪烁体探测器,实现高空间分辨动态X射线成像,相关成果发表在Science子刊One-dimensional scintillator film with benign grain boundaries for high-resolution and fast X-ray imaging. (感兴趣者可观看B站Dr陈可乐老师的视频https://www.bilibili.com/video/BV1zN411n7mK/)。相关研究内容获得国自然青年基金、中国博士后面上项目一等资助(资助比例仅2%)。研究成果在B站、新华网等多媒体上获专题解读和报道,成果获得第二届全国博士后创新创业大赛金奖。相关原理、材料和方法通过中国核学会鉴定为“国际领先水平”,获得核学会自然科学二等奖。

  在前期研究的基础上,自主设计并搭建了一套X射线高分辨成像系统,相关设备已交付中船重工719研究所,实现了某新能源刀片电池的质量检测。连续两次获得全国创新创业优秀博士后称号(2021年、2023年)。

  [1]W. Pan#, H. Wu#, J. Luo#, Z. Deng#, G. Niu*, Q. Xie*, J. Tang*, et al. Cs2AgBiBr6 single-crystal X-ray detectors with a low detection limit. Nature Photonics, 2017, 11, 726. (IF=35.0,Highly Cited Papers)

  [2]H. Wu#, Qian Wang#, Ao Zhang#, G. Niu*, Yuntao Wu*, J. Tang*, et al. One-dimensional scintillator film with benign grain boundaries for high-resolution and fast X-ray imaging. Science Advances, 2023, 9, eadh1789. (IF=13.6)

  [3]H. Wu#, Xu Chen#, Guangda Niu*, et al. Mechanochemical synthesis of high-entropy perovskite toward highly sensitive and stable X-ray flat panel detector. Advanced Materials, 2023, 35, 2301406. (IF=29.4)

  [4]H. Wu, Y. Ge, G. Niu*, J. Tang*. Metal halide perovskites for X-ray detection and imaging. Matter, 2021, 4, 144. (IF=18.9, Highly Cited Papers)

  [5]J. Pang#, H. Wu#, G. Niu*, et al. Reconfigurable perovskite X-ray detector for intelligent imaging. Nature Communications, 2024, 15, 1769. (IF=16.6)

  [6]Z. Liu#, H. Wu*, G. Niu*, et al. Robust perovskite X-ray flat panel detector by anisotropic conductive adhesive to regulate thermal stress. ACS Energy Letters, 2024, 9, 1397. (IF=22.0)

  [7]G. Zheng, H. Wu*, L. Xu*, J. Tang*, et al. Direct X-ray detection made of zero-dimensional hybrid metal halide perovskite single crystal. Journal of Materials Chemistry C, 2024, 12, 6288. (IF=6.4)

  [8]H. Wu, G. Niu, J. Tang. Roadmap on printable electronic materials for next-generation sensors: Printable lead-halide-perovskite radiation detectors. Nano Futures, 2024, DOI: 10.1088/2399-1984/ad36ff.

  [9]B. Yang#, W. Pan#, H. Wu#, G. Niu*, J. Tang*, et al. Heteroepitaxial passivation of Cs2AgBiBr6 wafers with suppressed ionic migration for X-ray imaging. Nature Communications, 2019, 10, 1989. (IF=16.6, Highly Cited Papers)

  [10]X. Zhao#, P. Fu#, H. Wu*, Z. Xiao*, J. Luo*, et al. Solution-processed hybrid europium (II) iodide scintillator for sensitive X-ray detection. Research, 2023, 6, 0125. (IF=11.0)

  [11]H. Wang#, H. Wu#, G. Niu*, W. Li*, J. Fan*, et al. Controllable CsxFA1-xPbI3 single crystal morphology via rationally regulating the diffusion and collision of micelle towards high performance photon detectors. ACS Applied Materials & Interfaces, 2019, 11, 13812. (IF=9.5)

  [12]F. Ye#, H. Lin#, H. Wu#, W. C. H. Choy*, et al. High-quality cuboid CH3NH3PbI3 single crystals for high performance x-ray and photon detectors. Advanced Functional Materials, 2018, 29, 1806984. (IF=19.0)

  [13]J. Li#, C. Wang#, H. Wu#, L. Chen*, Y. Zhang*, et al. Eco-friendly and highly efficient light-emission ferroelectric scintillators by precise molecular design. Advanced Functional Materials, 2021, 31, 2102848. (IF=19.0)

  [14]Fu D*, Hou Z, He Y, H. Wu*, S. Wu, Y. Zhang*, G. Niu, X. Zhang*. Formamidinium perovskitizers and aromatic spacers synergistically building bilayer Dion–Jacobson perovskite photoelectric bulk crystals. ACS Applied Materials & Interfaces, 2022, 14, 11690. (IF=9.5)

  国家自然科学基金委员会,面上项目,2025/01-2028/12,48万元,在研,主持

  [2] 国家自然科学基金委员会,青年基金,2023/01-2024/12,20万元,在研,主持

  [3] 中国博士后科学基金特别资助(站中),2023/01-2024/03,18万元,结题,主持

  [4] 中国博士后科学基金面上项目,一等资助,2022/06-2024/03,12万元,结题,主持

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  [2]唐江,巫皓迪,牛广达,潘伟程,罗家俊,尹力骁; 一种双钙钛矿晶体的后处理方法及应用,ZL201710375865.X.

  [3]唐江,潘伟程,巫皓迪,罗家俊,牛广达,周英;基于Bi基四元卤化物单晶的半导体辐射探测器及制备方法,ZL201611071705.8.

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  [5]唐江,罗家俊,潘伟程,巫皓迪,蔡粉莎;一种钙钛矿单晶的制备方法,ZL201611066423.9.

  [6]唐江,陈正午,牛广达,巫皓迪;一种一体化卤素钙钛矿核电池及制备方法,ZL201710367795.3.

  [7]唐江,牛广达,潘伟程,杨波,巫皓迪,尹力骁;一种提高辐射探测性能的方法、对应的辐射探测器及制备,ZL201810163874.7.

  [8]唐江,牛广达,巫皓迪,杜鑫源;一种钙钛矿超快X射线探测器及其制备方法,ZL202011283052.6.

  [9]唐江,牛广达,宋子豪,夏梦玲,巫皓迪;一种MAPbI3厚膜的表面处理方法,ZL202011329619.9.