李洛阳(副教授)

发布者:时振波发布时间:2023-12-01浏览次数:7079

一、基本信息

姓名:李洛阳

性别:男

出生年月:19909

祖籍:山东省滨州市

联系地址:山东省青岛市崂山区松岭路238号,邮编266100

办公地点:澳门永利集团304官网手机A412-2

E-mail: liluoyang@ouc.edu.cn

 

二、简历

1. 学习经历

西北大学,地质学(基地班),理学学士学位,中国西安,2010.09-2014.06

西北大学,生命科学,辅修学士,中国西安,2012.09-2013.12

西北大学,古生物学与地层学,理学博士学位(直博),中国西安,2014.09-2019.06

瑞典自然历史博物馆,古生物学与地层学,联合培养博士,合作导师:Christian Skovsted,瑞典,2017.12-2018.12

 

2. 工作经历

2019.10-2021.10,瑞典自然历史博物馆,古生物系,博士后

2021.11-至今,澳门永利集团304官网手机,澳门永利集团304官网手机,副教授

 

3. 获奖情况

2019,西北大学优秀博士论文,

2021,澳门永利集团304官网手机,青年英才工程(第三层次)

 

4. 重要科研项目

(1).国家自然科学基金青年基金,42202001,华北寒武纪软体动物贝壳化石超微结构及其早期演化研究,主持;

(2). 国家自然科学基金重点项目,41930319,寒武纪清江生物群研究,参与;

(3). 国家自然科学基金面上项目,41772011,华南寒武纪布尔吉斯页岩型生物群中节肢动物的形态分异,发育模式及谱系演化关系,参与;

(4). 国家自然科学基金重大项目,41890845,寒武纪大爆发时期动物门类多样性及其演化关系研究,参与;

 

三、主要学术领域

1.学科方向:地球生物学,演化生物学,生物矿化

2.研究兴趣:

1)地球-生命系统协同演化关系;

2)寒武纪生命大爆发:前寒武纪/寒武纪过渡时期早期生命演化;

3)深时生物矿化作用:早期动物生物控制矿化骨骼起源与演化;

4)冠轮动物起源与谱系演化:软体动物及疑难化石类群;

5)特异埋藏化石库:清江生物群生物多样性及化石埋藏学;

6)环节动物分类学与系统演化

3. 尖端技术应用:

为开展多学科交叉研究,常用仪器包括:扫描电子显微镜SEM-EDX(形貌与成分分析)、电子探针EPMA(矿物分析)、Micro-CT(结构与形貌分析)、共聚焦拉曼光谱Raman Spectrometer(矿物组成分析)、激光扫描共聚焦显微镜CLSM(荧光分析),等等。

四、已发表论文

目前已发表SCI文章20余篇,包括Science (Nature index)Geology (Nature index)Proceedings of the Royal Society B Biological Science (Nature index)iScienceCell旗下)、PalaeontologyPapers in Palaeontology Journal of Systematic PalaeontologyPalaeo-3Scientific Reports Nature旗下)等国际古生物学、生物学、地质学,以及综合期刊上。

 

[1]. Li, L., Topper, T.P., Betts, M.J., Altanshagai, G., Enkhbaatar, B., Li, G., Li, S., Skovsted, C.B., Cui, L. and Zhang, X., 2024. Tubule system of earliest shells as a defense against increasing microbial attacks. iScience.

[1]. Li, L.*, Betts, M.J., Yun, H., Pan, B., Topper, T.P., Li, G., Zhang, X. and Skovsted, C.B., 2023. Fibrous or Prismatic? A Comparison of the Lamello-Fibrillar Nacre in Early Cambrian and Modern Lophotrochozoans. Biology12(1), p.113.

[2]. Li, L.*, Topper, T.P., Betts, M.J. Dorjnamjaa, D., Altanshagai, G., Enhkbaatar, B., Li, G. and Skovsted, C.B., 2022. Calcitic shells in the aragonite sea of earliest Cambrian. Geology, 51(1), pp.8-12.

[3]. Li, L.*, Skovsted, C.B. and Topper, T.P., 2022. Deep origin of the crossed‐lamellar microstructure in early Cambrian molluscs. Palaeontology, 65(4), p.e12620.

[4]. Li, L.*, Christian, C.B., Dai, T., Yun, H. Fu, D. and Zhang, X., 2021. Qingjianglepas from the Qingjiang biota, an evolutionary dead-end of Cambrian helcionelloid mollusks?. Palaeogeography, Palaeoclimatology, Palaeoecology, 575, p.110480.

[5]. Li, L., Zhang, X.*, Skovsted, C.B., Yun, H., Pan, B. and Li, G., 2020. Revisiting the molluscan fauna from the Cambrian (Series 2, stages 3–4) Xinji Formation of North China. Papers in Palaeontology, 7(1), pp.521-564.

[6]. Li, L.*, Skovsted, C.B., Yun, H., Betts, M.J. and Zhang, X., 2020. New insight into the soft anatomy and shell microstructures of early Cambrian orthothecids (Hyolitha). Proceedings of the Royal Society B, Vol., No, 287: 20201467, 08.

[7]. Li, L., Zhang, X.*, Skovsted, C.B.*, Yun, H., Pan, B. and Li, G., 2019. Homologous shell microstructures in Cambrian hyoliths and molluscs. Palaeontology, Vol., No, 62, pp. 515–532.

[8]. Li, L., Zhang, X.*, Skovsted, C.B., Yun, H., Li, G. and Pan, B., 2019. Shell microstructures of the helcionelloid mollusc Anabarella australis from the lower Cambrian (Series 2) Xinji Formation of North China. Journal of Systematic Palaeontology, Vol., No, 17, pp. 1699–1709.

[9]. Li, L., Yun, H. and Zhang, X. Guide Book for Field Trip 1 of ICECS 2018: Precambrian-Cambrian transition in the southern margin of North China.

[10]. Li, L., Zhang, X.*, Yun, H. and Li, G., 2017. Complex hierarchical microstructures of Cambrian mollusk Pelagiella: insight into early biomineralization and evolution. Scientific reports, Vol., No, 7, 1935.

[11]. Li, L., Zhang, X.*, Yun, H. and Li, G., 2016. New occurrence of Cambroclavus absonus from the lowermost Cambrian of North China and its stratigraphical importance. Alcheringa, Vol., No, 40, pp. 45–52.

[12].Goñi, I., Skovsted, C.B., Li, L., Li, G., Betts, M.J., Dorjnamjaa, D., Altanshagai, G., Enkhbaatar, B. and Topper, T.P., 2023. New palaeoscolecid plates from the Cambrian Stage 3 of northern Mongolia. Acta Palaeontologica Polonica, 68, in press.

[13]. Yun, H., Luo, C., Chang, C., Li, L., Reitner, J. and Zhang, X., 2022. Adaptive specialization of a unique sponge body from the Cambrian Qingjiang biota. Proceedings of the Royal Society B, 289(1977), p.20220804.

[14]. Qiu, H., Feng, L., Chu, X., Li, L., Zhang, X. and Li, J., 2022. Genesis of silica-phosphatic nodules with Small Shelly Fossils preserved in the lowermost Cambrian of South China. Acta Geologica Sinica-English Edition, 96(4), pp.1294-1307.

[15]. Topper, T., Betts, M.J., Dorjnamjaa, D., Li, G., Li, L., Altanshagai, G., Enkhbaatar, B. and Skovsted, C.B., 2022. Locating the BACE of the Cambrian: Bayan Gol in southwestern Mongolia and global correlation of the Ediacaran–Cambrian boundary. Earth-Science Reviews, 229, p.104017.

[16]. Yun, H.*, Zhang, X., Glenn, B.A., Li, L. and Li, G., 2021. Biomineralization of the Cambrian chancelloriids. Geology. Vol., No, 49, pp. 623638.

[17]. Wang, X., Zhang, X., Zhang, Y., Cui, L. and Li, L. 2021. New materials reveal Shaanxilithes as a Cloudina-like organism of the late Ediacaran. Precambrian Research, 362, p.106277.

[18]. Pan, B., Skovsted, C.B., Brock, G.A. Topper, T.P., Holmer, L.E., Li, L. and Li, G.*, 2020. Early Cambrian organophosphatic brachiopods from the Xinji Formation, Shuiyu section, North China. Palaeoworld, Vol., No, 29, pp. 512–533, 09.

[19]. Skovsted, C.B.*, Martí Mus, M., Zhang, Z.., Pan, B., Li, L., Liu, F., Li, G. and Zhang, Z., 2020. On the origin of hyolith helens. Palaeogeography, Palaeoclimatology, Palaeoecology, Vol., No, 555, 10.

[20]. Yun, H., Brock, G.A., Zhang, X.*, Li, L., García-Bellido, D.C. and Paterson, J.R., 2019. A new chancelloriid from the Emu Bay Shale (Cambrian Stage 4) of South Australia. Journal of Systematic Palaeontology, Vol., No, 17, pp. 857–867.

[21]. Yun, H., Zhang, X.*, Li, L., Pan, B., Li, G. and Brock, G.A., Chancelloriid sclerites from the lowermost Cambrian of North China and discussion of sclerite taxonomy. Geobios, Vol., No, 53, pp. 65–75.

[22]. Fu, D., Tong, G., Dai, T., Liu, W., Yang, Y., Zhang, Y., Cui, L., Li, L., Yun, H., Wu, Y., Sun, A., Liu, C., Pei, W., Lin, W., Ma, J., Gains, R.R. and Zhang, X.*, 2019. The Qingjiang biota – An extraordinary new Burgess Shale-type fossil Lagerstätte from the early Cambrian, South China. Science, Vol., No, 363, pp.1338–1342.

[23]. Yun, H., Zhang, X. *andLi, L., 2017. Chancelloriid Allonniaerjiensis sp. nov. from the Chengjiang Lagerstätte of South China. Journal of Systematic Palaeontology, Vol., No, 16, pp. 435–444.

[24]. Yun, H., Zhang, X.*, Li, L., Zhang, M. and Liu, W., 2016. Skeletal fossils and microfacies analysis of the lowermost Cambrian in the southwestern margin of the North China Platform. Journal of Asian Earth Sciences, Vol., No, 129, pp. 54–66.

研究生培养:热烈欢迎拥有生物学、古生物学、材料学、地质学背景的本硕博同学加入课题组。