Yang Meiling
School
School of Earth System Science
Professional Title
Associate professor
Contact Information
meilingyang@tju.edu.cn
Rm 613, Building No.16
300072
Education Background
- Doctoral degree| Nankai University| Genetics| 2017
Research Interests
- 1 The element coupled biogeochemistry;
2 The regulation mechanism of phytoplankton element coupling ;
Positions & Employments
-
2023.6-Now
地球系统科学学院 | 天津大学 | 副教授 -
2018.1-2023.6
School of Earth System Science | Tianjin University | Lecturer
Academic Achievements
- Papers
- [1] Stepwise degradation of organic matters driven by microbial interactions in China΄s coastal wetlands: Evidence from carbon isotope analysis
- [2] Regulation of particulate inorganic carbon by phytoplankton in hydropower reservoirs: Evidence from stable carbon isotope analysis
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- [3] Geographical constraints on chemodiversity of sediment dissolved organic matter in China's coastal wetlands
- [4] River damming enhances ecological functional stability of planktonic microorganisms
- [5] Archaeal contribution to carbon-functional composition and abundance in China’s coastal wetlands: Not to be underestimated
- [6] Regulation strategy for nutrient-dependent carbon and nitrogen stoichiometric homeostasis in freshwater phytoplankton
- [7] Co-occurrence of planktonic bacteria and archaea affects their biogeographic patterns in China’s coastal wetlands
- [8] Interaction between carbon cycling and phytoplankton community succession in hydropower reservoirs: Evidence from stable carbon isotope analysis
- [9] Control of Hydraulic Load on Bacterioplankton Diversity in Cascade Hydropower Reservoirs, Southwest China
- [10] Ecological Distribution, Reproductive Characteristics, and In Situ Conservation of Malus sieversii in Xinjiang, China
- [11] Identification of MsHsp20 Gene Family in Malus sieversii and Functional Characterization of MsHsp16.9 in Heat Tolerance
- [12] Malus niedzwetzkyana (Dieck) Langenf transcriptome comparison and phylogenetic analysis with Malus sieversii (Ledeb) Roem
- [13] Universal stress protein in Malus sieversii confers enhanced drought tolerance