Kang Yang

Kang Yang MSc

PhD Candidate
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Visiting Address

Droevendaalsesteeg 10
6708 PB Wageningen

+31 (0) 317 47 34 00

The Netherlands

About

The main focus of my PhD project is to determine the interactions between the plant biostimulant and beneficial microbes linked to N cycles to provide nutrients to plants, increase soil quality and fertility and mitigate greenhouse gas nitrous oxide (N2O).

Biography

I got my Bachelor and Master Degree from China University of Geosciences in Wuhan, with a specialized focus on geomicrobiology and N biogeochemistry cycling.


Currently, I am pursuing my PhD Degree in Eiko's Group in Utrecht University, the Netherlands, and I am conducting my research in the Microbial Ecology department at the Netherlands Institute of Ecology (NIOO-KNAW). My research focuses on mitigating greenhouse gas emissions, with a particular interest in addressing the challenge of reducing N2O emissions meanwhile keeping the agricultural sustainable through plant biostimulants addition.


My commitment to taking insight to nitrogen cycling in various ecosystems through molecular biological and geochemistrical technologies continues to drive my academic and research goals.

CV

Education

  • 2015–2019
    Bachelor, China University of Geosciences (Wuhan)
  • 2019–2022
    Msc, China University of Geosciences (Wuhan)
  • 2022–Present
    PhD, Utrecht University & NIOO-KNAW

Publications

Key publications

Science of The Total Environment
2024

Differential response of subterranean microbiome to exogenous organic matter input in a cave ecosystem

Xiaoyu Cheng, Rui Zhao, Paul L.E. Bodelier, Yuyang Song, Kang Yang, Olli H. Tuovinen, Hongmei Wang
As a recurrent climatic phenomenon in the context of climate change, extreme rainstorms induce vertical translocation of organic matter and increase moisture content in terrestrial ecosystems. However, it remains unclear whether heavy rainstorms can impact microbial communities in the deep biosphere by modulating organic matter input. In this study, we present findings on the different responses of bacterial and fungal communities in a subsurface cave to rainstorms and moisture variations through field surveys and microcosm experiments. During periods of rainstorms, the influx of dissolved organic matter (DOM) from soil overlying the cave into cave sediments significantly enhanced the correlation between core bacteria and environmental factors, particularly fluorescence spectral indices. The resource utilization of core bacteria was diminished, while the functional diversity of core fungi remained relatively unaltered. We also performed simulated experiments with restricted external DOM inputs, in which DOM content was observed to decrease and microbial diversity increase in response to artificially increased moisture content (MC). The niche breadth of core bacteria decreased and became more closely associated with DOM as the MC increased, while the niche breadth of core fungi remained predominantly unchanged. Compared to fungi, cave bacteria exhibited higher sensitivity towards variations in DOM. The core microbiome can efficiently utilize the available organic matter and participate in nitrogen- and sulfur-related metabolic processes. The study systematically revealed distinct microbial responses to rainstorm events, thereby providing valuable insights for future investigations into energy utilization within deep biospheres.

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