Jiamin Qi's research while affiliated with Xi'an Jiaotong University and other places

What is this page?

This page lists the scientific contributions of an author, who either does not have a ResearchGate profile, or has not yet added these contributions to their profile.

It was automatically created by ResearchGate to create a record of this author's body of work. We create such pages to advance our goal of creating and maintaining the most comprehensive scientific repository possible. In doing so, we process publicly available (personal) data relating to the author as a member of the scientific community.

If you're a ResearchGate member, you can follow this page to keep up with this author's work.

If you are this author, and you don't want us to display this page anymore, please let us know.

Publications (1)

The location of the study area and the research sites from reported literature. (a) the sites location, XA: Xi’an, Chinese Loess Plateau, this study; AUS: Australia (Yao et al. 2019); GER: Germany (Spohn and Giani 2011); SC: South China, Hunan (Wang et al. 2007) and Guangxi (Wang and Wang 2007); SRB: Republic of Serbia (Šeremešić et al. 2013); USA: United States (Rodriguez et al. 2021). The map of mean annual precipitation (MAP) is from the data in https://psl.noaa.gov/. (b), the location of study site and Chinese Loess Plateau. (c), the mean annual temperature and annual precipitation of Xi’an, data are cited from http://data.cma.cn.
The carbon content of the topsoil of the study area. (a) soil organic carbon (SOC) content at 0-5 cm and 5-10 cm, (b) hot water extractable organic carbon (HWOC) content at 0-5 cm and 5-10 cm. The box shows the mean value and ±1σ standard deviation range, and the whisker shows the outlier data.
Comparison of soil organic carbon (SOC) and hot water extractable organic carbon (HWOC) contents between the study area and literature reports. (a) SOC content of woodland, (b) SOC content of grassland, (c) SOC content of arable land, (d) HWOC content of woodland, (e) HWOC content of grassland, and (f) HWOC content of arable land. P/T is the ratio of annual precipitation to annual average temperature, which represents the corresponding precipitation per degree centigrade. AUS: Australia; GER: Germany; SC: South China, Hunan and Guangxi; SRB: Republic of Serbia; USA: United States; XA: Xi’an, Chinese Loess Plateau. Error bars show 1σ standard deviation. XA, AUS, HN and USA were 0-10 cm, and GX, SRB and GER were 0-20 cm.
Hot water extractable organic carbon (HWOC) content and HWOC proportion. (a) HWOC and soil organic carbon (SOC) contents of the study area in 0-10 cm, (b) HWOC and SOC contents from the literature reports, (c) HWOC proportion of the study area, (d), (e), (f), (g) and (h) HWOC proportion from the literature reports. AUS: Australia; GER: Germany; SC: South China, Hunan and Guangxi; SRB: Republic of Serbia; USA: United States; XA: Xi’an, Chinese Loess Plateau. Error bars show 1σ standard deviation.
The lower labile carbon of surface soils in Chinese semiarid areas
  • Article
  • Full-text available

February 2023

·

18 Reads

Acta Agriculturae Scandinavica, Section B — Soil & Plant Science

Acta Agriculturae Scandinavica, Section B — Soil & Plant Science

Fan Zhang

·

Jiamin Qi

·

Congwen Gui

·

[...]

·

Zheng Wang

Hot water extractable organic carbon (HWOC), the labile carbon component, is often used to indicate soil organic carbon (SOC) dynamics. Nevertheless, few studies have been carried out in arid climate areas which affects our full understanding of HWOC. Here, we investigated the change in HWOC in the topsoil of different ecosystems in the southern part of the Loess Plateau in the semiarid region of China and compared it with that in other regions. The HWOC concentrations of the study area (0-10 cm) were 0.27 ± 0.12 g C kg⁻¹ and 0.19 ± 0.04 g C kg⁻¹ in the natural and agricultural systems respectively, and the HWOC proportions were 1.38 ± 0.38% and 2.18 ± 0.22%. The HWOC concentration and proportion in the study area were much lower than the reported data in other areas, which may be affected by drought conditions. Irrigation could weaken the difference in HWOC between agricultural systems in different regions. Since HWOC is easily lost due to the impact of the arid climate, the soil carbon balance and carbon sequestration in arid and semiarid areas are relatively unstable, indicating that soil management should be improved in combination with water management.

Download
Share