Anthropogenic shrub encroachment has accelerated the degradation of desert steppe soil over the past four decades
Abstract
Anthropogenic and natural shrub encroachment have similar ecological consequences on native grassland ecosystems. In fact, there is an accelerating trend toward anthropogenic shrub encroachment, as opposed to the century-long process of natural shrub encroachment. However, the soil quality during the transition of anthropogenic shrub encroachment into grasslands remains insufficiently understood. Here, we used a soil quality assessment method that utilized three datasets and two scoring methods to evaluate changes in soil quality during the anthropogenic transition from temperate desert grassland to shrubland. Our findings demonstrated that the soil quality index decreased with increasing shrub cover, from 0.49 in the desert grassland to 0.31 in the shrubland. Our final results revealed a gradual and significant decline of 36.73 % in soil quality during the transition from desert grassland to shrubland. Reduced soil moisture levels, nutrient availability, and microbial activity characterized this decline. Nearly four decades of anthropogenic shrub encroachment have exacerbated soil drought conditions while leading to a decrease in perennial herbaceous plants and an increase in bare ground cover; these factors can explain the observed decline in soil quality. These findings emphasize the importance of considering soil moisture availability and potential thresholds when implementing revegetation strategies in arid and semiarid regions.
- Publication:
-
Science of the Total Environment
- Pub Date:
- October 2024
- DOI:
- 10.1016/j.scitotenv.2024.174487
- Bibcode:
- 2024ScTEn.94674487Z
- Keywords:
-
- Anthropogenic shrub encroachment;
- Temperate desert steppe;
- Woody plant encroachment;
- Soil quality index;
- Soil moisture;
- Land degradation;
- SWC;
- soil water content;
- SMC;
- saturation moisture capacity;
- CMC;
- capillary moisture capacity;
- SCP;
- soil compactness;
- EC;
- electrical conductance;
- BD;
- bulk density;
- FC;
- field capacity;
- NCP;
- non-capillary porosity;
- CP;
- capillary porosity;
- TPO;
- total porosity;
- STC;
- soil total carbon;
- SIC;
- soil inorganic carbon;
- SOC;
- soil organic carbon;
- DOC;
- dissolved organic carbon;
- SIN;
- soil inorganic nitrogen;
- NO<SUB>3</SUB><SUP>-</SUP>-N;
- nitrate nitrogen;
- NH<SUB>4</SUB><SUP>+</SUP>-N;
- ammonium nitrogen;
- STN;
- soil total nitrogen;
- SON;
- soil organic nitrogen;
- STP;
- soil total phosphorus;
- MBC;
- microbial biomass carbon;
- MBN;
- microbial biomass nitrogen;
- MBP;
- microbial biomass phosphorus;
- BG;
- β-1;
- 4-glucosidas;
- BXYL;
- β-1;
- 4-xylosidase;
- LAP;
- leucine aminopeptidase;
- NAG;
- β-1;
- 4-N-acetylglucosaminidase;
- AKP;
- alkaline phosphatase;
- SC;
- sucrose;
- AKPT;
- alkaline protease;
- UE;
- urease;
- CAT;
- catalase;
- BA;
- bacteria abundance;
- FA;
- fungi abundance;
- SMR;
- soil microbial respiration