Abstract
Anthropogenic overexploitation poses significant threats to the ecosystems that surround mining sites, which also have tremendous negative impacts on human health and society safety. The technological capacity of the ecological restoration of mine sites is imminent, however, it remains a challenge to sustain the green restorative effects of ecological reconstruction. As a promising and environmentally friendly method, the use of microbial technologies to improve existing ecological restoration strategies have shown to be effective. Nonetheless, research into the mechanisms and influences of rock-solubilizing microbial inoculums on plant growth is negligible and the lack of this knowledge inhibits the broader application of this technology. We compared the effects of rock-solubilizing microbial inoculums on two plant species. The results revealed that rock-solubilizing microbial inoculums significantly increased the number of nodules and the total nodule volume of Robinia pseudoacacia L. but not of Lespedeza bicolor Turcz. The reason of the opposite reactions is possibly because the growth of R. pseudoacacia was significantly correlated with nodule formation, whereas L. bicolor’s growth index was more closely related to soil characteristics and if soil nitrogen content was sufficient to support its growth. Further, we found that soil sucrase activity contributed the most to the height of R. pseudoacacia, and the total volume of root nodules contributed most to its ground diameter and leaf area. Differently, we found a high contribution of total soil carbon to seedling height and ground diameter of L. bicolor, and the soil phosphatase activity contributed the most to the L. bicolor’ s leaf area. Our work suggests that the addition of rock-solubilizing microbial inoculums can enhance the supply capacity of soil nutrients and the ability of plants to take up nutrients for the promotion of plant growth. Altogether, our study provides technical support for the practical application of rock-solubilizing microbes on bare rock in the future.
Highlights
Open-pit mining makes significant contributions to economic development, it can degrade ecosystems through soil erosion and the loss of productive land, which restricts social development and endangers the wellbeing of neighboring residents [1,2,3,4]
We found that the addition of NL-11, NL-11 + NL-15, and NL-1 + NL-11 + NL-15 resulted in significant changes in the photosynthetic system and roots of R. pseudoacacia and L. bicolor [21]
Boosted Regression Tree (BRT) analysis showed that plant nitrogen uptake, nodulation status, and soil urease activities contribute more than 10% to the growth factors of R. pseudoacacia and L. bicolor
Summary
Open-pit mining makes significant contributions to economic development, it can degrade ecosystems through soil erosion and the loss of productive land, which restricts social development and endangers the wellbeing of neighboring residents [1,2,3,4]. There are various approaches for the ecological restoration of carbonate mining areas. Issues related to the erosion resistance of bare rocky slopes when combined with spraying matrices occur subsequent to the application of this technology, which limits its applications for the ecological restoration of mining areas [11]. This is primarily manifested through difficulties in the sustained preservation and propagation of vegetation [12]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
