[Objectives]This study was conducted to investigate the effects of biochar-based fertilizer on high yield and quality of green pepper(Zanthoxylum armatum var.novemfolius)and soil nutrient status.[Methods]With green pe...[Objectives]This study was conducted to investigate the effects of biochar-based fertilizer on high yield and quality of green pepper(Zanthoxylum armatum var.novemfolius)and soil nutrient status.[Methods]With green pepper and pepper field soil as the research subjects,four treatments were set up,namely,conventional fertilization(T_(1)),conventional fertilization+biochar(T_(2)),biochar-based fertilizer 1(T_(3)),and biochar-based fertilizer 2(T_(4)).[Results]The application of biochar-based fertilizer increased green pepper yield by 9.37%-51.12%,with the order of increase being T_(4)>T_(3)>T_(2)>T_(1).In terms of soil nutrients,biochar-based fertilizer raised soil pH by 6.67%-53.33%,with the order of increase being T_(3)>T_(4)>T_(2)>T_(1).The initially strongly acidic soil gradually shifted to weakly acidic and approached neutral,indicating significantly improved soil acidity.The application of biochar-based fertilizer increased the contents of soil organic matter,available nitrogen,available phosphorus,available potassium,available copper,available zinc,available iron,and available manganese.It significantly enhanced green pepper yield,improved soil acidity,and elevated soil nutrient levels.Considering yield,nutrient uptake,and soil nutrient content,biochar-based fertilizer 2(T_(4))was identified as the optimal treatment.[Conclusions]This study provides a theoretical basis for improving green pepper yield and soil amendment.展开更多
This study investigated the effects of planting duration(1,5,10 and 15 years)on soil properties,bacterial community diversity,and function in the rhizosphere of Zanthoxylum bungeanum.We employed Illumina highthroughpu...This study investigated the effects of planting duration(1,5,10 and 15 years)on soil properties,bacterial community diversity,and function in the rhizosphere of Zanthoxylum bungeanum.We employed Illumina highthroughput sequencing and PICRUSt2 functional prediction to analyze the structure and functional potential of rhizosphere soil bacterial communities.The Mantel test and redundancy analysis were used to identify physicochemical factors influencing bacterial community structure and function.The results indicated significant differences in rhizosphere soil physicochemical properties across planting years:the content of organic matter,alkaline hydrolyzable nitrogen in the soil,as well as the activity of invertase,urease,and alkaline phosphatase initially increased and then decreased,while available potassium,Olsen-phosphorus content,and peroxidase activity continued to increase.However,bacterial alpha diversity(Chao1 and Shannon indices)and the number of amplicon sequence variants increased continuously with planting duration.Principal coordinate analysis and Adonis tests revealed that the planting year significantly influenced the bacterial community structure(p<0.05).The phyla Proteobacteria,Actinobacteria,Acidobacteriota and Chloroflexi collectively constituted 56.7%to 71.2%of the relative abundance,representing the dominant taxa.PICRUSt2 predictions indicated key functional categories(cellular processes,metabolism,genetic information processing,and environmental information processing)each exceeding 10%relative abundance.BugBase analysis revealed a progressive increase in aerobic and oxidative stress-tolerant bacteria and a decrease in anaerobic and potentially pathogenic bacteria.Differential indicator species analysis identified Firmicutes,Planctomycetes,Methylomirabilota and Actinobacteriota as key discriminators for the 1-,5-,10-and 15-year stages,respectively.Organic matter,alkaline phosphatase,soil pH,and available phosphorus were the primary physicochemical drivers of bacterial communities.Notably,soil organic matter significantly influenced both the community structure(p<0.05)and predictedmetabolic functions(p<0.05).In conclusion,prolonged planting duration significantly enhanced rhizosphere microbial diversity and functional gene abundance in Z.bungeanumwhile driving the structural succession of bacterial communities dominated by Proteobacteria,Actinobacteria,Acidobacteriota,and Chloroflexi.This ecological shift,characterized by increased aerobic/oxidative-stress taxa and decreased anaerobic/pathogenic bacteria,was primarily regulated by soil organic matter,a key driver shaping both community structure and metabolic functions,ultimately improving soil microecological health.展开更多
To provide reference for the prevention and control of diseases,pests,and weeds on Zanthoxylum bungeanum Maxim.and the research and development of new pesticide registrations,this paper analyzes the quantity,variety s...To provide reference for the prevention and control of diseases,pests,and weeds on Zanthoxylum bungeanum Maxim.and the research and development of new pesticide registrations,this paper analyzes the quantity,variety structure,dosage forms,and toxicity of pesticides registered on Z.bungeanum in China.The analysis reveals a relatively low quantity of pesticide registrations on Z.bungeanum,with no herbicide registrations;suspension concentrates dominate the dosage forms,and pesticide toxicity is classified as low-toxicity or micro-toxicity;registered pesticides target only rust,anthracnose,scale insects,aphids,and spider mites,while plant growth regulators solely involve growth regulation and shoot control.Given the current status of limited and incomplete pesticide registrations targeting major diseases,pests,and weeds on Z.bungeanum,severe product homogenization,and unknown maximum residue limits,it is recommended to intensify efforts in pesticide registration on Z.bungeanum,actively research and apply green control technologies,strengthen technical training guidance and pesticide supervision enforcement,to promote the healthy development of the industry.展开更多
基金Supported by General Project of Chongqing Technology Innovation and Application Demonstration(Social People s Livelihood Category)(cstc2018jscx-msybX0215)Horizontal Project of Chongqing Agricultural Technology Extension Station(WLHX-2021-0113).
文摘[Objectives]This study was conducted to investigate the effects of biochar-based fertilizer on high yield and quality of green pepper(Zanthoxylum armatum var.novemfolius)and soil nutrient status.[Methods]With green pepper and pepper field soil as the research subjects,four treatments were set up,namely,conventional fertilization(T_(1)),conventional fertilization+biochar(T_(2)),biochar-based fertilizer 1(T_(3)),and biochar-based fertilizer 2(T_(4)).[Results]The application of biochar-based fertilizer increased green pepper yield by 9.37%-51.12%,with the order of increase being T_(4)>T_(3)>T_(2)>T_(1).In terms of soil nutrients,biochar-based fertilizer raised soil pH by 6.67%-53.33%,with the order of increase being T_(3)>T_(4)>T_(2)>T_(1).The initially strongly acidic soil gradually shifted to weakly acidic and approached neutral,indicating significantly improved soil acidity.The application of biochar-based fertilizer increased the contents of soil organic matter,available nitrogen,available phosphorus,available potassium,available copper,available zinc,available iron,and available manganese.It significantly enhanced green pepper yield,improved soil acidity,and elevated soil nutrient levels.Considering yield,nutrient uptake,and soil nutrient content,biochar-based fertilizer 2(T_(4))was identified as the optimal treatment.[Conclusions]This study provides a theoretical basis for improving green pepper yield and soil amendment.
基金supported by Forestry and Grassland Science and Technology Innovation Project(LCKJCX2022001)from Forestry and Grassland Bureau of Gansu Province’s.
文摘This study investigated the effects of planting duration(1,5,10 and 15 years)on soil properties,bacterial community diversity,and function in the rhizosphere of Zanthoxylum bungeanum.We employed Illumina highthroughput sequencing and PICRUSt2 functional prediction to analyze the structure and functional potential of rhizosphere soil bacterial communities.The Mantel test and redundancy analysis were used to identify physicochemical factors influencing bacterial community structure and function.The results indicated significant differences in rhizosphere soil physicochemical properties across planting years:the content of organic matter,alkaline hydrolyzable nitrogen in the soil,as well as the activity of invertase,urease,and alkaline phosphatase initially increased and then decreased,while available potassium,Olsen-phosphorus content,and peroxidase activity continued to increase.However,bacterial alpha diversity(Chao1 and Shannon indices)and the number of amplicon sequence variants increased continuously with planting duration.Principal coordinate analysis and Adonis tests revealed that the planting year significantly influenced the bacterial community structure(p<0.05).The phyla Proteobacteria,Actinobacteria,Acidobacteriota and Chloroflexi collectively constituted 56.7%to 71.2%of the relative abundance,representing the dominant taxa.PICRUSt2 predictions indicated key functional categories(cellular processes,metabolism,genetic information processing,and environmental information processing)each exceeding 10%relative abundance.BugBase analysis revealed a progressive increase in aerobic and oxidative stress-tolerant bacteria and a decrease in anaerobic and potentially pathogenic bacteria.Differential indicator species analysis identified Firmicutes,Planctomycetes,Methylomirabilota and Actinobacteriota as key discriminators for the 1-,5-,10-and 15-year stages,respectively.Organic matter,alkaline phosphatase,soil pH,and available phosphorus were the primary physicochemical drivers of bacterial communities.Notably,soil organic matter significantly influenced both the community structure(p<0.05)and predictedmetabolic functions(p<0.05).In conclusion,prolonged planting duration significantly enhanced rhizosphere microbial diversity and functional gene abundance in Z.bungeanumwhile driving the structural succession of bacterial communities dominated by Proteobacteria,Actinobacteria,Acidobacteriota,and Chloroflexi.This ecological shift,characterized by increased aerobic/oxidative-stress taxa and decreased anaerobic/pathogenic bacteria,was primarily regulated by soil organic matter,a key driver shaping both community structure and metabolic functions,ultimately improving soil microecological health.
基金Supported by Sichuan Province Zanthoxylum bungeanum Maxim.Innovation Team Project"Green Control of Diseases and Weeds on Zanthoxylum bungeanum Maxim."Institute-Local Cooperation Project"Demonstration of Chemical Fertilizer and Pesticide Reduction Techniques in Hongya County(2024-2026)".
文摘To provide reference for the prevention and control of diseases,pests,and weeds on Zanthoxylum bungeanum Maxim.and the research and development of new pesticide registrations,this paper analyzes the quantity,variety structure,dosage forms,and toxicity of pesticides registered on Z.bungeanum in China.The analysis reveals a relatively low quantity of pesticide registrations on Z.bungeanum,with no herbicide registrations;suspension concentrates dominate the dosage forms,and pesticide toxicity is classified as low-toxicity or micro-toxicity;registered pesticides target only rust,anthracnose,scale insects,aphids,and spider mites,while plant growth regulators solely involve growth regulation and shoot control.Given the current status of limited and incomplete pesticide registrations targeting major diseases,pests,and weeds on Z.bungeanum,severe product homogenization,and unknown maximum residue limits,it is recommended to intensify efforts in pesticide registration on Z.bungeanum,actively research and apply green control technologies,strengthen technical training guidance and pesticide supervision enforcement,to promote the healthy development of the industry.
