参考文献/References:
[1] 黄坚钦,夏国华.图说山核桃生态栽培技术[M]. 杭州:浙江科学技术出版社,2008:7-8.
[2] 吕惠进.浙江临安山核桃立地环境研究[J].森林工程,2005,21(1):1-3.
[3] 艾呈祥,李翠学,陈相艳,等.我国山核桃属植物资源[J].落叶果树,2006,38(4):23-24.
[4] JIN J,WANG L,MULLER K,et al. A 10-year monitoring of soil properties dynamics and soil fertility evaluation in Chinese hickory plantation regions of southeastern China[J]. Sci Rep,2021,11:23531.
[5] FU W,DONG J,DING L,et al. Spatial correlation of nutrients in a typical soil-hickory system of southeastern China and its implication for site-specific fertilizer application[J]. Soil Tillage Res,2022,217:105265.
[6] 颜芳.农林废弃物山核桃蒲壳资源化利用研究进展[J].安徽农业科学,2013,41(14):6329-6330.
[7] 常海楠.山核桃蒲壳用作铁皮石斛栽培基质的应用技术研究[D].杭州:浙江农林大学,2015.
[8] 申秀英,毛建卫,蔡成岗.山核桃外蒲壳成分与功能研究进展[J].食品研究与开发,2013,34(21):128-130.
[9] 王国平,过婉珍.山核桃蒲壳污染综合治理及其效应[J].现代农业科技,2006,12:72-73.
[10] DONG Q G,YANG Y C,YU K,et al.Effects of straw mulching and plastic film mulching on improving soil organic carbon and nitrogen fractions, crop yield and water use efficiency in the Loess Plateau, China[J]. Agr Water Manag,2018,201:133-43.
[11] ZHANG S N,WANG Y,SUN L T,et al.Organic mulching positively regulates the soil microbial communities and ecosystem functions in tea plantation[J]. BMC Microbiol,2020,20(5):374-382.
[12] LOPEZ V M,GOMEZ J A,GUZMAN G,et al.The role of cover crops in the loss of protected and non-protected soil organic carbon fractions due to water erosion in a Mediterranean olive grove[J]. Soil Tillage Res,2021,213:105119.
[13] 周子军,郭松,陈琨,等.长期秸秆覆盖对免耕稻-麦产量、土壤氮组分及微生物群落的影响[J].土壤学报,2021,7:1-13.
[14] 顾美英,唐光木,刘洪亮,等.施用棉秆炭对新疆连作棉花根际土壤微生物群落结构和功能的影响[J]. 应用生态学报,2016,27(1):173-181.
[15] ENWALL K,NYBERG K,BERTILSSON S,et al.Long-term impact of fertilization on activity and composition of bacterial communities and metabolic guilds in agricultural soil[J]. Soil Biol Biochem,2007,39:106-115.
[16] 鲁如坤.土壤农业化学分析方法[M]. 北京:中国农业科技出版社,2000:146-195.
[17] BOSSIO D A,SCOW K M.Impacts of carbon and flooding on soil microbial communities: phospholipid fatty acid profiles and substrate utilization patterns[J]. Microb Ecol,1998,35,265-278.
[18] WILLIAMSON G B,RICHARDSON D.Bioassays for allelopathy: Measuring treatment responses with independent controls[J]. J Chem Ecol, 1988,14(1):181-187.
[19] 陈向明,俞志敏,金杰,等.山核桃外蒲壳无机成分的分析研究[J].分析实验室,2006,26(8):45-47.
[20] 姜著英,宣贵达,李林林.山核桃蒲壳化学成分定性鉴定及总生物碱提取工艺研究[J]. 浙江大学学报(理学版),2009,36(4):442-449.
[21] 望银平,许彬彬,李姝婉,等.山核桃蒲综合利用的研究进展[J].广州化工,2013,41(23):20-22.
[22] DURING C,WEEDA W C,DOROFAEFF D F.Some effects of cattle dung on soil properties, pasture production,and nutrient uptake[J]. N Zealand J Agr Res,2012,16(3):431-438.
[23] SCHMID M W I,NOACK A G.Black carbon in soils and sediments: analysis, distribution, implications, and current challenges[J]. Global Biogeochem Cycles,2000,14(3):777-793.
[24] HARTER J,KRAUSE H M,SCHUETTLER S,et al.Linking N2O emissions from biochar-amended soil to the structure and function of the N-cycling microbial community[J]. ISME J,2014,8(3):660-674.
[25] SHURE D J,GOTTSCHALK M R,PARSONS K A.Litter decomposition processes in a floodplain forest[J]. Amer Midland Nat,1986,115 (2):314-327.
[26] 韩晓君,张先政.不同作物秸秆腐熟还田对土壤理化性质及作物产量的影响分析[J]. 安徽农学通报,2013,19(16):80-82.
[27] CHEN Z,WANG Y P,XIA D,et al. Enhanced bio reduction of iron and arsenic in sediment by biochar amendment influencing microbial community composition and dissolved organic matter content and composition[J]. J Hazard Mater,2016,311,20-29.
[28] IPPOLITO J A,STROMBERGER M E,LENTZ R D,et al.Hardwood biochar influences calcareous soil physicochemical and microbiological status[J]. J Environ Quality,2014,43(2):681-689.
[29] ZHANG Y L,LI T T,WU H H.Effect of different fertilization practices on soil microbial community in a wheat-maize rotation system, Sustainability,2019,11:4088.
[30] ASADU C O,ANEKE N G,EGBUNA S O,et al.Comparative studies on the impact of bio-fertilizer produced from agro-wastes using thermo-tolerant actinomycetes on the growth performance of Maize(Zea mays)and Okro (Abelmoschus esculentus)[J]. Environ Technol Innov,2018,12:55-71.
[31] GARCIA-SANCHEZ M,GARCIA-ROMERA I,CAJTHAML T,et al.Changes in soil microbial community functionality and structure in a metal-polluted site: The effect of dig estate and fly ash applications[J]. J Environ Manag,2015,162:63-73.
[32] SINSABAUGH R L,FOLLSTAD SHAH J J.Ecoenzymatic stoichiometry of recalcitrant organic matter decomposition: the growth rate hypothesis in reverse[J]. Biogeochemistry,2011,102(1-3):31-43.
[33] DEBOSZ K,RASMUSSEN P H,PEDERSEN A R.Temporal variations in microbial biomass C and cellulolytic enzyme activity in arable soils:effects of organic matter input[J]. App Soil Ecol,1999,13(3):209-218.
[34] VERES Z,KOTROCZ? Z,FEKETE I,et al.Soil extracellular enzyme activities are sensitive indicators of detrital inputs and carbon availability[J]. App Soil Ecol,2015,92:18-23.