不同生物有机肥应用效果及机理的比较研究
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摘要
本试验是把本室自己组配的两种微生物制剂与现在广泛使用的EM、CM(处理2)和BL(处理3)的应用效果作比较,以为研究出效果更好、有自己知识产权的微生物有机肥提供科学依据。在试验过程中,利用微生物制剂处理畜禽粪便和农作物秸秆制做成堆肥作为底肥施入到土壤中,这样既可以发挥生物有机肥在改善土壤环境、提高作物产量和改善作物产品品质的作用,同时也为农业废弃物资源化提供新的途径。
1、施用有机肥可以改善土壤性质,提高土壤养分,增加土壤的生物活性。总的趋势是:生物有机肥>传统有机肥>不施肥处理。几种生物有机肥之间的比较,以EM(处理1)的效果更好,其次为本室筛选的B~#(处理4)和M~#(处理5),其他几种生物有机肥各有其特点。如土壤阳离子交换以处理1、处理4和处理5提高更为显著,其他土壤物理性状的改善也有类似的趋势。各施肥处理有机质和全氮增加顺序均为:处理1>处理2>处理4>处理5>处理3。土壤中的有效养分的增加以处理1为最高,其次为处理4和处理5。在改善生物学性质方面,因为不同生物有机肥所含菌种不同,所以形成不同的优势菌群。
2、有机肥的作用最终体现在提高作物产量和改善作物产品品质上。在提高作物产量和改善作物品质方面,生物有机肥也优于传统有机肥。小麦产量生物有机肥处理比传统有机肥处理高3.41%~27.8%,夏玉米产量生物有机肥处理比传统有机肥处理高0.8%~23.62%。夏玉米籽粒粗蛋白含量生物有机肥处理比传统有机肥处理高4.48%~7.26%,差异极显著。在提高作物产量上,小麦的产量以处理1最高,其次是处理4和处理5,其排序是处理1>处理4>处理5>处理3>处理2>处理6(传统堆肥)>处理7(对照),夏玉米的产量与其有相似的的趋势。在改善作物品质上的效果通过对玉米籽粒粗蛋白的测定来体现,处理1是最高的6.84%,其次为处理5,其顺序为处理1>处理5>处理3>处理4>处理2>处理6>处理7。但各生物有机肥处理之间差异并不显著。
In this study: two kinds of effective microorganism, which are confected by our lab, are compared to EM, CM(treatment 2) and BL(treatment 3) used widely with application effect to offer scientific data for developing the fertilizer with better results and holding property right. In the course of study, the biological organic compost is made of using microorganism preparation to deal with the agricultural organic waste. It may bring bio-fertilizer into influence on improving soil environment; increasing crop yield and reforming product reality, contemporary offer a new approach for exploring the agricultural organic waste.
1. Employing organic fertilizer could ameliorate the character of soil, increase the capacity of soil nutrient providing and advance soil biological activities. Total trend as follow: biological-organic fertilizer>traditional-organic fertilizer>no fertilizer. Compared with several various bio-organic fertilizer, effect of EM(treatment 1) was best, secondly it was B# (treatment 4) and M#(treatment 5) which was confected by our lab. Others had respective character. For example, in treatmentl, 4 and 5, soil positive ion exchange is improved more obvious, rest soil physical properties were improved on similar trend. Increasing sequence of organism and total N as follow: treatment 1, 2 , 4, 5, 3. Enhancement of soil available nutrient was highest in treatment 1, treatment 4 and 5 on the second place. On aspect of improving biological property, because different kinds bioorganic fertilizer contained various microorganism, distinct superiority community was formed.
2.Effect of organic fertilizer was embodied in adding yield and ameliorating quality. On ascending aspect, bio-organic fertilizer excelled to traditional-organic fertilizer. Compared with it yield declined 0.8%~23.62% and the content of corn seed coarse protein reduced 4.48%~7.26% in traditional-organic fertilizer treatment. The wheat yield was highest in treatment 1, next was treatment 4 and 5. In yield sequence as follow: treatment l,4,5,3,2,6(tradational compost),7(ck), corn yield with similar tread. The effect of improving product quality was show by measuring seed core protein. The highest value is 6.84% in treatment 1. The second was treatment 5. But, the difference was not notable among various bio-organic fertilizer treatments.
1、施用有机肥可以改善土壤性质,提高土壤养分,增加土壤的生物活性。总的趋势是:生物有机肥>传统有机肥>不施肥处理。几种生物有机肥之间的比较,以EM(处理1)的效果更好,其次为本室筛选的B~#(处理4)和M~#(处理5),其他几种生物有机肥各有其特点。如土壤阳离子交换以处理1、处理4和处理5提高更为显著,其他土壤物理性状的改善也有类似的趋势。各施肥处理有机质和全氮增加顺序均为:处理1>处理2>处理4>处理5>处理3。土壤中的有效养分的增加以处理1为最高,其次为处理4和处理5。在改善生物学性质方面,因为不同生物有机肥所含菌种不同,所以形成不同的优势菌群。
2、有机肥的作用最终体现在提高作物产量和改善作物产品品质上。在提高作物产量和改善作物品质方面,生物有机肥也优于传统有机肥。小麦产量生物有机肥处理比传统有机肥处理高3.41%~27.8%,夏玉米产量生物有机肥处理比传统有机肥处理高0.8%~23.62%。夏玉米籽粒粗蛋白含量生物有机肥处理比传统有机肥处理高4.48%~7.26%,差异极显著。在提高作物产量上,小麦的产量以处理1最高,其次是处理4和处理5,其排序是处理1>处理4>处理5>处理3>处理2>处理6(传统堆肥)>处理7(对照),夏玉米的产量与其有相似的的趋势。在改善作物品质上的效果通过对玉米籽粒粗蛋白的测定来体现,处理1是最高的6.84%,其次为处理5,其顺序为处理1>处理5>处理3>处理4>处理2>处理6>处理7。但各生物有机肥处理之间差异并不显著。
In this study: two kinds of effective microorganism, which are confected by our lab, are compared to EM, CM(treatment 2) and BL(treatment 3) used widely with application effect to offer scientific data for developing the fertilizer with better results and holding property right. In the course of study, the biological organic compost is made of using microorganism preparation to deal with the agricultural organic waste. It may bring bio-fertilizer into influence on improving soil environment; increasing crop yield and reforming product reality, contemporary offer a new approach for exploring the agricultural organic waste.
1. Employing organic fertilizer could ameliorate the character of soil, increase the capacity of soil nutrient providing and advance soil biological activities. Total trend as follow: biological-organic fertilizer>traditional-organic fertilizer>no fertilizer. Compared with several various bio-organic fertilizer, effect of EM(treatment 1) was best, secondly it was B# (treatment 4) and M#(treatment 5) which was confected by our lab. Others had respective character. For example, in treatmentl, 4 and 5, soil positive ion exchange is improved more obvious, rest soil physical properties were improved on similar trend. Increasing sequence of organism and total N as follow: treatment 1, 2 , 4, 5, 3. Enhancement of soil available nutrient was highest in treatment 1, treatment 4 and 5 on the second place. On aspect of improving biological property, because different kinds bioorganic fertilizer contained various microorganism, distinct superiority community was formed.
2.Effect of organic fertilizer was embodied in adding yield and ameliorating quality. On ascending aspect, bio-organic fertilizer excelled to traditional-organic fertilizer. Compared with it yield declined 0.8%~23.62% and the content of corn seed coarse protein reduced 4.48%~7.26% in traditional-organic fertilizer treatment. The wheat yield was highest in treatment 1, next was treatment 4 and 5. In yield sequence as follow: treatment l,4,5,3,2,6(tradational compost),7(ck), corn yield with similar tread. The effect of improving product quality was show by measuring seed core protein. The highest value is 6.84% in treatment 1. The second was treatment 5. But, the difference was not notable among various bio-organic fertilizer treatments.
引文
曹翠玲等.氮素水平对冬小麦分蘖期某些含氮化合物及生物量的影响[J].西北农林科技大学学报(自然科学版),2002,30(6):11~14.
曹仁林,贾晓葵.我国集约农业中氮污染问题及防治对策[J].农业环境保护,2001(3).
曹志洪.科学施肥与我国粮食安全保障[J].土壤,1998,2:57~63,69.
陈利根.我国耕地资源可持续利用研究[J].生态农业研究,1999,7(1):28~31.
陈琼贤等.有机肥料和无机肥料对土壤微量元素含量的影响[J].热带亚热带土壤科学,1997,6(4):235~238.
陈廷伟等.我国微生物肥料发展趋向[J].土壤肥料,1995(6):16~19.
陈文新.土壤和环境微生物学[M].北京:中国农业大学出版社,1990.
陈晓斌,张炳欣.植物根围促生细菌 (PGPR)作用机制的研究进展[J].微生物杂志,2000,20(1):38~41,44.
陈新宏.小麦顶三叶与粒重关系的研究初报[J].西北农林科技大学学报,2002,30(4):6~8.
褚天铎.澄清化肥使用中的几个问题[J].土壤肥料,1997,5.
葛诚.微生物有料概述[J].土壤肥料,1993,(8):43~47.
顾锡江.夏玉米高产栽培技术研究[J].玉米科学,1997,5(1):50~53.
胡承孝.氮素水平对蔬菜品质的影响[J].土壤肥料,1996(3):34~36.
胡雪峰,王效举.农业生产与土壤变化[J].热带亚热带土壤科学,1998,7(1):64~67.
黄昌勇.土壤学[M].北京:中国农业出版社,2000.
金善宝.中国小麦学[M],北京:中国农业出版社,1996.
靳贤福.水资源存在问题及对策[J].甘肃农业,2001(1):20~22.
康白.微生态学[M].大连:大连出版社,1988.
寇长林,王永岐等.施肥结构对砂质潮土中微量元素空间变化的影响[J].土壤通报,2001,2,32(1).
赖庆旺等.无机肥连施对红壤性水稻有机质消长的影响[J].土壤肥料,1991(1):3~7.
李纯忠等.我国耕地土壤生产潜力分析[J].土壤肥料,1996(1):1~5.
李登武等.施钾和AM真菌对考烟产量和品质的影响[J].西北农林科技大学学报(自然科学版),2002,30(5):63~68.
李东风.光合细菌的开发应用动态[J].微生物学杂志,1998,2(18):44~50.
李芳柏,廖宗文.试论我国有机无机肥料的配合使用[J].热带亚热带土壤科学,1996,5(3):167~172.
李生秀.植物营养与肥料科学的现状与发展[J].植物营养与肥料学报,1999,5(3):193~250.
李维炯,倪永珍.EM(有效微生物群)的研究与应用[J].生态学杂志;1995,14(5):58~62.
李星洪等.花生施用微物肥的作用和增产效果初探[J].土壤肥料,1998(2):35~37.
林葆,林继雄,李家康.长期施肥的作物产量和土壤肥力变化[J].植物营养与肥料学报,1994,9(1):6~18.
林成谷.土壤学[M].北京:农业出版社,1983.
刘更另等.中国有机肥料[M].北京:农业出版社,1991.
刘经荣.水稻土有机无机肥料配合的效应[J].江西农业大学学报,1990,12(1):37~42.
刘丽生等.生物肥料的作用特点和发展趋势[J].黑龙江农业科学,2001(5):30~31.
刘丽丽等.津农菌肥对水果糖度和着色度的影响[J].天津农业科学,1995,1(3):17~18.
刘玉凯.整治农业生态环境刻不容缓[J].农村生态环境,2002,18(2):47~49.
吕殿青,同延安,孙本华.氮肥施用对环境污染影响的研究[J].植物营养与肥料学报,1998,4(1):8~15.
毛知耘.肥料学[M].北京:中国农业出版社,1995.
孟旭光.我国国土资源安全面临的挑战及对策[J].中国人口、资源与环境,2002,12(1):47~50.
倪永珍,李维炯.EM技术应用研究[M].北京:中国农业大学出版社,1998.
潘超美等.VA菌根真菌对玉米生长及根际微生态环境的影响[J].土壤与环境,2000,9(4):304~306.
彭运生,刘恩.关于提取叶绿素方法的比较研究[J].北京农业大学学报,1992,18(3):247~248.
彭可珊.我国粮食生产可持续发展问题的再认识[J].国土与自然资源研究,1998,12(3):10~14.
仇志华等.施用阿姆斯生物肥土壤养分的变化研究[J].中国农学通报,1999,15(4):59~60.
任祖淦,陈玉水等.有机肥料配施对土壤微生物和酶活性的影响[J].植物营养与肥料学报,1996,2(3):279~283.
司友斌等.农田氮磷的流失与水体富营养化[J].土壤,2000,8,32(4):188~193.
单玉珊等.小麦高产栽培技术原理[M].2001,6.
沈景文.化肥农药和污灌对地下水的污染[J].农业环境保护,1992,11(3):137~139.
沈其荣.土壤肥料科学通论[M].北京:高等教育出版社.
沈中泉,郭云桃,袁家富.有机肥料对改善农产品品质的作用及机理[J].植物营养与肥料学报,1995,1(2):54~59.
宋秀杰.我国有机肥利用现状及合理利用的技术措施[J].农村生态环境,1997,13(2):56~59.
宋玉清,马麟祥.生物肥料在辽宁省的应用[J].微生物学杂志,1994,14(1):49~51.
孙波等.土壤质量与持续环境Ⅲ.土壤质量评价的生物学指标[J].土壤,1997(5):225~234.
唐勇等.解磷微生物及其应用的研究进展[J].中国农业科学,1995,1(2):41~43.
同小娟.中国农业大学硕士论文,2001.
汪建飞,邢素芝.农田土壤施肥的负效应及其防治对策[J].农业环境保护,1998,17(1):40~43.
王庆仁等.论合理施肥与土壤环境可持续发展[J].环境科学进展,1999,7(2):116~123.
王朝辉,李生秀,田霄鸿.不同氮肥用量对蔬菜硝态氮积累的影响[J].植物营养与肥料学报,1998,4(1):22~28.
王慧中.有机菌肥在马铃薯上的应用[J].江西农业学报2002,14(1):41~43.
王经武等.小麦[M].科学普及出版社,1983.
王世敬等.春小麦籽粒灌浆生理与提高粒重措施的研究[J],宁夏农学院学报,1992,
韦鹤平.环境系统工程[M].上海:同济大学出版社,1993.
魏辉.生物有机无机复合肥的研制与效果研究[J].微生物学杂志,1997,17(3):18~24.
吴波,卢琦.我国荒漠化基本特点及加快荒漠化地区发展的意义[J].中国人口、资源与环境,2002,12(1):99~101.
吴同彦等.小麦株高构成因素与产量及其他性状相关性的研究[J].河北农业大学学报,2002,25(3):10~12.
吴绍騤 等.玉米裁培生理[M].上海:上海科技出版社,1980.
夏荣基等.土壤和肥料基础知识[M].北京:农业出版社,1981.
解金瑞译自 等.No.4,16~18,1992.
赵景逵校.
谢明杰,程爱华,曹文伟.我国微生物肥料的研究进展及发展趋势[J].微生物学杂志,2000,20(4):42~45.
徐恒立,赵君实.高产冬小麦的冠层光合能力及不同器官的贡献[J].作物学报,1995(2):204~209.
徐谦.我国化肥和农药非点源污染状况[J].农村生态环境,1996,12(2):39~43.
许前欣,孟兆芳,于彩虹.微生物肥料农业应用的效益评价[J].天津农业科学,2000,6(2):44~46.
杨林书等.秸秆资源化考略[J].农业环境保护,1993,12(6):271~273,283.
杨文钰,王兰英.作物秸秆还田的现状与展望[J].四川农业大学学报,1999,17(2):211~216.
杨佑兴.倾听巢湖诉说[N].中国环境报,1996年9月10日.
杨玉爱.我国有机肥料研究及展望[J].土壤学报,1996,33(4):414~418.
于彩虹等.生物菌肥对蔬菜品质的影响[J].天津农业科学,2000,6(2):20~22.
于振文等.黄淮麦区冬小麦超高产栽培的理论与实践[J].作物学报,2002,28(5):577~585.
曾广骥等.有机肥提高作物产品品质作用初探[J].黑龙江农业科学,1990(2):10~15.
曾希柏等.农业农用化学品对工农业生态环境的影响及其防治[J].科技导报,2000(4):52~54,59.
占新华,蒋延惠,徐阳春等.微生物制剂促进植物生长机理的研究进展[J].植物营养与肥料学报,1999,5(2):97~105.
张道勇等.中国实用肥料学[M].上海:上海科学技术出版社,1997.
张夫道.氮素营养研究中几个热点问题[J].植物营养与肥料学报,1998,4(4):331~338.
张辉,李维炯,倪永珍等.生物有机无机复合肥效应的初步研究[J].农业环境保护,21(4):352~356.
张晶心.微生态制剂与农业环境保护[J].农业环境保护,1994,13(2):81~83.
张锐,严慧峻,魏由庆等.有机肥在改良盐渍土中的作用[J].土壤肥料,1997(4):11~14.
张维理,田哲旭,张宁等.我国北方农用氮肥造成地下水硝酸盐污染的调查[J].植物营养与肥料学报,1995,1(2):80~87.
张宪政.作物生理研究法[M].北京:农业出版社,1995.
张新明,李华兴,吴文良.氮素肥料对环境与蔬菜的污染及其合理调控途径[J].土壤通报,2002,33(6):471~473.
张玉革等.长期施肥对土壤水分特性影响的研究[J].土壤1999,3:120~125.
张玉先,余国锋等.不同培肥方式对黑土肥力持续效应影响的研究Ⅰ.土壤氮素持续效应[J].黑龙江八一农垦大学学报,2002,13(1):12~16.
赵可夫.玉米生理[M].山东:山东科学技术出版社,1982.
郑长英.施用EM堆肥对土壤螨群落结构的影响[J].生态学报,2002,22(7):1116~1121.
中国农业持续发展和综合生产力研究组.中国农业持续发展和综合生产力研究[M].山东:山东科学技术出版社,1995.
中国农业科学院.小麦栽培理论与技术[M].北京:农业出版社,1979.
中国农业科学院土壤肥料研究所.中国肥料[M].上海:上海科学技术出版社,1994.
朱兆良.农田氮肥的损失与对策[J].土壤与环境,2000,9(1):1~6.
周卫军,王凯荣.不同农业施肥制对红壤稻田土壤肥力的影响[J].热带亚热带土壤科学,1997,6(4):231~234.
Alexander, Soberer. Use of chrome azure S reagents to evaluate siderophore production by photosphere bacteria. Biol. And Fertility of soils, 1991, 12(1): 39~45.
Bay A M et al. Vitamin production in relation to phosphate volatilization by soil bacteria, Soil Biol. Brioche., 1981, 13:527~531.
Brito DE, Alvarez, Gagne, Antoun. Effect of compost on photosphere micro flora of the tomato and on the incidence of plant-growth-promoting rhizobacteria. Applied and Environ. Microbial. ,
1995,61(1): 194~199.
Cooper R. Bacterial fertilizers in Soviet Union. Soils anti fertilizer, 1959,22(5): 327~333.
Duijff, De Kogel, Bakker, Schippers. Infirence of pseudobactin 358 on the iron nutrition of barley. Soil Biol. Biochem., 1994, 26(12):1681~1688.
Elazar Fallik and Yaacov Okon. Indentification and quantification of IAA and IBA in Azospirillum brasilense-inoculated maize roots. Soil Biol. Biochem., 1989,21(1): 147~153.
Grayston, Germida. Sulfur-oxidizing bacteria as plant growth promoting rhizobaceria for canola. J. of Microbiol., 37(7):521~529.
Gonzalez-Lopez J et al. Amino acids and vitamins procueed by Azotobacter vinelandii atcc 12837 in chemically-defined media and dialysed soil media. Soil Biol. Biochem., 1983, 115(6):711~713.
Gruen H E. Auxins and fungi, Annu. Rev. plant physiol., 1959(1): 405~440.
Hussain A, Arsshad M, Hussain A and Hussain E Response of maize(Zea mays) to azotobacter inoculation under fertilized and unfertilized conditions. Biol. Fertil. Soil, 1987, 4: 73~77.
Ikram. Beneficial soil microbes and crop productivity. Planter, 1996, 66(7):640~648.
Koda Y, Takahashi K and Kikuta Y. Potato tuber-inducing activities of salieylic acid and related compounds. J. Plant Growth Regul., 1992, 11: 215~219.
Leslie CA and Romani RJ. Inbibition of ethykene biosynthesis by salicylic acid. Plant Physiol., 1988, 88: 833~837.
M.A.Mcmahon. Fertilizer use and environmental impact, Agro-chemicals News in Brief, 1995 Vol Ⅹ Ⅷ, No.4, Marumoto T, Anderson J P, Domsch K H. Mineralization of nutrients from soil microbial biomass. Soil Biol & Biochem, 1982, 14: 469~475.
Marschner, Ascher, Graham. Effect of manganese- reducing rhizosphere bacteria on the growth of Gaeuman-nomyees graminis var. critic and on manganese uptake by wheat (Tritium festive L.). Biol. And Fertility of Soils, 1991,12(1) 33~38.
Muhammad arched and Frankenberger WT Jr. Microbial prodrction of plant hormones. Plant and Soil, 1991, 133:1~8.
Nieto K F and Frankkenberger WT Jr, Biosynthesis of cytokinins prodrced by Azotobater chroococcum, Soil Biol. & Biochem., 1989(21): 967~972.
Schloter, Bode, Hartmann, Beese. Sensitive chemolumine-scence-based immunologiacal quantification of bacteria of bacteria in soil extracts with monoclonal antibodies. Soil Biol. And Biochem., 1992, 24(5):399~403.
Schmid A and Buchala AJ. An examination of the growth substance activity of vitamin D3. J. Plant Growth Regul., 1987, 5:175~180.
Swift M J. Transaction of 15th World Congress of soil Science. 1994, Vol. 4b.
Weller D. M.1998. Biological control of soil-become plant pathhogene in the rhizosphere with bacteria. Ann. Rev. Phytopathol. ,1988,26: 397~407.
Yong et al PGPR: Is there a relationship and the stimulation of plant growth or biological activity? Bulletin-SROP. 1991,14(8): 182~186.
曹仁林,贾晓葵.我国集约农业中氮污染问题及防治对策[J].农业环境保护,2001(3).
曹志洪.科学施肥与我国粮食安全保障[J].土壤,1998,2:57~63,69.
陈利根.我国耕地资源可持续利用研究[J].生态农业研究,1999,7(1):28~31.
陈琼贤等.有机肥料和无机肥料对土壤微量元素含量的影响[J].热带亚热带土壤科学,1997,6(4):235~238.
陈廷伟等.我国微生物肥料发展趋向[J].土壤肥料,1995(6):16~19.
陈文新.土壤和环境微生物学[M].北京:中国农业大学出版社,1990.
陈晓斌,张炳欣.植物根围促生细菌 (PGPR)作用机制的研究进展[J].微生物杂志,2000,20(1):38~41,44.
陈新宏.小麦顶三叶与粒重关系的研究初报[J].西北农林科技大学学报,2002,30(4):6~8.
褚天铎.澄清化肥使用中的几个问题[J].土壤肥料,1997,5.
葛诚.微生物有料概述[J].土壤肥料,1993,(8):43~47.
顾锡江.夏玉米高产栽培技术研究[J].玉米科学,1997,5(1):50~53.
胡承孝.氮素水平对蔬菜品质的影响[J].土壤肥料,1996(3):34~36.
胡雪峰,王效举.农业生产与土壤变化[J].热带亚热带土壤科学,1998,7(1):64~67.
黄昌勇.土壤学[M].北京:中国农业出版社,2000.
金善宝.中国小麦学[M],北京:中国农业出版社,1996.
靳贤福.水资源存在问题及对策[J].甘肃农业,2001(1):20~22.
康白.微生态学[M].大连:大连出版社,1988.
寇长林,王永岐等.施肥结构对砂质潮土中微量元素空间变化的影响[J].土壤通报,2001,2,32(1).
赖庆旺等.无机肥连施对红壤性水稻有机质消长的影响[J].土壤肥料,1991(1):3~7.
李纯忠等.我国耕地土壤生产潜力分析[J].土壤肥料,1996(1):1~5.
李登武等.施钾和AM真菌对考烟产量和品质的影响[J].西北农林科技大学学报(自然科学版),2002,30(5):63~68.
李东风.光合细菌的开发应用动态[J].微生物学杂志,1998,2(18):44~50.
李芳柏,廖宗文.试论我国有机无机肥料的配合使用[J].热带亚热带土壤科学,1996,5(3):167~172.
李生秀.植物营养与肥料科学的现状与发展[J].植物营养与肥料学报,1999,5(3):193~250.
李维炯,倪永珍.EM(有效微生物群)的研究与应用[J].生态学杂志;1995,14(5):58~62.
李星洪等.花生施用微物肥的作用和增产效果初探[J].土壤肥料,1998(2):35~37.
林葆,林继雄,李家康.长期施肥的作物产量和土壤肥力变化[J].植物营养与肥料学报,1994,9(1):6~18.
林成谷.土壤学[M].北京:农业出版社,1983.
刘更另等.中国有机肥料[M].北京:农业出版社,1991.
刘经荣.水稻土有机无机肥料配合的效应[J].江西农业大学学报,1990,12(1):37~42.
刘丽生等.生物肥料的作用特点和发展趋势[J].黑龙江农业科学,2001(5):30~31.
刘丽丽等.津农菌肥对水果糖度和着色度的影响[J].天津农业科学,1995,1(3):17~18.
刘玉凯.整治农业生态环境刻不容缓[J].农村生态环境,2002,18(2):47~49.
吕殿青,同延安,孙本华.氮肥施用对环境污染影响的研究[J].植物营养与肥料学报,1998,4(1):8~15.
毛知耘.肥料学[M].北京:中国农业出版社,1995.
孟旭光.我国国土资源安全面临的挑战及对策[J].中国人口、资源与环境,2002,12(1):47~50.
倪永珍,李维炯.EM技术应用研究[M].北京:中国农业大学出版社,1998.
潘超美等.VA菌根真菌对玉米生长及根际微生态环境的影响[J].土壤与环境,2000,9(4):304~306.
彭运生,刘恩.关于提取叶绿素方法的比较研究[J].北京农业大学学报,1992,18(3):247~248.
彭可珊.我国粮食生产可持续发展问题的再认识[J].国土与自然资源研究,1998,12(3):10~14.
仇志华等.施用阿姆斯生物肥土壤养分的变化研究[J].中国农学通报,1999,15(4):59~60.
任祖淦,陈玉水等.有机肥料配施对土壤微生物和酶活性的影响[J].植物营养与肥料学报,1996,2(3):279~283.
司友斌等.农田氮磷的流失与水体富营养化[J].土壤,2000,8,32(4):188~193.
单玉珊等.小麦高产栽培技术原理[M].2001,6.
沈景文.化肥农药和污灌对地下水的污染[J].农业环境保护,1992,11(3):137~139.
沈其荣.土壤肥料科学通论[M].北京:高等教育出版社.
沈中泉,郭云桃,袁家富.有机肥料对改善农产品品质的作用及机理[J].植物营养与肥料学报,1995,1(2):54~59.
宋秀杰.我国有机肥利用现状及合理利用的技术措施[J].农村生态环境,1997,13(2):56~59.
宋玉清,马麟祥.生物肥料在辽宁省的应用[J].微生物学杂志,1994,14(1):49~51.
孙波等.土壤质量与持续环境Ⅲ.土壤质量评价的生物学指标[J].土壤,1997(5):225~234.
唐勇等.解磷微生物及其应用的研究进展[J].中国农业科学,1995,1(2):41~43.
同小娟.中国农业大学硕士论文,2001.
汪建飞,邢素芝.农田土壤施肥的负效应及其防治对策[J].农业环境保护,1998,17(1):40~43.
王庆仁等.论合理施肥与土壤环境可持续发展[J].环境科学进展,1999,7(2):116~123.
王朝辉,李生秀,田霄鸿.不同氮肥用量对蔬菜硝态氮积累的影响[J].植物营养与肥料学报,1998,4(1):22~28.
王慧中.有机菌肥在马铃薯上的应用[J].江西农业学报2002,14(1):41~43.
王经武等.小麦[M].科学普及出版社,1983.
王世敬等.春小麦籽粒灌浆生理与提高粒重措施的研究[J],宁夏农学院学报,1992,
韦鹤平.环境系统工程[M].上海:同济大学出版社,1993.
魏辉.生物有机无机复合肥的研制与效果研究[J].微生物学杂志,1997,17(3):18~24.
吴波,卢琦.我国荒漠化基本特点及加快荒漠化地区发展的意义[J].中国人口、资源与环境,2002,12(1):99~101.
吴同彦等.小麦株高构成因素与产量及其他性状相关性的研究[J].河北农业大学学报,2002,25(3):10~12.
吴绍騤 等.玉米裁培生理[M].上海:上海科技出版社,1980.
夏荣基等.土壤和肥料基础知识[M].北京:农业出版社,1981.
解金瑞译自 等.No.4,16~18,1992.
赵景逵校.
谢明杰,程爱华,曹文伟.我国微生物肥料的研究进展及发展趋势[J].微生物学杂志,2000,20(4):42~45.
徐恒立,赵君实.高产冬小麦的冠层光合能力及不同器官的贡献[J].作物学报,1995(2):204~209.
徐谦.我国化肥和农药非点源污染状况[J].农村生态环境,1996,12(2):39~43.
许前欣,孟兆芳,于彩虹.微生物肥料农业应用的效益评价[J].天津农业科学,2000,6(2):44~46.
杨林书等.秸秆资源化考略[J].农业环境保护,1993,12(6):271~273,283.
杨文钰,王兰英.作物秸秆还田的现状与展望[J].四川农业大学学报,1999,17(2):211~216.
杨佑兴.倾听巢湖诉说[N].中国环境报,1996年9月10日.
杨玉爱.我国有机肥料研究及展望[J].土壤学报,1996,33(4):414~418.
于彩虹等.生物菌肥对蔬菜品质的影响[J].天津农业科学,2000,6(2):20~22.
于振文等.黄淮麦区冬小麦超高产栽培的理论与实践[J].作物学报,2002,28(5):577~585.
曾广骥等.有机肥提高作物产品品质作用初探[J].黑龙江农业科学,1990(2):10~15.
曾希柏等.农业农用化学品对工农业生态环境的影响及其防治[J].科技导报,2000(4):52~54,59.
占新华,蒋延惠,徐阳春等.微生物制剂促进植物生长机理的研究进展[J].植物营养与肥料学报,1999,5(2):97~105.
张道勇等.中国实用肥料学[M].上海:上海科学技术出版社,1997.
张夫道.氮素营养研究中几个热点问题[J].植物营养与肥料学报,1998,4(4):331~338.
张辉,李维炯,倪永珍等.生物有机无机复合肥效应的初步研究[J].农业环境保护,21(4):352~356.
张晶心.微生态制剂与农业环境保护[J].农业环境保护,1994,13(2):81~83.
张锐,严慧峻,魏由庆等.有机肥在改良盐渍土中的作用[J].土壤肥料,1997(4):11~14.
张维理,田哲旭,张宁等.我国北方农用氮肥造成地下水硝酸盐污染的调查[J].植物营养与肥料学报,1995,1(2):80~87.
张宪政.作物生理研究法[M].北京:农业出版社,1995.
张新明,李华兴,吴文良.氮素肥料对环境与蔬菜的污染及其合理调控途径[J].土壤通报,2002,33(6):471~473.
张玉革等.长期施肥对土壤水分特性影响的研究[J].土壤1999,3:120~125.
张玉先,余国锋等.不同培肥方式对黑土肥力持续效应影响的研究Ⅰ.土壤氮素持续效应[J].黑龙江八一农垦大学学报,2002,13(1):12~16.
赵可夫.玉米生理[M].山东:山东科学技术出版社,1982.
郑长英.施用EM堆肥对土壤螨群落结构的影响[J].生态学报,2002,22(7):1116~1121.
中国农业持续发展和综合生产力研究组.中国农业持续发展和综合生产力研究[M].山东:山东科学技术出版社,1995.
中国农业科学院.小麦栽培理论与技术[M].北京:农业出版社,1979.
中国农业科学院土壤肥料研究所.中国肥料[M].上海:上海科学技术出版社,1994.
朱兆良.农田氮肥的损失与对策[J].土壤与环境,2000,9(1):1~6.
周卫军,王凯荣.不同农业施肥制对红壤稻田土壤肥力的影响[J].热带亚热带土壤科学,1997,6(4):231~234.
Alexander, Soberer. Use of chrome azure S reagents to evaluate siderophore production by photosphere bacteria. Biol. And Fertility of soils, 1991, 12(1): 39~45.
Bay A M et al. Vitamin production in relation to phosphate volatilization by soil bacteria, Soil Biol. Brioche., 1981, 13:527~531.
Brito DE, Alvarez, Gagne, Antoun. Effect of compost on photosphere micro flora of the tomato and on the incidence of plant-growth-promoting rhizobacteria. Applied and Environ. Microbial. ,
1995,61(1): 194~199.
Cooper R. Bacterial fertilizers in Soviet Union. Soils anti fertilizer, 1959,22(5): 327~333.
Duijff, De Kogel, Bakker, Schippers. Infirence of pseudobactin 358 on the iron nutrition of barley. Soil Biol. Biochem., 1994, 26(12):1681~1688.
Elazar Fallik and Yaacov Okon. Indentification and quantification of IAA and IBA in Azospirillum brasilense-inoculated maize roots. Soil Biol. Biochem., 1989,21(1): 147~153.
Grayston, Germida. Sulfur-oxidizing bacteria as plant growth promoting rhizobaceria for canola. J. of Microbiol., 37(7):521~529.
Gonzalez-Lopez J et al. Amino acids and vitamins procueed by Azotobacter vinelandii atcc 12837 in chemically-defined media and dialysed soil media. Soil Biol. Biochem., 1983, 115(6):711~713.
Gruen H E. Auxins and fungi, Annu. Rev. plant physiol., 1959(1): 405~440.
Hussain A, Arsshad M, Hussain A and Hussain E Response of maize(Zea mays) to azotobacter inoculation under fertilized and unfertilized conditions. Biol. Fertil. Soil, 1987, 4: 73~77.
Ikram. Beneficial soil microbes and crop productivity. Planter, 1996, 66(7):640~648.
Koda Y, Takahashi K and Kikuta Y. Potato tuber-inducing activities of salieylic acid and related compounds. J. Plant Growth Regul., 1992, 11: 215~219.
Leslie CA and Romani RJ. Inbibition of ethykene biosynthesis by salicylic acid. Plant Physiol., 1988, 88: 833~837.
M.A.Mcmahon. Fertilizer use and environmental impact, Agro-chemicals News in Brief, 1995 Vol Ⅹ Ⅷ, No.4, Marumoto T, Anderson J P, Domsch K H. Mineralization of nutrients from soil microbial biomass. Soil Biol & Biochem, 1982, 14: 469~475.
Marschner, Ascher, Graham. Effect of manganese- reducing rhizosphere bacteria on the growth of Gaeuman-nomyees graminis var. critic and on manganese uptake by wheat (Tritium festive L.). Biol. And Fertility of Soils, 1991,12(1) 33~38.
Muhammad arched and Frankenberger WT Jr. Microbial prodrction of plant hormones. Plant and Soil, 1991, 133:1~8.
Nieto K F and Frankkenberger WT Jr, Biosynthesis of cytokinins prodrced by Azotobater chroococcum, Soil Biol. & Biochem., 1989(21): 967~972.
Schloter, Bode, Hartmann, Beese. Sensitive chemolumine-scence-based immunologiacal quantification of bacteria of bacteria in soil extracts with monoclonal antibodies. Soil Biol. And Biochem., 1992, 24(5):399~403.
Schmid A and Buchala AJ. An examination of the growth substance activity of vitamin D3. J. Plant Growth Regul., 1987, 5:175~180.
Swift M J. Transaction of 15th World Congress of soil Science. 1994, Vol. 4b.
Weller D. M.1998. Biological control of soil-become plant pathhogene in the rhizosphere with bacteria. Ann. Rev. Phytopathol. ,1988,26: 397~407.
Yong et al PGPR: Is there a relationship and the stimulation of plant growth or biological activity? Bulletin-SROP. 1991,14(8): 182~186.