[1] 马越强,廖利平,杨跃军,等.香草醛对杉木幼苗生长的影响[J],应用生态学报,1998,9(2):128~132 [2] 王大力.全球CO2浓度变化与植物的化感作用[J].生态学报,1999,19(1):122~127. [3] 乐教全,郑师章.凤眼莲根际细菌的趋化性研究[J].复旦学报(自然科学版),1990,29(3):314~319 [4] 安保珠,王俊儒,赵效文.小麦、油菜、荞麦根分泌物中非极性和弱极性组分的比较研究[J].西北农业大学学报,1995,23(3):31~35. [5] 刘芷宇,李良漠,施卫明.根际研究法[M].南京:江苏科学技术出版社,1997. [6] 何绍江,毛新国,李传涵.菌根化杉树苗抗酚能力的研究[J].湖北农学院学报,1999,19(2):107~109 [7] 宋勇春,冯固,李晓林.泡囊丛枝菌根对三叶草根际土壤磷酸酶活性的影响[J].应用与环境生物学报,2000,6(2):171~175 [8] 李振高,李良谟,潘映华,等.小麦苗期根系分泌物对根际反硝化细菌的影响[J].土壤学报,1995,32(4):408~413. [9] 陈楚莹,廖利平,汪思龙.杉木人工林生态学[M].北京:科学出版社,2000 [10] 范俊岗,范国儒.植物根系分泌及其在林业中的意义[J].植物研究,1995,15(2):246~251 [11] 林琦,郑春荣,陈怀满.根际环境中镉的形态转化[J].土壤学报,1998,35(4):461~467. [12] 陆文龙,王敬国,曹一平,等.低分子量有机酸对土壤磷释放动力学的影响[J].土壤学报,1998,35(4):493~500 [13] 罗明,陈新红,李兢,等.种保素对几种根际微生物效应的影响[J].生态学杂志,2000,19(3):69~72 [14] 张宝琛,白雪芳,顾立华,等.主化他感作用与高寒草甸上人工草场自然退化现象的研究[J].生态学报,1989,9(2):115~120. [15] 张福锁.根分泌物及其在植物营养中的作用Ⅰ.缺锌对双子叶植物根系分泌物的影响[J].北京农业大学学报,1991,17(2):63~67 [16] 张福锁,曹一平.根际动态过程与植物营养[J].土壤学报,1992,29(3):239~250. [17] 张福锁,等.环境胁迫与植物根际营养[M].北京:中国农业出版社,1997 [18] 赵大君,郑师章.凤眼莲根分泌物氨基酸组分对根际肠杆菌属F2细菌的趋化作用[J].应用生态学报,1996,7(2):207~212 [19] 赵大君,郑师章.无菌凤眼莲根分泌物组分分析[J].复旦学报(自然科学版),1996,35(2):177~182 [20] 胡锋,李辉信,史玉英,等.两种基因型小麦根际土壤生物动态及根际效应[J].土壤通报,1998,29(3):133~135 [21] 徐秋芳.马尾松根际土壤化学性质分析[J].浙江林学院学报,1998,15(2):122~126 [22] 高子勤,张淑香.连作障碍与根际微生态研究Ⅰ.根系分泌物及其生态效应[J].应用生态学报,1998,9(5):549~554 [23] 涂书新,孙锦荷,郭智芬,等.植物根系分泌物与根际营养关系评述[J].土壤与环境,2000,9(1):64~67 [24] 常学秀,段昌群,王焕校.根分泌作用与植物对金属毒害的抗性[J].应用生态学报,2000,11(2):315~320 [25] 曾任森,林象联.蟛蜞菊根系分泌物的异种克生作用及初步分离[J].生态学杂志,1994,13(1):51~56 [26] 切尔诺布里维卡,C.H.植物分泌物的生物学作用和间作中的种间相互关系[M].北京:科学出版社,1961 [27] Ayers, W.A. et al. Exudation of amino acids by intact and damaged roots of wheat and peas[J]. Plant and Soil, 1968, 28:193~207. [28] Delhaize, E. and Ryan, P. R. Aluminum toxicity and tolerance in plants[J]. Plant Physiol., 1995,107: 315~ 321. [29] Elroy, A. C. The Rhizosphere[M]. Berlin: Heidelber Spring-Verlag,1986. [30] Gregory, P. J and Hinsinger. P. New approaches to studying chemical and physical changes in the rhizosphere: an overview [J]. Plant and Soil, 1999, 211: 1 ~ 9. [31] Killham, K. Soil Ecology[M]. Cambridge: Cambridge University Press, 1994. [32] Koeppe, E. D. E. et al. The relationship of tissue chlorogenic acid concentrations and leaching of phenolics from sunflowers grown under varying phosphates nutrient conditions [J]. Canad. J.Bot., 1976, 54: 593 ~ 599. [33] Kraffczyk, I. et al. Soluble root exudates of maize: influence of potassium supply and rhizosphere microorganisms[J]. Soil Biol.Biochem., 1984, 16: 315~ 322. [34] Lynch, J.M. and Whipps, J. M. Substrate flow in the rhizosphere[J]. Plant and Soil, 1990, 129:1~10. [35] Jane, F.J. et al. Phosphorus deficiency in Lupinus albus Altered lateral root development and enhanced expression of phosphoenolpyruvate carboxylase[J]. Plant Physiol., 1996, 112:31~41. [36] Materechera, S. A. et al. Formation of aggregates by plant roots in homogenised soils[J]. Plant and Soil, 1992, 142:69~79. [37] Mori, S. et al. Dynamic state of mugineic acid and analogous phytosiderophores in Fe deficient barley [J]. J. Plant Nutr.,1987, 10:1003~ 1011. [38] Neumann, G. et al. Physiological adaptations to phosphorusdeficiency during proteoid root development on white lupin [J].Planta, 1999, 208:373 ~382. [39] Norby, R.J. et al. Carbon allocation, root exudation and mycorrhizal colonization of Pinus echinata seedlings grown under CO2 enrichment[J]. Tree Physiol., 1987, 3: 203~ 210. [40] Oades, J. M. Mucilages at the root surface[J]. J. Soil Sci.,1978,29:1~16. [41] Patterson, D. T. Effect of allelopathic chemicals on growth and physiological restponses of soybean ( Glycine ax ) [J]. Weed Sci., 1981,29(1) :53~58. [42] Pellet, D. M. et al. Organic acid exudation as an aluminum-toler-ance mechanism in maize(Zea mays L. )[J]. Planta, 1995,196:788~795. [43] Rovira, A. D. et al. Plant root exudates[J]. Bot. Rev., 1969, 35~57. [44] Schoenwitz, R. and Ziegler, H. Exudation of water-souble vitamins and of some carbohydrates by intact roots of maize seedlings (Zea mays L. ) into a mineral nutrient solution [J]. Z.Pflanzenphysioe, 1982, 107: 7 ~ 14. [45] Tang, C. S. et al. Collection and identification of allelopathic com pounds from the undisturbed root system of bigatta limpograss ( Hemarthria altissima ) [J ]. Plant Physiol., 1982, 69:155 ~ 160. [46] Tyler, G. and Strom, L. Differing organic acid exudation pattern explains calcifuge and acidifuge behavior of plants [J ]. Ann.Bot., 1995, 75: 75~ 78. [47] Vancura, V. Root exudates of plants[J]. Plant and Soil, 1964,21:231~248. [48] Yu, J. Q. and Matsui, Y. Effects of root exudates of cucumber (Cucumis sativus) and allelochemicals on ion uptake by cucumber seedlings[J]. J. Chem. Ecol., 1997, 23 (3): 817 ~ 827. [49] Zhang, F. S. et al. Release of zine mobilizing root exudates in different plant species as affected by zinc nutritional status [J]. J.Plant Nutr., 1991.14(7):675~686. |