生长期紫穗槐植株的含水量及营养结构特征
|
摘要
植物的养分含量既是植物在一定环境条件下吸收营养元素的能力表现,又是生态系统营养循环的一个组成部分。为了探明紫穗槐植株的含水量以及营养结构特征,测定了生长季(6-9月)紫穗槐的组织含水量,叶以及不同径级根、不同径级茎的10种养分(有机碳、N, P、 K、 Ca、Mg、Fe、 Mn、 Cu、 Zn)含量。主要结果如下:
1.紫穗槐的鲜干比随生长时间逐渐减小,生长初期鲜干比高,适口性较好,刈割宜作青饲料或与禾草混作青贮料;生长后期鲜干比低,刈割宜晒制干草。茎叶比随生长时间逐渐增大,生长初期紫穗槐的茎叶比小,叶片的比例高,营养物质较多,适口性较强,品质也较好;生长后期茎叶比大,叶片的比例小,营养物质减少,适口性以及品质稍差。
2.生长季紫穗槐的茎、叶含水量与各土层土壤含水量之间均呈不显著的负相关关系,且紫穗槐单株地上茎、叶以及总生物量与各土层土壤含水量之间均呈显著的负相关性,表明紫穗槐具有很强的吸水、保水性,因此具有较强的抗旱性,是西北干旱、半干旱地区适宜发展的优良灌木。
3.根和茎的N、P、K含量与径级呈典型逆相关关系,即随着径级的增大养分含量减少,含量最高的部位集中于叶以及小径级的根、小径级的茎。生长季紫穗槐叶片的C、 N.、Ca、Mn、 Cu含量高于根和茎,叶中大量元素的含量顺序为C>N>K>Ca>Mg>P,微量元素为Fe>Mn>Zn>Cu。
4.紫穗槐对Zn的选择性吸收能力最强,吸收系数达745.00,其次为Mn,吸收系数为216.61,对其他元素的选择性吸收能力顺序为:Zn>Mn>C>Fe>N>Cu>P。虽然土壤中各种营养元素的含量很低,但紫穗槐通过这种很强的吸收或富集作用使植株中各种营养元素的含量维持在较高的水平,既能满足自身正常生长发育的需要,同时又提高了对瘠薄环境的适应性。
5.土壤含水量的下降,有利于紫穗槐对钙、镁的吸收富集,不利于紫穗槐对氮、磷、钾、铁、锌和铜元素的吸收富集,其中对铁、锌元素的不利影响较小。
Nutrient content of plant not only can reflect absorption capacity of the nutritional elements under certain environmental conditions, but also is an integral part of the nutrient cycling. The aim was to investigate water content of stem and leave and the nutrient structure of Amorpha fruticosa. The water content and nutrient content of leaf, the stem and root of different diameter of Amorpha fruticosa in growing season was studied. C, N, P, K, Ca, Mg, Fe, Mn, Cu and Zn were analysed, several important conclusions can be drawn from this study.
1. the GW/DW ratio was higher and Amorpha fruticosa was suitable for green fodder in early growth stages. The GW/DW ratio was lower and Amorpha fruticosa was suitable for hay in late growth stages. The stem/leaf ratio increased month by month and was from0.74in early June to1.71in early September. The stem/leaf ratio of Amorpha fruticosa was lower in early growth stages, so it had high proportion of leave and more nutrients and good palatability. In other words, the quality of Amorpha fruticosa was good in early growth stages. The stem/leaf ratio of Amorpha fruticosa was higher in late growth stages, so it had low proportion of leave and less nutrients and bad palatability. In other words, the quality of Amorpha fruticosa was bad in late growth stages.
2. stems、 leaves and total biomass per plant above ground showed a significant negative correlation with soil moisture content at different depths. Water content of stems and leaves showed a negative correlation with soil moisture content at different depths. The above reresults showed that the plant of Amorpha fruticosa had a strong water absorption and water holding capacity and drought resistance, the plant of Amorpha fruticosa was suitable for development in northwest arid and semiarid areas.
3. The nutrient content of N, P and K had an opposite relationship with diameter of stem and root. In other words, the nutrient content reduced with the increase of the diameter. The site of the highest content was leaf, the stem and root of thin diameter. There was more organic carbon, N, Ca, Mn and Cu in leaf than in stem and root of Amorpha fruticosa in the whole growth season. The order of macroelement content in leaf was C>N>K>Ca>Mg>P and the order of trace element content in leaf was Fe>Mn>Zn>Cu.
4. The selective absorption capacity of the Zn was strongest. Absorption coefficient of Zn was745.00. The selective absorption capacity of the Mn was stronger. Absorption coefficient of Mn was216.61. The order of selective absorption capacity of elements was Zn>Mn>Fe>N >Cu>P. Although various elements content was low in soil, it maintained a high level in Amorpha fruticosa to meet its normal growth and development needs by a strong absorption or accumulation ability.The adaptability of the barren environment was improved at the same time.
5. The decline of soil moisture was helpful for enrichment of calcium and magnesium. The decline of soil moisture was not helpful for enrichment of nitrogen、 phosphorus、 potassium、iron、 zinc and copper. The adverse effect on iron and zinc was smaller.
1.紫穗槐的鲜干比随生长时间逐渐减小,生长初期鲜干比高,适口性较好,刈割宜作青饲料或与禾草混作青贮料;生长后期鲜干比低,刈割宜晒制干草。茎叶比随生长时间逐渐增大,生长初期紫穗槐的茎叶比小,叶片的比例高,营养物质较多,适口性较强,品质也较好;生长后期茎叶比大,叶片的比例小,营养物质减少,适口性以及品质稍差。
2.生长季紫穗槐的茎、叶含水量与各土层土壤含水量之间均呈不显著的负相关关系,且紫穗槐单株地上茎、叶以及总生物量与各土层土壤含水量之间均呈显著的负相关性,表明紫穗槐具有很强的吸水、保水性,因此具有较强的抗旱性,是西北干旱、半干旱地区适宜发展的优良灌木。
3.根和茎的N、P、K含量与径级呈典型逆相关关系,即随着径级的增大养分含量减少,含量最高的部位集中于叶以及小径级的根、小径级的茎。生长季紫穗槐叶片的C、 N.、Ca、Mn、 Cu含量高于根和茎,叶中大量元素的含量顺序为C>N>K>Ca>Mg>P,微量元素为Fe>Mn>Zn>Cu。
4.紫穗槐对Zn的选择性吸收能力最强,吸收系数达745.00,其次为Mn,吸收系数为216.61,对其他元素的选择性吸收能力顺序为:Zn>Mn>C>Fe>N>Cu>P。虽然土壤中各种营养元素的含量很低,但紫穗槐通过这种很强的吸收或富集作用使植株中各种营养元素的含量维持在较高的水平,既能满足自身正常生长发育的需要,同时又提高了对瘠薄环境的适应性。
5.土壤含水量的下降,有利于紫穗槐对钙、镁的吸收富集,不利于紫穗槐对氮、磷、钾、铁、锌和铜元素的吸收富集,其中对铁、锌元素的不利影响较小。
Nutrient content of plant not only can reflect absorption capacity of the nutritional elements under certain environmental conditions, but also is an integral part of the nutrient cycling. The aim was to investigate water content of stem and leave and the nutrient structure of Amorpha fruticosa. The water content and nutrient content of leaf, the stem and root of different diameter of Amorpha fruticosa in growing season was studied. C, N, P, K, Ca, Mg, Fe, Mn, Cu and Zn were analysed, several important conclusions can be drawn from this study.
1. the GW/DW ratio was higher and Amorpha fruticosa was suitable for green fodder in early growth stages. The GW/DW ratio was lower and Amorpha fruticosa was suitable for hay in late growth stages. The stem/leaf ratio increased month by month and was from0.74in early June to1.71in early September. The stem/leaf ratio of Amorpha fruticosa was lower in early growth stages, so it had high proportion of leave and more nutrients and good palatability. In other words, the quality of Amorpha fruticosa was good in early growth stages. The stem/leaf ratio of Amorpha fruticosa was higher in late growth stages, so it had low proportion of leave and less nutrients and bad palatability. In other words, the quality of Amorpha fruticosa was bad in late growth stages.
2. stems、 leaves and total biomass per plant above ground showed a significant negative correlation with soil moisture content at different depths. Water content of stems and leaves showed a negative correlation with soil moisture content at different depths. The above reresults showed that the plant of Amorpha fruticosa had a strong water absorption and water holding capacity and drought resistance, the plant of Amorpha fruticosa was suitable for development in northwest arid and semiarid areas.
3. The nutrient content of N, P and K had an opposite relationship with diameter of stem and root. In other words, the nutrient content reduced with the increase of the diameter. The site of the highest content was leaf, the stem and root of thin diameter. There was more organic carbon, N, Ca, Mn and Cu in leaf than in stem and root of Amorpha fruticosa in the whole growth season. The order of macroelement content in leaf was C>N>K>Ca>Mg>P and the order of trace element content in leaf was Fe>Mn>Zn>Cu.
4. The selective absorption capacity of the Zn was strongest. Absorption coefficient of Zn was745.00. The selective absorption capacity of the Mn was stronger. Absorption coefficient of Mn was216.61. The order of selective absorption capacity of elements was Zn>Mn>Fe>N >Cu>P. Although various elements content was low in soil, it maintained a high level in Amorpha fruticosa to meet its normal growth and development needs by a strong absorption or accumulation ability.The adaptability of the barren environment was improved at the same time.
5. The decline of soil moisture was helpful for enrichment of calcium and magnesium. The decline of soil moisture was not helpful for enrichment of nitrogen、 phosphorus、 potassium、iron、 zinc and copper. The adverse effect on iron and zinc was smaller.
引文
[1]白志英,张林萍.关于紫穗槐花序类型的探讨[J].河北林果研究,1998,13(3):1.
[2]卞禄,谢宝东,吴峰.不同香樟单株含水量及抗寒性差异分析[J].林业科技开发,2009,23(3):77-79.
[3]常杰,葛滢.羊草群落主要营养元素吸收相关性分析[J].植物学通报,1995,12(生态学专辑):136-141.
[4]曹文侠,张德罡,洪绂曾.祁连山高寒灌丛草地杜鹃属植物的水分动态及生态适应[J].草地学报,2006,14(1):67-71.
[5]曹小艳,李小进.微量元素对农产品品质的影响[J].安徽农学通报,2007,13(17):212.
[6]柴凤久,刘崇生,罗新义,李红,王凤国.苜蓿引种筛选试验初报[J].草业科学,2005,22(4):36-39.
[7]陈灵芝.北京人工刺槐林化学元素含量特征[J].植物生态与地植物学学报,1988,12(4):245-254.
[8]陈有君.内蒙古浑善达克沙地土壤水分状况的分析[J].干旱区资源与境,2000,14(1):80-85.
[9]刁乃宏.种植紫穗槐防止水土流失效益显著[J].黑龙江水利科技,2006,34(5):120.
[10]董丽,路艳红.常绿阔叶植物越冬期间叶片水分及淀粉粒的动态变化[J].北京林业大学学报,2002,5(6):76-80.
[11]杜桂娟,刘晓宏,侯志研,李启辉,马凤江,张鹏.紫花苜蓿品种比较与性状分析初报[J].草业科学,2005,22(9):45-48.
[12]杜前进,张永发,曾宾,等.海南富硒地区水稻富硒品种的筛选[J].中国土壤与肥料,2009,1:46-49.
[13]杜占池,樊江文,钟华平.红三叶和鸭茅化学元素的生物吸收能力研究[J].草业学报,
2008,17(2):47-53.
[14]方运霆,莫江明,周国逸,等.鼎湖山南亚热带常绿阔叶林植物和土壤微量元素含量[J].广西植物,2005,25(6):504-510.
[15]冯金朝,刘新民.干旱环境与植物的水分关系[M].北京:中国环境科学出版社,1998:208-211.
[16]冯锐,刘九庆.利用微波法测量植物叶片含水量[J].林业机械与木工设备,2009,37(2):47-48.
[17]冯宗炜.亚热带杉木纯林生态系统中营养元素的积累、分配和循环的研究[J].植物生态与地植物学丛刊,1985,9(4):245-256.
[18]伏建增,杜汉强,牛一川,等.紫花苜蓿品种抗旱性研究分析[J].草原与草坪,2006,115(2):65-67.
[19]付华,周志宇,陈善科.腾格里沙漠东南缘飞播区白沙蒿植被密度与土壤水分关系的研究[J].中国沙漠,2001,21(3):265-269.
[20]高彩霞,王培.收获期和干燥方法对苜蓿干草质量的影响[J].草地学报,1997,5(2):113-116.
[21]高洪波,陈贵林.钙调素拮抗剂与Ca2+对茄子幼苗抗冷性的影晌[J].园艺学报,2002,29(3):243-246.
[22]龚明,杜朝昆,许文忠.钙和钙调素对玉米幼苗抗旱性的调控[J].西北植物学报,1996,16(3):214-220
[23]谷小军.重提紫穗槐利国又利民[J].水土保持科技情报,2005,(2):48-49.
[24]顾振瑜,胡景江,文建雷.元宝枫对干旱适应性的研究[J].西北林学院学报,1999,14(2):1-6.
[25]管东生,罗琳.海南热带植物叶片化学元素含量特征[J].林业科学,2003,39(2):28-32.
[26]郭惠清,田有亮.杨幼树水分生理指标和光合强度与土壤含水量关系研究[J].干旱资源与环境,1998,12(2):101-106.
[27]郭卫华,李波,黄永梅.不同程度的水分胁迫对中间锦鸡儿幼苗气体交换特征的影响[J].生态学报,2004,24(12):2-16.
[28]韩玉林,黄苏珍,孙桂弟.5种鸢尾属观赏地被植物的抗旱性研究[J].江苏农业科学,2007,(2):79-81.
[29]何念鹏,周道玮,吴冷.极端干旱干扰下松嫩草原土壤含水量与植物的反映[J].干旱区资源与环境,2001,15(3):52-56.
[30]何维明.水分因素对沙地柏实生苗水分和生长特征的影响[J].植物生态学报,2001,25(1):11-16.
[31]侯学煜.中国植被地理及优势植物化学成分[M].北京:科学出版社,1982.316-321.
[32]候学煜.中国150种植物的化学成分及其分析方法[M].北京:高等教育出版社,1959.
[33]胡娟,邱慧珍,何秀成,等.施钾水平对甘肃烤烟钾含量及经济效益的影响[J].草业学报,2010,19(5):156-160.
[34]华东师范大学生物系植物生理教研组.植物生理学实验指导[M].上海:高等教育出版社,1980:10-17.
[35]黄明丽,邓西平,白登忠,等.N、P营养对旱地小麦生理过程和产量形成的补偿效应研究进展[J].麦类作物学报,2002,22(4):74-78.
[36]黄伟生,彭佩钦,黄道友,等.洞庭湖区不同土地利用方式耕作土壤氮素含量与循环[J].中国生态农业学报,2007,15(4):49-52.
[37]简令成,王红.钙在植物抗寒中的作用[[]].细胞生物学杂志,2002,24(3):166-171.
[38]姜永诰.发展紫穗槐产业的分析[[]].安徽农业科学,2007,35(1):98-151.
[39]姜勇,张玉革,梁文举.耕地土壤中交换态钙镁铁锰铜锌相关关系研究[[]].生态环境,2003,12(2):160-163.
[40]蒋式洪,何云峰.作物镁素营养与镁肥应用前景[J].化肥工业,1994,21(1):17-18,23.
[41]焦树仁.辽宁章古台樟子松人工林的生物量与营养元素分布的初步研究[J].植物生态与地植物学丛刊,1985,9(4):257-265.
[42]卡德尔·阿不都热西提.干旱胁迫下不同作物品种叶片含水量的测定[J].喀什师范学院学报,2009,30(6):50-53.
[43]刘颖,冯金朝,吴亚丽,等.内蒙古和林格尔地区柠条锦鸡儿生化成分分析[J].干旱区资源与环境,2008,22(9):159-162.
[44]来强,李青丰,莫日根敖其尔,等.草地牧草含水量测定暨干鲜比估测方法研究[J].内蒙古草业,2008,20(3):4-7.
[45]来强,李青丰,莫日根敖其尔,师桂花,吴雪宾.影响牧草含水量测定以及牧草干鲜比的主要因素[J].中国草地学报,2008,30(4):73-77.
[46]雷丽,程星,蔡雄飞.贵州岩溶山区土壤含水量时空分布与植物生长关系研究[J].贵州科学,2009,27(2):50-54.
[47]李德红,王小青,潘瑞炽.钙信使系统与植物激素信号传递[J].生物学杂志,1998,15(4):1-4.
[48]李广德,王晓辉,贾黎明,沈繁宜.国槐枝叶水分特征及其对树干边材液流的影响[J].中南林业科技大学学报,2010,30(1):23-28.
[49]李红丽,董智,王林和.浑善达克沙地流沙与4种主要植物群落土壤水分时空变化的研究[J].干旱区资源与环境,2006,20(3):169-174.
[50]李景梅,鞠殿民.微量元素的生理功能在农业生产中的作用[J].长春光学精密机械学院学报,2001,21(4):61-64.
[51]李俊清,宫伟光.东北主要造林树种的营养元索含量特征分析[J].植物生态与地植物学学报,1991,15(4):380-385.
[52]李明晶,孙华云,刘亦凡.镁在植物生长中的作用及镁肥[J].硫磷设计与粉体工程,2009,(4):36-38.
[53]李文华,刘广权,马松涛,王鸿哲.干旱胁迫对苗木蒸腾耗水和生长的影响[J].西北农林科技大学学报(自然科学版),2004,32(1):61-65.
[54]李文华,吴万兴,张忠良.土壤水分对仁用杏水分和生长特征的影响[J].西北农林科技大学学报(自然科学版),2003,31(4):139-144.
[55]李新虎,赵文杰.银川平原土壤中几种元素有效态与全量相关关系的研究[J].宁夏农林科技,2001,(4):26-28
[56]李志安,彭少麟.我国热带亚热带几种人工林体内营养结构特征[J].生态学杂志,2001,20(4):1-4.
[57]李志安,王伯荪,孔国辉,等.鼎湖山季风常绿阔叶林黄果厚壳桂群落植物元素含量特征[J].植物生态学报,1999,23(5):411~417.
[58]李志安,王伯荪,林永标,等.植物营养转移研究进展[J].武汉植物学研究,2000,18(3):229~236.
[59]李志安,王伯荪,张宏达.关于植物营养生态学[J].生态科学,1999,18(4):43-47.
[60]栗德永,王开曦.太白山植物元素背景值的研究[J].植物生态与地植物学丛刊,1983,7(3):230-239.
[61]廖观荣,钟继洪,郭庆荣.土壤水分对幼龄桉树蒸腾和生长的影响[J].土壤与环境,2001,10(4):285-288.
[62]林厚萱.中国境内酸性土、钙质土和盐渍土植物和指示植物的化学成分[J].土壤学报,1957,5(3):247-267.
[63]林克惠,赵平,祖艳群.微量元素对作物和人体的毒害作用及其控制[J].云南农业大学学报,2002,17(1):94-98.
[64]林秀华,刘传芹,范业春.镁肥对水稻产量及品质的影响研究[J].农业科技通讯,2008,(11):40-41.
[65]刘贵波,乔仁甫.饲用黑麦适宜青刈时期及青刈次数研究[J].草业科学,2005,22(10):47-50.
[66]刘建福,倪书邦,贺熙勇,汤青林.水分胁迫对澳洲坚果叶片矿质元素含量的影响[J].热带农业科,2004,27(1):1-3.
[67]刘任涛,任佳.不同土壤水分条件下翅果油树幼苗生理特性[J].南阳师范学院学报,2005,4(12):59-62.
[68]刘雪云,李晓忠,周志宇,秦或,姜文清,田发益.不同开垦年限西藏草地中量、微量元素含量变化特点[J].中国草地学报,2010,32(6):70-75.
[69]刘颖,李改枝,李晓伟.呼和浩特市和林格尔地区沙棘生化成分分[J].内蒙古师范大学学报(自然科学版),2006,35(4):466-469.
[70]刘颖一,冯金朝,周珊珊,李改枝,范文静,李皎洁.内蒙古和林格尔地区沙地柏生化成分分析[J].内蒙古大学学报(自然科学版),2008,39(4):411-416.
[71]刘振虎,卢欣石.几个紫花苜蓿品种在北京地区引种及适应性评价[J].2004,21(增刊):405-407.
[72]刘忠宽,王艳芬,汪诗平,韩建国,陈佐忠.不同干燥失水方式对牧草营养品质影响的研究[J].草业学报,2004,13(3):47-51.
[73]吕绪清,吕新龙,义如格勒图,等.俄罗斯杂花苜蓿引种栽培试验初报[J].草原与草坪,2008,128(3):52-55.
[74]马红,熊号发,谢雪山,陈继红,杨金勇,熊云祥.多花黑麦草品比试验[J].草业与畜牧,2010(1):16-18.
[75]马丽琼,曹敏建,刘蓓,李必富.不同钾营养效率型玉米品种的苗期生理特性[J].安徽农业科学,2006,34(13):3011-3013.
[76]莫江明,张德强,黄忠良,等.鼎湖山南亚热带常绿阔叶林植物营养元素含量分配格局研究[J].热带亚热带植物学报,2000,8(3):198-206.
[77]牟咏花.钙的生理功能及在果蔬生理中的重要性(综述)[J].浙江农业学报,1995,7(6):499-501.
[78]娜日苏,米福贵.串叶松香草生物学特性及营养成分研究[J].内蒙古草业,2006,18(2):9-11.
[79]南德标,姜同弟.紫穗槐的特征特性与栽培技术[J].现代农业科技,2009,15:211
[80]裴彩霞,董宽虎,范华.不同刈割期和干燥方法对牧草营养成分含量的影响[J].中国草地,2000,(1):32-37.
[81]乔洁,崔秀艳,王君芳,刘卓,李洪涛,马训骏,罗文浩,娄玉杰.土壤水分、氮、磷、钾含量与牧草营养成分的关系[J].饲草与饲,2009,(9):58-59.
[82]乔有明,王振群,段中华.青海湖北岸土地利用方式对土壤碳氮含量的影响[J].草业学报,2009,18(6):105-112.
[83]秦海,李俊祥,高三平,等.中国660种陆生植物叶片8种元素含量特征[J].生态学报,2010,30(5):1247-1257.
[84]任桂霞.紫穗槐水土保持效果浅析[J].农业与技术,2006,26(4):84.
[85]任海彦,郑淑霞,白永飞.放牧对内蒙古锡林河流域草地群落植物茎叶生物量资源分配的影响[J].植物生态学报,2009,33(6):1065-1074.
[86]任伟,周志宇,詹媛媛.阿拉善荒漠灌木根际中、微量元素含量特征[J].生态学报,2009,29(7):3760-3767.
[87]尚爱军,卜耀军,艾海舰,刘翠英,张雄.榆林沙区土壤水分时空格局及动态变化规律研究[J].水土保持学报,2008,22(4):86-89.
[88]宋德荣.施用不同氮肥对牧草和放牧牦牛血液营养元素含量的影响[J].中国草地学报,2010,32(2):42-46.
[89]孙彦,杨青川,张英华.不同草坪草种及品种苗期抗旱性比较[J].草地学报,2001,9(1):16-20.
[90]谭华.氮、磷、钾和密度等因素对玉米产量形成的作用[J].玉米科学,1998,(增刊):93-96.
[91]田德贵,卢克俊,张素华,卞志高,仁青扎西.紫花苗蓿引种试验研究[J].试验研究,(5):19-20.
[92]田晶会,王百田.黄土半干旱区剌槐林水分与生长关系研究[J].水土保持学报,2002,16(5):61-63.
[93]田士林,李莉.香樟在我国中部引种适应性研究[J].安徽农业科学,2006,34(11):2403-2445.
[94]翁凌飞,韩烈保,常智慧,等.重庆庆隆高尔夫球场果岭土壤理化性状测试与分析[J].草业学报,2010,19(4):108-114.
[95]王海.青海东部地区公路边坡灌木栽培技术[J].辽宁林业科技,2009(3):55-56.
[96]王加启,于建国.饲料分析与检验[M].北京:中国计量出版社,2004:40-50.
[97]王建国,贾国兴,冯忠,苏月玲,邓景丽,丁永锋,陈苹.耐水湿、耐盐碱树种造林技术试验[J].宁夏农林科技,1999,(6):34-35.
[98]王奇丽,张垚,白志明,等.不同秋眠性紫花苜蓿品种初冬季节的植物量变化研究[J].草原与草坪,2009,136(5):6-9.
[99]王瑞云,王玉国.钙在植物生理代谢中的作用[J].世界农业,2001,(6):41-43.
[100]王伟,曹敏建,周春喜,李植,张辉.大豆耐低钾胁迫品种(系)的筛选[J].大豆通报,2005,(4):7-8.
[101]王印川.紫穗槐及其经济利用价值[J].山西水土保持科技,2003,(1):21-23.
[102]温肇穆.杉木成熟林乔木层营养元素生物循环的研究[J].植物生态与地植物学学报,1991,15(1):36-45.
[103]吴高潮,王晓娟,吕宁.固氮树种在混交林中的作用[J].福建林业科技,2006,33(3):175-177.
[104]吴婧舒,周广柱,周金峰.平榛抗旱性研究[J].江苏农业科学,2010,(2):196-198.
[105]邢倩,谷艳芳,高志英,丁圣彦.氮、磷、钾营养对冬小麦光合作用及水分利用的影响[J].生态学杂志,2008,27(3):355-360.
[106]熊景发,谢雪山,杨金勇,苏会银,马红,杨永康,熊云祥.夏季青贮饲草品种引种试验[J].草原与饲料,2009,29(6):39-41.
[107]徐安凯,王志峰,于洪柱.吉林省种植苜蓿品种选择研究[J].草业科学,2004,21(增刊):316-322.
[108]颜淑云.紫穗槐幼苗对于干旱胁迫的生理生化响应[D].甘肃:兰州大学,2010.
[109]杨成,刘丛强,宋照亮,等.贵州喀斯特山区植物营养元素含量特征[J].生态环境,2007,16(2):503-508.
[110]杨恒山,曹敏建,范富,等.刈割次数对健宝(Jumbo)产草量及品质的影响[J].中国草地,2003,25(3):28-31.
[111]杨建伟,韩蕊莲,魏宇昆.不同土壤水分状况对杨树、沙棘水分关系及生长的影响[J].西北植物学报,2002,22(3):579-586.
[112]杨建伟,梁宗锁,韩蕊莲.不同土壤水分状况对刺槐的生长及水分利用特征的影响[J].林业科学,2004,40(5):93-98.
[113]杨胜.饲料分析及饲料质量检测技术[M].北京:北京农业大学出版社,1999:34-45.
[114]杨廷良,崔国贤,罗中钦,肖红松.钙与植物抗逆性研究进展[J].作物研究,2004(5):380-384.
[115]余海燕,高红军,王海霞,等.紫穗槐繁殖技术及其应用[J].宁夏农林科技,2010,(6):153.
[116]周志宇,李锋瑞,陈亚明,等.阿拉善荒漠不同密度白沙蒿人工种群生长、繁殖与土壤水分的关系[J].生态学报,2004,24(5):895-899.
[117]曾凡江,张希明,李小明.柽柳的水分生理特性研究进展[J].应用生态学报,2002,13(5):611-614.
[118]张夫道.氮素营养研究中的几个热点问题[J].植物营养与肥料学报,1998,4(4):331-338.
[119]张国君,李云,付元瑞,等.刺槐、柠条和紫穗槐青贮品质的比较[J].西北林学院学报,2009,24(1):151~156.
[120]张杰,贾志宽,韩清芳.不同养分对苜蓿茎叶比和鲜干比的影响[J].西北农业学报,2007,16(4):121-125.
[121]张雷明,上官周平.黄土高原土壤水分与植被生产力的关系[J].干旱区研究,2002,19(4):59-63.
[122]张世绥.盐渍土地区公路边坡的生物防护[J].河北交通科技,2006,3(1):18-20.
[123]张志伟.浅析紫穗槐的利用价值及造林技术[J].安徽农学通报,2009,15(12):164.
[124]中国科学院南京土壤研究所.土壤理化分析[M].上海:科学技术出版社,1978,357-358.
[125]李文西,鲁剑巍,鲁君明,等.苏丹草—黑麦草轮作制中施氮量对饲草产量与土壤氮碳积累的影响[J].草业学报,2011,20(1):55-61.
[126]中国科学院南京土壤研究所微量元素组.士壤和植物中微量元素分析方法[M].北京:科学出版社,1979.
[127]周学辉,苗小林,张继华.青海湖滨草甸草场土-草-畜生态系统中铜的季节性变化研究[J].中国草地学报,2009,31(2):108-111.
[128]周志宇,张莉丽,高文星,等.试论灌木是干旱、半干旱区草地恢复中重要的生物资源[J].草业科学,2007,24(12):19-21.
[129]周志宇,朱宗元,刘钟龄等.干旱荒漠区受损生态系统的恢复重建与可持续发展[M].北京:科学出版社,2010,65-278.
[130]宗会,胡文玉.植物钙调素(CaM)研究进展[J].园艺学年评,1996,(2):177-196.
[131]邹邦基,何雪晖.植物的营养[M].北京:农业出版社.1985.29-301.
[132]邹丽娜.盐分胁迫下紫穗槐胜利生长特性及营养成分特征[D].甘肃:兰州大学,2010.
[133]左宇,李绍才一,杨志荣,赵建.岩生植物金发草生长发育对水分的响应[J].四川大学学报(自然科学版),2006,43(5):1142-1145.
[134]左忠,季文龙,王峰,李振永,郭永忠.柠条平茬后植株水分变化规律研究[J].宁夏农林科技,2005(5):22-23.
[135]张燕,方力,李天飞,等.钙对低温胁迫的烟草幼苗某些酶活性的影响[J].植物学通报,2002,19(3):342-347.
[1]Anisko T, Lindstrom O M. Reduced water supply induces fall acclimation of evergreen azaleas[J]. J. Amer. Soc. Hort. Sci.,1995,120(3):429-434.
[2]Abrahamson W G, Hal C. On the comparative allocation of biomass, energy and nutrient in plants [J].1982,63(4):982-991.
[3]Chopin E. I. B, Alloway B. J. Distribution and Mobility of Trace Elements in Soils and Vegetation Around the Mining and Smelting Areas of Tharsis, Riotinto and Huelva, Iberian Pyrite Belt, SW Spain[J]. Water Air Soil Pollut,2007, (182):245-261.
[4]En Tao Wang M, Antonio Rogel, Xin Hua Sui, et al. Mesorhizobium amorphae, a rhizobial species that nodulates Amorpha fruticosa, is native to American soils[J]. Arch Microbiol,2002, 178:301-305.
[5]Fonnesbeck P V, CarciaM M, Latis W H, et al. Estimating yield and nutrient losses due to rainfall on field drying alfalfahay [J]. Animal Feed Science and Technology,1986, (16):7-15.
[6]Fuqiang Song, Xingjun Tian, Xingbing He, Jiejie Hao. The influence of Desert False Indigo, Amorpha fruticosa, and three arbuscular mycorrhizae fungi on the growth of Populus ussuriensis seedlings[J]. New Forests,2009, (37):265-273.
[7]Go to M E, Simada E, Sugawara K. The relation between palatability and chemical composition of herbages cultivated in the shading condition [J]. Bulletin of the Faculty of Agriculture,1986, (72):81-85.
[8]Hak Ju Lee, Ha Young Kang, Cheol Hee Kim, et al. Effect of new rotenoid glycoside from the fruits of Amorpha fruticosa Linne on the growth of human immune cells[J], Cytotechnology,2006, 52:219-226.
[9]Jordan C F. The nutrient balance of Amazon Rainforest[J]. Ecology,1982, (63):647-655.
[10]John Maskall, lain Thornton. Trace element geochemistry of soils and plants in Kenyan conservation areas and implications for wildlife nutrition Environmental [J]. Geochemistry and Health,1991,13(2):93.
[11]Kramer P J. Water Relations of Plants[M]. New York: Academic Press,1983.
[12]Latinka Slavkovic, Biljana Skrbic, Nada Miljevic, et al. Principal component analysis of trace elements in industrial soils[J]. Environmental Chemistry Letters,2004,2(2):105-108.
[13]Madejon P, Burgos P, Murillo J M, et al. Bioavailability and accumulation of trace elements in soils and plants of a highly contaminated estuary(Domingo Rubio tidal channel, SW Spain)[J]. Environmental Geochemistry and Health,2009,31(6):629-642.
[14]Muneto Hirobe, Nobuhito Ohte, Nanae Karasawa. Plants pecies effect on the spat ial patterns of soil properties in the Muus desert ecosystem, In ner Mongolia[J]. China Plant and Soil,2001, 23(4):95-205.
[15]Muneto Hirobe, Nobuhito Ohte, Nanae Karasawa, et al. Plant species effect on the spatial patterns of soil properties in the Mu-us desert ecosystem, Inner Mongolia[J]. China Plant and Soil, 2001,23(4):95-205.
[16]Page A L, Mil ler R H, Keeney D R. Methods of soil analysis, part 2:Chemical and microbiological properties [C],2nd ASA, SSSA, Madison, Wisconsin USA, 1982.
[17]Papa S, Bartoli G, Pellegrino A, et al. Microbial activities and trace element contents in an urban soil. Environ Monit Assess,2009, DOI:10.1007/s 10661-009-0938-1.
[18]Price, Willian S. Hrioyoki Ide, Yoji Arta. Visualization of freezing behaviors in flower bud tissues of cold-hardy(Rhododendron japonieam)[J]. Austrilian Jornal of Plant Physiolog,1997, 24(5):599-605.
[19]Reddy N.S., Khan T.N., Malewer V.G., Dudde K.B.. Trace elements in spinach (Spinacia oleracea) cultivated in soil fortified with graded levels of iron[J]. Plant Foods for Human Nutrition, 1995, (47):357-360.
[20]Whittaker R H, et al. The Hubbard Brook ecosystem study:forest nutrient cycling and element behavior[J]. Ecology,1979,60(1):203-220.
[21]Woodwell G M, etal. Nutrient concentration in plants in the Brookhaven Cok-Pine forest[J]. Ecology,1975,56(2):318-332.
[22]Wang X J, Chen J S. Trace element contents and correlationin surface soils in China's eastern alluvial plains [J]. Environmental Geology,1998,36(4):277-284.
[2]卞禄,谢宝东,吴峰.不同香樟单株含水量及抗寒性差异分析[J].林业科技开发,2009,23(3):77-79.
[3]常杰,葛滢.羊草群落主要营养元素吸收相关性分析[J].植物学通报,1995,12(生态学专辑):136-141.
[4]曹文侠,张德罡,洪绂曾.祁连山高寒灌丛草地杜鹃属植物的水分动态及生态适应[J].草地学报,2006,14(1):67-71.
[5]曹小艳,李小进.微量元素对农产品品质的影响[J].安徽农学通报,2007,13(17):212.
[6]柴凤久,刘崇生,罗新义,李红,王凤国.苜蓿引种筛选试验初报[J].草业科学,2005,22(4):36-39.
[7]陈灵芝.北京人工刺槐林化学元素含量特征[J].植物生态与地植物学学报,1988,12(4):245-254.
[8]陈有君.内蒙古浑善达克沙地土壤水分状况的分析[J].干旱区资源与境,2000,14(1):80-85.
[9]刁乃宏.种植紫穗槐防止水土流失效益显著[J].黑龙江水利科技,2006,34(5):120.
[10]董丽,路艳红.常绿阔叶植物越冬期间叶片水分及淀粉粒的动态变化[J].北京林业大学学报,2002,5(6):76-80.
[11]杜桂娟,刘晓宏,侯志研,李启辉,马凤江,张鹏.紫花苜蓿品种比较与性状分析初报[J].草业科学,2005,22(9):45-48.
[12]杜前进,张永发,曾宾,等.海南富硒地区水稻富硒品种的筛选[J].中国土壤与肥料,2009,1:46-49.
[13]杜占池,樊江文,钟华平.红三叶和鸭茅化学元素的生物吸收能力研究[J].草业学报,
2008,17(2):47-53.
[14]方运霆,莫江明,周国逸,等.鼎湖山南亚热带常绿阔叶林植物和土壤微量元素含量[J].广西植物,2005,25(6):504-510.
[15]冯金朝,刘新民.干旱环境与植物的水分关系[M].北京:中国环境科学出版社,1998:208-211.
[16]冯锐,刘九庆.利用微波法测量植物叶片含水量[J].林业机械与木工设备,2009,37(2):47-48.
[17]冯宗炜.亚热带杉木纯林生态系统中营养元素的积累、分配和循环的研究[J].植物生态与地植物学丛刊,1985,9(4):245-256.
[18]伏建增,杜汉强,牛一川,等.紫花苜蓿品种抗旱性研究分析[J].草原与草坪,2006,115(2):65-67.
[19]付华,周志宇,陈善科.腾格里沙漠东南缘飞播区白沙蒿植被密度与土壤水分关系的研究[J].中国沙漠,2001,21(3):265-269.
[20]高彩霞,王培.收获期和干燥方法对苜蓿干草质量的影响[J].草地学报,1997,5(2):113-116.
[21]高洪波,陈贵林.钙调素拮抗剂与Ca2+对茄子幼苗抗冷性的影晌[J].园艺学报,2002,29(3):243-246.
[22]龚明,杜朝昆,许文忠.钙和钙调素对玉米幼苗抗旱性的调控[J].西北植物学报,1996,16(3):214-220
[23]谷小军.重提紫穗槐利国又利民[J].水土保持科技情报,2005,(2):48-49.
[24]顾振瑜,胡景江,文建雷.元宝枫对干旱适应性的研究[J].西北林学院学报,1999,14(2):1-6.
[25]管东生,罗琳.海南热带植物叶片化学元素含量特征[J].林业科学,2003,39(2):28-32.
[26]郭惠清,田有亮.杨幼树水分生理指标和光合强度与土壤含水量关系研究[J].干旱资源与环境,1998,12(2):101-106.
[27]郭卫华,李波,黄永梅.不同程度的水分胁迫对中间锦鸡儿幼苗气体交换特征的影响[J].生态学报,2004,24(12):2-16.
[28]韩玉林,黄苏珍,孙桂弟.5种鸢尾属观赏地被植物的抗旱性研究[J].江苏农业科学,2007,(2):79-81.
[29]何念鹏,周道玮,吴冷.极端干旱干扰下松嫩草原土壤含水量与植物的反映[J].干旱区资源与环境,2001,15(3):52-56.
[30]何维明.水分因素对沙地柏实生苗水分和生长特征的影响[J].植物生态学报,2001,25(1):11-16.
[31]侯学煜.中国植被地理及优势植物化学成分[M].北京:科学出版社,1982.316-321.
[32]候学煜.中国150种植物的化学成分及其分析方法[M].北京:高等教育出版社,1959.
[33]胡娟,邱慧珍,何秀成,等.施钾水平对甘肃烤烟钾含量及经济效益的影响[J].草业学报,2010,19(5):156-160.
[34]华东师范大学生物系植物生理教研组.植物生理学实验指导[M].上海:高等教育出版社,1980:10-17.
[35]黄明丽,邓西平,白登忠,等.N、P营养对旱地小麦生理过程和产量形成的补偿效应研究进展[J].麦类作物学报,2002,22(4):74-78.
[36]黄伟生,彭佩钦,黄道友,等.洞庭湖区不同土地利用方式耕作土壤氮素含量与循环[J].中国生态农业学报,2007,15(4):49-52.
[37]简令成,王红.钙在植物抗寒中的作用[[]].细胞生物学杂志,2002,24(3):166-171.
[38]姜永诰.发展紫穗槐产业的分析[[]].安徽农业科学,2007,35(1):98-151.
[39]姜勇,张玉革,梁文举.耕地土壤中交换态钙镁铁锰铜锌相关关系研究[[]].生态环境,2003,12(2):160-163.
[40]蒋式洪,何云峰.作物镁素营养与镁肥应用前景[J].化肥工业,1994,21(1):17-18,23.
[41]焦树仁.辽宁章古台樟子松人工林的生物量与营养元素分布的初步研究[J].植物生态与地植物学丛刊,1985,9(4):257-265.
[42]卡德尔·阿不都热西提.干旱胁迫下不同作物品种叶片含水量的测定[J].喀什师范学院学报,2009,30(6):50-53.
[43]刘颖,冯金朝,吴亚丽,等.内蒙古和林格尔地区柠条锦鸡儿生化成分分析[J].干旱区资源与环境,2008,22(9):159-162.
[44]来强,李青丰,莫日根敖其尔,等.草地牧草含水量测定暨干鲜比估测方法研究[J].内蒙古草业,2008,20(3):4-7.
[45]来强,李青丰,莫日根敖其尔,师桂花,吴雪宾.影响牧草含水量测定以及牧草干鲜比的主要因素[J].中国草地学报,2008,30(4):73-77.
[46]雷丽,程星,蔡雄飞.贵州岩溶山区土壤含水量时空分布与植物生长关系研究[J].贵州科学,2009,27(2):50-54.
[47]李德红,王小青,潘瑞炽.钙信使系统与植物激素信号传递[J].生物学杂志,1998,15(4):1-4.
[48]李广德,王晓辉,贾黎明,沈繁宜.国槐枝叶水分特征及其对树干边材液流的影响[J].中南林业科技大学学报,2010,30(1):23-28.
[49]李红丽,董智,王林和.浑善达克沙地流沙与4种主要植物群落土壤水分时空变化的研究[J].干旱区资源与环境,2006,20(3):169-174.
[50]李景梅,鞠殿民.微量元素的生理功能在农业生产中的作用[J].长春光学精密机械学院学报,2001,21(4):61-64.
[51]李俊清,宫伟光.东北主要造林树种的营养元索含量特征分析[J].植物生态与地植物学学报,1991,15(4):380-385.
[52]李明晶,孙华云,刘亦凡.镁在植物生长中的作用及镁肥[J].硫磷设计与粉体工程,2009,(4):36-38.
[53]李文华,刘广权,马松涛,王鸿哲.干旱胁迫对苗木蒸腾耗水和生长的影响[J].西北农林科技大学学报(自然科学版),2004,32(1):61-65.
[54]李文华,吴万兴,张忠良.土壤水分对仁用杏水分和生长特征的影响[J].西北农林科技大学学报(自然科学版),2003,31(4):139-144.
[55]李新虎,赵文杰.银川平原土壤中几种元素有效态与全量相关关系的研究[J].宁夏农林科技,2001,(4):26-28
[56]李志安,彭少麟.我国热带亚热带几种人工林体内营养结构特征[J].生态学杂志,2001,20(4):1-4.
[57]李志安,王伯荪,孔国辉,等.鼎湖山季风常绿阔叶林黄果厚壳桂群落植物元素含量特征[J].植物生态学报,1999,23(5):411~417.
[58]李志安,王伯荪,林永标,等.植物营养转移研究进展[J].武汉植物学研究,2000,18(3):229~236.
[59]李志安,王伯荪,张宏达.关于植物营养生态学[J].生态科学,1999,18(4):43-47.
[60]栗德永,王开曦.太白山植物元素背景值的研究[J].植物生态与地植物学丛刊,1983,7(3):230-239.
[61]廖观荣,钟继洪,郭庆荣.土壤水分对幼龄桉树蒸腾和生长的影响[J].土壤与环境,2001,10(4):285-288.
[62]林厚萱.中国境内酸性土、钙质土和盐渍土植物和指示植物的化学成分[J].土壤学报,1957,5(3):247-267.
[63]林克惠,赵平,祖艳群.微量元素对作物和人体的毒害作用及其控制[J].云南农业大学学报,2002,17(1):94-98.
[64]林秀华,刘传芹,范业春.镁肥对水稻产量及品质的影响研究[J].农业科技通讯,2008,(11):40-41.
[65]刘贵波,乔仁甫.饲用黑麦适宜青刈时期及青刈次数研究[J].草业科学,2005,22(10):47-50.
[66]刘建福,倪书邦,贺熙勇,汤青林.水分胁迫对澳洲坚果叶片矿质元素含量的影响[J].热带农业科,2004,27(1):1-3.
[67]刘任涛,任佳.不同土壤水分条件下翅果油树幼苗生理特性[J].南阳师范学院学报,2005,4(12):59-62.
[68]刘雪云,李晓忠,周志宇,秦或,姜文清,田发益.不同开垦年限西藏草地中量、微量元素含量变化特点[J].中国草地学报,2010,32(6):70-75.
[69]刘颖,李改枝,李晓伟.呼和浩特市和林格尔地区沙棘生化成分分[J].内蒙古师范大学学报(自然科学版),2006,35(4):466-469.
[70]刘颖一,冯金朝,周珊珊,李改枝,范文静,李皎洁.内蒙古和林格尔地区沙地柏生化成分分析[J].内蒙古大学学报(自然科学版),2008,39(4):411-416.
[71]刘振虎,卢欣石.几个紫花苜蓿品种在北京地区引种及适应性评价[J].2004,21(增刊):405-407.
[72]刘忠宽,王艳芬,汪诗平,韩建国,陈佐忠.不同干燥失水方式对牧草营养品质影响的研究[J].草业学报,2004,13(3):47-51.
[73]吕绪清,吕新龙,义如格勒图,等.俄罗斯杂花苜蓿引种栽培试验初报[J].草原与草坪,2008,128(3):52-55.
[74]马红,熊号发,谢雪山,陈继红,杨金勇,熊云祥.多花黑麦草品比试验[J].草业与畜牧,2010(1):16-18.
[75]马丽琼,曹敏建,刘蓓,李必富.不同钾营养效率型玉米品种的苗期生理特性[J].安徽农业科学,2006,34(13):3011-3013.
[76]莫江明,张德强,黄忠良,等.鼎湖山南亚热带常绿阔叶林植物营养元素含量分配格局研究[J].热带亚热带植物学报,2000,8(3):198-206.
[77]牟咏花.钙的生理功能及在果蔬生理中的重要性(综述)[J].浙江农业学报,1995,7(6):499-501.
[78]娜日苏,米福贵.串叶松香草生物学特性及营养成分研究[J].内蒙古草业,2006,18(2):9-11.
[79]南德标,姜同弟.紫穗槐的特征特性与栽培技术[J].现代农业科技,2009,15:211
[80]裴彩霞,董宽虎,范华.不同刈割期和干燥方法对牧草营养成分含量的影响[J].中国草地,2000,(1):32-37.
[81]乔洁,崔秀艳,王君芳,刘卓,李洪涛,马训骏,罗文浩,娄玉杰.土壤水分、氮、磷、钾含量与牧草营养成分的关系[J].饲草与饲,2009,(9):58-59.
[82]乔有明,王振群,段中华.青海湖北岸土地利用方式对土壤碳氮含量的影响[J].草业学报,2009,18(6):105-112.
[83]秦海,李俊祥,高三平,等.中国660种陆生植物叶片8种元素含量特征[J].生态学报,2010,30(5):1247-1257.
[84]任桂霞.紫穗槐水土保持效果浅析[J].农业与技术,2006,26(4):84.
[85]任海彦,郑淑霞,白永飞.放牧对内蒙古锡林河流域草地群落植物茎叶生物量资源分配的影响[J].植物生态学报,2009,33(6):1065-1074.
[86]任伟,周志宇,詹媛媛.阿拉善荒漠灌木根际中、微量元素含量特征[J].生态学报,2009,29(7):3760-3767.
[87]尚爱军,卜耀军,艾海舰,刘翠英,张雄.榆林沙区土壤水分时空格局及动态变化规律研究[J].水土保持学报,2008,22(4):86-89.
[88]宋德荣.施用不同氮肥对牧草和放牧牦牛血液营养元素含量的影响[J].中国草地学报,2010,32(2):42-46.
[89]孙彦,杨青川,张英华.不同草坪草种及品种苗期抗旱性比较[J].草地学报,2001,9(1):16-20.
[90]谭华.氮、磷、钾和密度等因素对玉米产量形成的作用[J].玉米科学,1998,(增刊):93-96.
[91]田德贵,卢克俊,张素华,卞志高,仁青扎西.紫花苗蓿引种试验研究[J].试验研究,(5):19-20.
[92]田晶会,王百田.黄土半干旱区剌槐林水分与生长关系研究[J].水土保持学报,2002,16(5):61-63.
[93]田士林,李莉.香樟在我国中部引种适应性研究[J].安徽农业科学,2006,34(11):2403-2445.
[94]翁凌飞,韩烈保,常智慧,等.重庆庆隆高尔夫球场果岭土壤理化性状测试与分析[J].草业学报,2010,19(4):108-114.
[95]王海.青海东部地区公路边坡灌木栽培技术[J].辽宁林业科技,2009(3):55-56.
[96]王加启,于建国.饲料分析与检验[M].北京:中国计量出版社,2004:40-50.
[97]王建国,贾国兴,冯忠,苏月玲,邓景丽,丁永锋,陈苹.耐水湿、耐盐碱树种造林技术试验[J].宁夏农林科技,1999,(6):34-35.
[98]王奇丽,张垚,白志明,等.不同秋眠性紫花苜蓿品种初冬季节的植物量变化研究[J].草原与草坪,2009,136(5):6-9.
[99]王瑞云,王玉国.钙在植物生理代谢中的作用[J].世界农业,2001,(6):41-43.
[100]王伟,曹敏建,周春喜,李植,张辉.大豆耐低钾胁迫品种(系)的筛选[J].大豆通报,2005,(4):7-8.
[101]王印川.紫穗槐及其经济利用价值[J].山西水土保持科技,2003,(1):21-23.
[102]温肇穆.杉木成熟林乔木层营养元素生物循环的研究[J].植物生态与地植物学学报,1991,15(1):36-45.
[103]吴高潮,王晓娟,吕宁.固氮树种在混交林中的作用[J].福建林业科技,2006,33(3):175-177.
[104]吴婧舒,周广柱,周金峰.平榛抗旱性研究[J].江苏农业科学,2010,(2):196-198.
[105]邢倩,谷艳芳,高志英,丁圣彦.氮、磷、钾营养对冬小麦光合作用及水分利用的影响[J].生态学杂志,2008,27(3):355-360.
[106]熊景发,谢雪山,杨金勇,苏会银,马红,杨永康,熊云祥.夏季青贮饲草品种引种试验[J].草原与饲料,2009,29(6):39-41.
[107]徐安凯,王志峰,于洪柱.吉林省种植苜蓿品种选择研究[J].草业科学,2004,21(增刊):316-322.
[108]颜淑云.紫穗槐幼苗对于干旱胁迫的生理生化响应[D].甘肃:兰州大学,2010.
[109]杨成,刘丛强,宋照亮,等.贵州喀斯特山区植物营养元素含量特征[J].生态环境,2007,16(2):503-508.
[110]杨恒山,曹敏建,范富,等.刈割次数对健宝(Jumbo)产草量及品质的影响[J].中国草地,2003,25(3):28-31.
[111]杨建伟,韩蕊莲,魏宇昆.不同土壤水分状况对杨树、沙棘水分关系及生长的影响[J].西北植物学报,2002,22(3):579-586.
[112]杨建伟,梁宗锁,韩蕊莲.不同土壤水分状况对刺槐的生长及水分利用特征的影响[J].林业科学,2004,40(5):93-98.
[113]杨胜.饲料分析及饲料质量检测技术[M].北京:北京农业大学出版社,1999:34-45.
[114]杨廷良,崔国贤,罗中钦,肖红松.钙与植物抗逆性研究进展[J].作物研究,2004(5):380-384.
[115]余海燕,高红军,王海霞,等.紫穗槐繁殖技术及其应用[J].宁夏农林科技,2010,(6):153.
[116]周志宇,李锋瑞,陈亚明,等.阿拉善荒漠不同密度白沙蒿人工种群生长、繁殖与土壤水分的关系[J].生态学报,2004,24(5):895-899.
[117]曾凡江,张希明,李小明.柽柳的水分生理特性研究进展[J].应用生态学报,2002,13(5):611-614.
[118]张夫道.氮素营养研究中的几个热点问题[J].植物营养与肥料学报,1998,4(4):331-338.
[119]张国君,李云,付元瑞,等.刺槐、柠条和紫穗槐青贮品质的比较[J].西北林学院学报,2009,24(1):151~156.
[120]张杰,贾志宽,韩清芳.不同养分对苜蓿茎叶比和鲜干比的影响[J].西北农业学报,2007,16(4):121-125.
[121]张雷明,上官周平.黄土高原土壤水分与植被生产力的关系[J].干旱区研究,2002,19(4):59-63.
[122]张世绥.盐渍土地区公路边坡的生物防护[J].河北交通科技,2006,3(1):18-20.
[123]张志伟.浅析紫穗槐的利用价值及造林技术[J].安徽农学通报,2009,15(12):164.
[124]中国科学院南京土壤研究所.土壤理化分析[M].上海:科学技术出版社,1978,357-358.
[125]李文西,鲁剑巍,鲁君明,等.苏丹草—黑麦草轮作制中施氮量对饲草产量与土壤氮碳积累的影响[J].草业学报,2011,20(1):55-61.
[126]中国科学院南京土壤研究所微量元素组.士壤和植物中微量元素分析方法[M].北京:科学出版社,1979.
[127]周学辉,苗小林,张继华.青海湖滨草甸草场土-草-畜生态系统中铜的季节性变化研究[J].中国草地学报,2009,31(2):108-111.
[128]周志宇,张莉丽,高文星,等.试论灌木是干旱、半干旱区草地恢复中重要的生物资源[J].草业科学,2007,24(12):19-21.
[129]周志宇,朱宗元,刘钟龄等.干旱荒漠区受损生态系统的恢复重建与可持续发展[M].北京:科学出版社,2010,65-278.
[130]宗会,胡文玉.植物钙调素(CaM)研究进展[J].园艺学年评,1996,(2):177-196.
[131]邹邦基,何雪晖.植物的营养[M].北京:农业出版社.1985.29-301.
[132]邹丽娜.盐分胁迫下紫穗槐胜利生长特性及营养成分特征[D].甘肃:兰州大学,2010.
[133]左宇,李绍才一,杨志荣,赵建.岩生植物金发草生长发育对水分的响应[J].四川大学学报(自然科学版),2006,43(5):1142-1145.
[134]左忠,季文龙,王峰,李振永,郭永忠.柠条平茬后植株水分变化规律研究[J].宁夏农林科技,2005(5):22-23.
[135]张燕,方力,李天飞,等.钙对低温胁迫的烟草幼苗某些酶活性的影响[J].植物学通报,2002,19(3):342-347.
[1]Anisko T, Lindstrom O M. Reduced water supply induces fall acclimation of evergreen azaleas[J]. J. Amer. Soc. Hort. Sci.,1995,120(3):429-434.
[2]Abrahamson W G, Hal C. On the comparative allocation of biomass, energy and nutrient in plants [J].1982,63(4):982-991.
[3]Chopin E. I. B, Alloway B. J. Distribution and Mobility of Trace Elements in Soils and Vegetation Around the Mining and Smelting Areas of Tharsis, Riotinto and Huelva, Iberian Pyrite Belt, SW Spain[J]. Water Air Soil Pollut,2007, (182):245-261.
[4]En Tao Wang M, Antonio Rogel, Xin Hua Sui, et al. Mesorhizobium amorphae, a rhizobial species that nodulates Amorpha fruticosa, is native to American soils[J]. Arch Microbiol,2002, 178:301-305.
[5]Fonnesbeck P V, CarciaM M, Latis W H, et al. Estimating yield and nutrient losses due to rainfall on field drying alfalfahay [J]. Animal Feed Science and Technology,1986, (16):7-15.
[6]Fuqiang Song, Xingjun Tian, Xingbing He, Jiejie Hao. The influence of Desert False Indigo, Amorpha fruticosa, and three arbuscular mycorrhizae fungi on the growth of Populus ussuriensis seedlings[J]. New Forests,2009, (37):265-273.
[7]Go to M E, Simada E, Sugawara K. The relation between palatability and chemical composition of herbages cultivated in the shading condition [J]. Bulletin of the Faculty of Agriculture,1986, (72):81-85.
[8]Hak Ju Lee, Ha Young Kang, Cheol Hee Kim, et al. Effect of new rotenoid glycoside from the fruits of Amorpha fruticosa Linne on the growth of human immune cells[J], Cytotechnology,2006, 52:219-226.
[9]Jordan C F. The nutrient balance of Amazon Rainforest[J]. Ecology,1982, (63):647-655.
[10]John Maskall, lain Thornton. Trace element geochemistry of soils and plants in Kenyan conservation areas and implications for wildlife nutrition Environmental [J]. Geochemistry and Health,1991,13(2):93.
[11]Kramer P J. Water Relations of Plants[M]. New York: Academic Press,1983.
[12]Latinka Slavkovic, Biljana Skrbic, Nada Miljevic, et al. Principal component analysis of trace elements in industrial soils[J]. Environmental Chemistry Letters,2004,2(2):105-108.
[13]Madejon P, Burgos P, Murillo J M, et al. Bioavailability and accumulation of trace elements in soils and plants of a highly contaminated estuary(Domingo Rubio tidal channel, SW Spain)[J]. Environmental Geochemistry and Health,2009,31(6):629-642.
[14]Muneto Hirobe, Nobuhito Ohte, Nanae Karasawa. Plants pecies effect on the spat ial patterns of soil properties in the Muus desert ecosystem, In ner Mongolia[J]. China Plant and Soil,2001, 23(4):95-205.
[15]Muneto Hirobe, Nobuhito Ohte, Nanae Karasawa, et al. Plant species effect on the spatial patterns of soil properties in the Mu-us desert ecosystem, Inner Mongolia[J]. China Plant and Soil, 2001,23(4):95-205.
[16]Page A L, Mil ler R H, Keeney D R. Methods of soil analysis, part 2:Chemical and microbiological properties [C],2nd ASA, SSSA, Madison, Wisconsin USA, 1982.
[17]Papa S, Bartoli G, Pellegrino A, et al. Microbial activities and trace element contents in an urban soil. Environ Monit Assess,2009, DOI:10.1007/s 10661-009-0938-1.
[18]Price, Willian S. Hrioyoki Ide, Yoji Arta. Visualization of freezing behaviors in flower bud tissues of cold-hardy(Rhododendron japonieam)[J]. Austrilian Jornal of Plant Physiolog,1997, 24(5):599-605.
[19]Reddy N.S., Khan T.N., Malewer V.G., Dudde K.B.. Trace elements in spinach (Spinacia oleracea) cultivated in soil fortified with graded levels of iron[J]. Plant Foods for Human Nutrition, 1995, (47):357-360.
[20]Whittaker R H, et al. The Hubbard Brook ecosystem study:forest nutrient cycling and element behavior[J]. Ecology,1979,60(1):203-220.
[21]Woodwell G M, etal. Nutrient concentration in plants in the Brookhaven Cok-Pine forest[J]. Ecology,1975,56(2):318-332.
[22]Wang X J, Chen J S. Trace element contents and correlationin surface soils in China's eastern alluvial plains [J]. Environmental Geology,1998,36(4):277-284.