西南山地小径竹的重金属富集能力
|
摘要
西南山地小径竹的种类多、分布广、生长快、生物量高,且对土壤重金属具有一定的耐受性,在土壤重金属修复方面具有潜在优势。目前对于西南山地竹区的小径竹在土壤重金属修复方面的研究和应用鲜有报道。以西南山地的林下优势层片缺苞箭竹(Fargesiadenudate)和拐棍竹(F.robusta)为研究对象,通过测定分析其茎、叶、笋及根际土壤的重金属Cu、Zn、Pb、Cd、Cr含量,比较不同小径竹地上各部位的富集系数,并与常见的超积累植物相比,探讨小径竹的重金属富集潜力。结果表明:(1)缺苞箭竹和拐棍竹叶的Cu、Zn、Pb、Cd、Cr含量和富集系数均显著大于茎和笋(P=0.001);(2)缺苞箭竹地上各部位对Cu的富集系数大于Zn、Pb、Cd、Cr,而拐棍竹对Cu的富集系数较小;(3)缺苞箭竹地上部的Cu富集系数(2.16)、Zn富集系数(1.27)显著大于拐棍竹(0.17、0.93,P=0.001),而Pb富集系数(0.09)、Cd富集系数(0.34)、Cr富集系数(0.82)显著小于拐棍竹(0.87、0.49、1.03,P=0.002、0.049、0.001);(4)与生长在未被污染土壤中的超积累植物相比,缺苞箭竹具有更大的Cu、Cr富集潜力,拐棍竹对Pb、Cr具有更大的富集潜力。西南山地小径竹在土壤污染修复方面具有较高的生态、经济和景观效益,有发展成为生态-经济型土壤重金属修复植物的潜力。
Numerous dwarf bamboo species, due to rapid growth ability and high biomass capacity, are widely distributed in the Southwest Mountainous area of China. Among these, some species show a strong potential tolerance to the heavy metals in soil.Thus, some of them can be used as bio-remediation of soil contaminated by heavy metals. Up to date, some researches have shown that the absorption and transformation of heavy metals in the bamboo as well as the physiological and ecological responses of bamboo plants under the stress of heavy metals. However, most of these studies focused on bamboo species in the Yangtze River and Nanling Mountains, there were few studies and applications on remediating heavy metals in the dwarf bamboo in the southwest mountainous region. In this paper, the Cu, Zn, Pb, Cd and Cr contents in stems, leaves and shoots and rhizosphere soils in Fargesia denudate and F. robusta, the undergrowth dominant layers in Southwest Mountainous China, were measured over its growing season.The bioaccumulation factors of above-ground parts of different dwarf bamboos were compared accordingly. The results showed,firstly, the contents and bioaccumulation factors of Cu, Zn, Pb, Cd and Cr in leaves were significantly higher than the stems and shoots(P=0.001). Secondly, the bioaccumulation factors of Cu in stems, leaves and shoots of F.denudate were higher than that of Zn,Pb, Cd and Cr, while the bioaccumulation factors of Cu in stems, leaves and shoots of F. robusta were lower than that of Zn, Pb, Cd and Cr. Thirdly, the bioaccumulation factors of Cu(2.16) and Zn(1.27) in stems, leaves and shoots of F. denudate were significantly higher than that of F. robusta(0.17, 0.93, P=0.001), while the bioaccumulation factors of Pb(0.09), Cd(0.34) and Cr(0.82) in stems,leaves and shoots of F. denudate were lower significantly(0.87, 0.49, 1.03, P=0.002, 0.049 and 0.001). Fourthly, compared with common hyperaccumulation plants, F. denudate showed the potential ability on Cu and Cr enrichment, and F. robusta on Pb and Cr.This study indicates that dwarf bamboos probably can be used on the ecosystem service with their higher economic benefits and landscape value in the remediation of soil with heavy metals pollutions.
Numerous dwarf bamboo species, due to rapid growth ability and high biomass capacity, are widely distributed in the Southwest Mountainous area of China. Among these, some species show a strong potential tolerance to the heavy metals in soil.Thus, some of them can be used as bio-remediation of soil contaminated by heavy metals. Up to date, some researches have shown that the absorption and transformation of heavy metals in the bamboo as well as the physiological and ecological responses of bamboo plants under the stress of heavy metals. However, most of these studies focused on bamboo species in the Yangtze River and Nanling Mountains, there were few studies and applications on remediating heavy metals in the dwarf bamboo in the southwest mountainous region. In this paper, the Cu, Zn, Pb, Cd and Cr contents in stems, leaves and shoots and rhizosphere soils in Fargesia denudate and F. robusta, the undergrowth dominant layers in Southwest Mountainous China, were measured over its growing season.The bioaccumulation factors of above-ground parts of different dwarf bamboos were compared accordingly. The results showed,firstly, the contents and bioaccumulation factors of Cu, Zn, Pb, Cd and Cr in leaves were significantly higher than the stems and shoots(P=0.001). Secondly, the bioaccumulation factors of Cu in stems, leaves and shoots of F.denudate were higher than that of Zn,Pb, Cd and Cr, while the bioaccumulation factors of Cu in stems, leaves and shoots of F. robusta were lower than that of Zn, Pb, Cd and Cr. Thirdly, the bioaccumulation factors of Cu(2.16) and Zn(1.27) in stems, leaves and shoots of F. denudate were significantly higher than that of F. robusta(0.17, 0.93, P=0.001), while the bioaccumulation factors of Pb(0.09), Cd(0.34) and Cr(0.82) in stems,leaves and shoots of F. denudate were lower significantly(0.87, 0.49, 1.03, P=0.002, 0.049 and 0.001). Fourthly, compared with common hyperaccumulation plants, F. denudate showed the potential ability on Cu and Cr enrichment, and F. robusta on Pb and Cr.This study indicates that dwarf bamboos probably can be used on the ecosystem service with their higher economic benefits and landscape value in the remediation of soil with heavy metals pollutions.
引文
BIAN F Y,ZHONG Z K,ZHANG X P,et al.,2017.Phytoremediation potential of moso bamboo(Phyllostachys pubescens)intercropped with Sedum plumbizincicola in metal-contaminated soil[J].Environmental Science and Pollution Research,24(35):27244-27253.
BROADLEY M R,WHITE P J,HAMMOND J P,et al.,2007.Zinc in plants[J].New Phytol,173(4):677-702.
CHANDRA R,KUMAR V,TRIPATHI S,et al.,2018.Heavy metal phytoextraction potential of native weeds and grasses from endocrine-disrupting chemicals rich complex distillery sludge and their histological observations during in-situ phytoremediation[J].Ecological Engineering,111:143-156.
CHEN J R,SHAFI M,LI S,et al.,2015.Copper induced oxidative stresses,antioxidant responses and phytoremediation potential of moso bamboo(Phyllostachys pubescens)[J].Scientific Reports,5:2045-2322.
COLLIN B,DOELSCH E,KELLER C,et al.,2012.Distribution and variability of silicon,copper and zinc in different bamboo species[J].Plant and Soil,351(1-2):377-387.
COLLIN B,DOELSCH E,KELLER C,et al.,2013.Effects of silicon and copper on bamboo grown hydroponically[J].Environmental Science and Pollution Research,20(9):6482-6495.
DAS M,BHATTACHARYA S,SINGH P,et al.,2008.Bamboo taxonomy and diversity in the era of molecular markers[J].Botanical Research:Incorporating Advances in Plant Pathology,47:225-268.
FLORIJIN P J,VAN BEUSICHEM M L,1993.Uptake and distribution of cadmium in maize inbred lines[J].Plant Soil,150(1):25-32.
JORGE R A,ARRUDA M P,2001.Probing the role of camodulin in Al toxicity in maize[J].Phytochemistry,58:415-422.
KLEINHENZ V,MIDMORE D J,2001.Aspects of bamboo agronomy[J].Advances in Agronomy,74:99-153.
LI J T,GURAJALA H K,WU L H,et al.,2018.Hyperaccumulator plants from China:a synthesis of the current state of knowledge[J].Environmental Science&Technology,52:1-66.
LI J,LEISNER M,FRANTZ J,2008.Alleviation of copper toxicity in Arabidopsis thaliana by silicon addition to hydroponic solutions[J].Journal of the American Society for Horticultural Science American Society for Horticultural Science,133(5):670-677.
LI S,ISLAM E,PENG D L,et al.,2015.Accumulation and localization of cadmium in moso bamboo(Phyllostachys pubescens)grown hydroponically[J].Acta Physiol Plant,37(3):56-62.
LI S,CHEN J R,ISLAM E,et al.,2016.Cadmium-induced oxidative stress,response of antioxidants and detection of intracellular cadmium in organs of moso bamboo(Phyllostachys pubescens)seedlings[J].Chemosphere,153:107-114.
MERCHANT S,BRIGGS W R,ORT D,2010.Metal hyperaccumulation in plants[J].Annual Review of Plant Biology,61:517-534.
REEVES R D,BAKER A J M,2000.Metal-accumulating plants[J].Phytoremediation of toxic metals,12:193-229.
SCANDALIOS J G,1993.Oxygen stress and superoxide dismutases[J].Plant Physiol,101(1):7-12.
SEREGIN I V,IVANOV V B,2001.Physiological aspects of cadmium and lead toxic effects on higher plants[J].Russian Journal of plant physiology,48(4):523-544.
TANG S R,WILKE B M,HUANG C Y,1999.The uptake of copper by plants dominantly growing on copper mining spoils along the Yangtze River,the People’s Republic of China[J].Plant and Soil,209(2):225-232.
WANG S F,ZHAO Y,GUO J H,et al.,2016.Effects of Cd,Cu and Zn on Ricinus communis L.growth in single element or co-contaminated soils:Pot experiments[J].Environmental Ecology,90:347-351.
WERE F H,WAFULA G A,WAIRUNGU S,2017.Phytoremediation using bamboo to reduce the risk of chromium exposure from a contaminated tannery site in Kenya[J].Journal of health&pollution,7(16):12-25.
YANG W H,ZHANG T X,LI S L,et al.,2014.Metal removal from and microbial property improvement of a multiple heavy metals contaminated soil by phytoextraction with a cadmium hyperaccumulator Sedum alfredii H.[J].Journal of Soils and Sediments,14(8):1385-1396.
ZHANG X H,LIU J,WANG D Q,et al.,2009.Bioaccumulation and chemical Form of chromium in Leersia hexandra Swartz[J].Bulletin of Environmental Contamination and Toxicology,82(3):358-362.
ZHONG B,CHEN J R,SHAFI M,et al.,2017.Effect of lead(Pb)on antioxidation system and accumulation ability of moso bamboo(Phyllostachys pubescens)[J].Ecotoxicology and Environmental Safety,138:71-77.
ZHOU G M,MENG C F,JIANG P K,et al.,2011.Review of carbon fixation in bamboo forests in China[J].Botanical Review,77(3):262-270.
陈能场,郑煜基,何晓峰,等,2017.《全国土壤污染状况调查公报》探析[J].农业环境科学学报,36(9):1689-1692.CHEN N C,ZHENG Y J,HE X F,et al.,2017.Analysis of the bulletin of national soil pollution survey[J].Journal of Agro-Environment Science,36(9):1689-1692.
杜俊杰,周启星,李娜,等,2018.超积累植物修复重金属污染土壤的研究进展[J].贵州农业科学,46(5):64-72.DU J J,ZHOU Q X,LI N,et al.,2018.Progress in remediation of heavy metal contaminated soil by hyperaccumulator[J].Guizhou Agricultural Sciences,46(5):64-72.
方其仙,李元,祖艳群,等,2012.圆叶无心菜对Pb的吸收累积特征研究[J].环境科学与技术,35(5):121-126.FANG Q X,LI Y,ZU Y Q,et al.,2012.Accumulation characteristics of Arenaria rotumdifolia Bieberstein to Pb[J].Environmental Science&Technology,35(5):121-126.
高洁,刘文英,陈卫军,2012.电镀污染区植物对复合重金属的富集、转移和对污染土壤的修复潜力[J].生态与农村环境学报,28(4):468-472.GAO J,LIU W Y,CHEN W J,2012.Potentials of plants growing in contaminated soils nearby electroplating plants for accumulating and translocating heavy metals and remedying the soils[J].Journal of Ecology and Rural Environment,28(4):468-472.
管铭,裴立,郭水良,等,2010.假稻对铬的富集作用及其耐受能力研究[J].环境科学与管理,35(3):125-130.GUAN M,PEI L,GUO S L,et al.,2010.On bioaccumulation and endurance of Leersia japonica to chromium[J].Environmental Science and Management,35(3):125-130.
郭绪虎,肖德荣,田昆,等,2013.滇西北高原纳帕海湿地湖滨带优势植物生物量及其凋落物分解[J].生态学报,33(5):1425-1432.GUO X H,XIAO D R,TIAN K,et al.,2013.Biomass production and litter decomposition of lakeshore plants in Napahai wetland,northwestern Yunnan Plateau,China[J].Acta Ecologica Sinica,33(5):1425-1432.
胡鹏杰,李柱,钟道旭,等,2014.我国土壤重金属污染植物吸取修复研究进展[J].植物生理学报,50(5):577-584.HU P J,LI Z,ZHONG D X,et al.,2014.Research progress on the phytoextraction of heavy metal contaminated soils in China[J].Plant Physiology Journal,50(5):577-584.
姜黎,2009.几种竹对过量Cu胁迫的生理适应性研究[D].南京:南京农业大学:1-57.JIANG L,2009.Research on the physiological adaptability of bamboo stressed by excess copper[D].Nanjing:Nanjing Agricultural University:1-57.
金忠民,李丹,潘林,等,2016.抗性菌株JB13强化高羊茅对铅镉的富集[J].北方园艺(9):75-78.JIN Z M,LI D,PAN L,et al.,2016.Resistant strains of JB13 enhanced enrichment of lead and cadmium in Festuca ovina[J].Northern Horticulture(9):75-78.
李娟,高健,2016.黄条金刚竹、阔叶箬竹和菲白竹在干旱、冻害和重金属Pb胁迫下光合生理响应研究[J].竹子研究汇刊,35(1):22-29.LI J,GAO J,et al.,2016.Photosynthetic and physiological responses to drought,cold and Pb stresses in Pleioblastus kongosanensi,Indocalamus latifolius and Sasa fortune[J].Journal of Bamboo Research,35(1):22-29.
刘威,束文圣,蓝崇钰,2003.宝山堇菜(Viola baoshanensis):一种新的镉超富集植物[J].科学通报,48(19):2046-2049.LIU W,SHU W S,LAN C Y,et al.,2003.Viola baoshanensis:A new cadmium rich plant[J].Bulletin of Science and Technology,48(19):2046-2049.
刘小红,2005.九华铜矿重金属污染调查及耐铜植物的筛选、耐性机理研究[D].合肥:安徽农业大学:1-77.LIU X H,2005.Heavy metal contamination and copper tolerant plants in the vicinity of Jiuhua copper mine[D].Hefei:Anhui Agricultural University:1-77.
龙新宪,倪吾钟,叶正钱,等,2006.超积累生态型东南景天吸收锌的特性[J].生态学报,26(2):334-340.LONG X X,NI W Z,YE Z Q,et al.,2006.The characteristic of Zn uptake by the hyperaccumulating ecotype of Sedum alfredii Hance[J].Acta Ecologica Sinica,26(2):334-340.
陆静,2018.西南地区农业土壤污染状况及防治对策建议[J].南方农业,12(16):83-86.LU J,2018.The situation of agricultural soil pollution and countermeasures in southwest China[J].Southern agriculture,12(16):83-86.
罗于洋,赵磊,王树森,2010.铅超富集植物密毛白莲蒿对铅的富集特性研究[J].西北林学院学报,25(5):37-40.LUO Y Y,ZHAO L,WANG S S,et al.,2010.Absorption characteristics of Artemisia sacrorum var.messerschmidtiana to lead[J].Journal of Northwest Forestry University,25(5):37-40.
乔云蕾,2016.几种植物对土壤重金属镉、铬污染的修复潜力研究[D].金华:浙江师范大学:1-53.QIAO Y L,2016.Study on remedial of Cd and Cr contamination in soil by several plants[D].Jinhua:Zhejiang Normal University:1-53.
时宇,冉珊珊,黄黄,等,2018.黄石国家矿山公园草本植物重金属富集能力研究[J].生态环境学报,27(4):769-775.SHI Y,RAN S S,HUANG H,et al.,2018.Enrichment capability of herbaceous plants in Huangshi national mine park[J].Ecology and Environmental Sciences,27(4):769-775.
汪前山,2017.董铺水库周边植被现状分析及恢复建议[J].安徽水利水电职业技术学院学报,17(3):14-16.WANG Q S,2017.Status assessments and recovery recommendations of the plants around the Dongpu reservior[J].Journal of Anhui Technical College of Water Resources and Hydroelectric Power,17(3):14-16.
王兵,2011.竹子对重金属铅镉的累积规律及耐抗性研究[D].泰安:山东农业大学:1-78.WANG B,2011.Study of heavy metals lead and cadmium on the accumulation and tolerance of bamboos[D].Taian:Shandong Agricultural University:1-78.
王开运,2004.川西亚高山森林群落生态系统过程[M].成都:四川科学技术出版社:23-55.WANG K Y,2004.Ecosystem process of subalpine forest community in western Sichuan[M].Chengdu:Sichuan Science and Technology Press:23-55.
吴开贤,陈蕴,赵玲,等,2010.修剪干扰下高羊茅的生长与生物量分配[J].云南农业大学学报,25(1):102-106.WU K X,CHEN Y,ZHAO L,et al.,2010.The growth and biomass allocation of Festuca ovina under clipping disturbance[J].Journal of Yunnan Agricultural University,25(1):102-106.
谢丽萍,李焘,蒋翠文,等,2018.重金属镉、汞、铜和铅在荸荠体内的累积特性研究[J].西南农业学报,31(8):1712-1716.XIE L P,LI T,JIANG C W,et al.,2018.Study on accumulation characteristics of heavy metals of cadmium,mercury,copper and lead in Heleocharis dulcis[J].Southwest China Journal of Agricultural Sciences,31(8):1712-1716.
杨肖娥,龙新宪,倪吾钟,等,2002.东南景天(Sedumalfredii H):一种新的锌超积累植物[J].科学通报,47(13):1003-1006.YANG X E,LONG X X,NI W Z,et al.,2002.Sedumalfredii H:A new zinc hyperaccumulator plant[J].Bulletin of Science and Technology,47(13):1003-1006.
姚婧,陈雪梅,王友保,2008.Pb污染土壤对高羊茅种子萌发及幼苗生长的影响[J].上海交通大学学报(农业科学版),26(1):61-65.YAO J,CHEN X M,WANG Y B,2008.Effects of soils contaminated by lead on germination and seedling growth of festuca arundinacea L.[J].Journal of Shanghai Jiaotong University(Agricultural Science),26(1):61-65.
易同培,史军义,马丽莎,等,2008.中国竹类图志[M].北京:科学出版社:21-33.YI T P,SHI J Y,MA L S,et al.,2008.Chinese bamboo pictorial[M].Beijing:Science Press:21-33.
杨兵,廖斌,邓冬梅,等,2004.Cu2+对两种生态型鸭跖草Cu积累和抗氧化酶的影响[J].中国环境科学,24(1):10-14.YANG B,LIAO B,DENG D M,et al.,2004.Effect of Cu2+on Cu accumulation and antioxidative enzymes of two ecotype of Commelina communis[J].China Environmental Science,24(1):10-14.
尹瑞安,叶柳欣,郑世伟,等,2018.3种不同地下茎形态竹子的钾含量及积累特征[J].浙江农业科学,59(7):1111-1113,1116.YIN R A,YE L X,ZHENG S W,et al.,2018.Potassium content and accumulation characteristics of three kinds of bamboos with different underground stem morphology[J].Journal of Zhejiang Agricultural Sciences,59(7):1111-1113,1116.
张学权,2013.不同遮荫条件下牛鞭草生长特征分析[J].成都大学学报(自然科学版),32(1):12-14.ZHANG X Q,2013.Growth characteristics analysis of Hemarthria altissima different shading degrees[J].Journal of Chengdu University(Natural Science Edition),32(1):12-14.
张志坚,高健,蔡春菊,等,2011.铅胁迫下菲白竹的矿质营养吸收和分配[J].林业科学,47(1):153-157.ZHANG Z J,GAO J,CAI C J,et al.,2011.Absorption and distribution of mineral nutrients in Pleioblastus fortunei under lead stress[J].Scientia Silvae Sinicae,47(1):153-157.
周建军,周桔,冯仁国,2014.我国土壤重金属污染现状及治理战略[J].中国科学院院刊,29(3):315-320,350,272.ZHOU J J,ZHOU J,FENG R G,2014.Status of China's heavy metal contamination in soil and its remediation strategy[J].Bulletin of Chinese Academy of Sciences,29(3):315-320,350,272.
BROADLEY M R,WHITE P J,HAMMOND J P,et al.,2007.Zinc in plants[J].New Phytol,173(4):677-702.
CHANDRA R,KUMAR V,TRIPATHI S,et al.,2018.Heavy metal phytoextraction potential of native weeds and grasses from endocrine-disrupting chemicals rich complex distillery sludge and their histological observations during in-situ phytoremediation[J].Ecological Engineering,111:143-156.
CHEN J R,SHAFI M,LI S,et al.,2015.Copper induced oxidative stresses,antioxidant responses and phytoremediation potential of moso bamboo(Phyllostachys pubescens)[J].Scientific Reports,5:2045-2322.
COLLIN B,DOELSCH E,KELLER C,et al.,2012.Distribution and variability of silicon,copper and zinc in different bamboo species[J].Plant and Soil,351(1-2):377-387.
COLLIN B,DOELSCH E,KELLER C,et al.,2013.Effects of silicon and copper on bamboo grown hydroponically[J].Environmental Science and Pollution Research,20(9):6482-6495.
DAS M,BHATTACHARYA S,SINGH P,et al.,2008.Bamboo taxonomy and diversity in the era of molecular markers[J].Botanical Research:Incorporating Advances in Plant Pathology,47:225-268.
FLORIJIN P J,VAN BEUSICHEM M L,1993.Uptake and distribution of cadmium in maize inbred lines[J].Plant Soil,150(1):25-32.
JORGE R A,ARRUDA M P,2001.Probing the role of camodulin in Al toxicity in maize[J].Phytochemistry,58:415-422.
KLEINHENZ V,MIDMORE D J,2001.Aspects of bamboo agronomy[J].Advances in Agronomy,74:99-153.
LI J T,GURAJALA H K,WU L H,et al.,2018.Hyperaccumulator plants from China:a synthesis of the current state of knowledge[J].Environmental Science&Technology,52:1-66.
LI J,LEISNER M,FRANTZ J,2008.Alleviation of copper toxicity in Arabidopsis thaliana by silicon addition to hydroponic solutions[J].Journal of the American Society for Horticultural Science American Society for Horticultural Science,133(5):670-677.
LI S,ISLAM E,PENG D L,et al.,2015.Accumulation and localization of cadmium in moso bamboo(Phyllostachys pubescens)grown hydroponically[J].Acta Physiol Plant,37(3):56-62.
LI S,CHEN J R,ISLAM E,et al.,2016.Cadmium-induced oxidative stress,response of antioxidants and detection of intracellular cadmium in organs of moso bamboo(Phyllostachys pubescens)seedlings[J].Chemosphere,153:107-114.
MERCHANT S,BRIGGS W R,ORT D,2010.Metal hyperaccumulation in plants[J].Annual Review of Plant Biology,61:517-534.
REEVES R D,BAKER A J M,2000.Metal-accumulating plants[J].Phytoremediation of toxic metals,12:193-229.
SCANDALIOS J G,1993.Oxygen stress and superoxide dismutases[J].Plant Physiol,101(1):7-12.
SEREGIN I V,IVANOV V B,2001.Physiological aspects of cadmium and lead toxic effects on higher plants[J].Russian Journal of plant physiology,48(4):523-544.
TANG S R,WILKE B M,HUANG C Y,1999.The uptake of copper by plants dominantly growing on copper mining spoils along the Yangtze River,the People’s Republic of China[J].Plant and Soil,209(2):225-232.
WANG S F,ZHAO Y,GUO J H,et al.,2016.Effects of Cd,Cu and Zn on Ricinus communis L.growth in single element or co-contaminated soils:Pot experiments[J].Environmental Ecology,90:347-351.
WERE F H,WAFULA G A,WAIRUNGU S,2017.Phytoremediation using bamboo to reduce the risk of chromium exposure from a contaminated tannery site in Kenya[J].Journal of health&pollution,7(16):12-25.
YANG W H,ZHANG T X,LI S L,et al.,2014.Metal removal from and microbial property improvement of a multiple heavy metals contaminated soil by phytoextraction with a cadmium hyperaccumulator Sedum alfredii H.[J].Journal of Soils and Sediments,14(8):1385-1396.
ZHANG X H,LIU J,WANG D Q,et al.,2009.Bioaccumulation and chemical Form of chromium in Leersia hexandra Swartz[J].Bulletin of Environmental Contamination and Toxicology,82(3):358-362.
ZHONG B,CHEN J R,SHAFI M,et al.,2017.Effect of lead(Pb)on antioxidation system and accumulation ability of moso bamboo(Phyllostachys pubescens)[J].Ecotoxicology and Environmental Safety,138:71-77.
ZHOU G M,MENG C F,JIANG P K,et al.,2011.Review of carbon fixation in bamboo forests in China[J].Botanical Review,77(3):262-270.
陈能场,郑煜基,何晓峰,等,2017.《全国土壤污染状况调查公报》探析[J].农业环境科学学报,36(9):1689-1692.CHEN N C,ZHENG Y J,HE X F,et al.,2017.Analysis of the bulletin of national soil pollution survey[J].Journal of Agro-Environment Science,36(9):1689-1692.
杜俊杰,周启星,李娜,等,2018.超积累植物修复重金属污染土壤的研究进展[J].贵州农业科学,46(5):64-72.DU J J,ZHOU Q X,LI N,et al.,2018.Progress in remediation of heavy metal contaminated soil by hyperaccumulator[J].Guizhou Agricultural Sciences,46(5):64-72.
方其仙,李元,祖艳群,等,2012.圆叶无心菜对Pb的吸收累积特征研究[J].环境科学与技术,35(5):121-126.FANG Q X,LI Y,ZU Y Q,et al.,2012.Accumulation characteristics of Arenaria rotumdifolia Bieberstein to Pb[J].Environmental Science&Technology,35(5):121-126.
高洁,刘文英,陈卫军,2012.电镀污染区植物对复合重金属的富集、转移和对污染土壤的修复潜力[J].生态与农村环境学报,28(4):468-472.GAO J,LIU W Y,CHEN W J,2012.Potentials of plants growing in contaminated soils nearby electroplating plants for accumulating and translocating heavy metals and remedying the soils[J].Journal of Ecology and Rural Environment,28(4):468-472.
管铭,裴立,郭水良,等,2010.假稻对铬的富集作用及其耐受能力研究[J].环境科学与管理,35(3):125-130.GUAN M,PEI L,GUO S L,et al.,2010.On bioaccumulation and endurance of Leersia japonica to chromium[J].Environmental Science and Management,35(3):125-130.
郭绪虎,肖德荣,田昆,等,2013.滇西北高原纳帕海湿地湖滨带优势植物生物量及其凋落物分解[J].生态学报,33(5):1425-1432.GUO X H,XIAO D R,TIAN K,et al.,2013.Biomass production and litter decomposition of lakeshore plants in Napahai wetland,northwestern Yunnan Plateau,China[J].Acta Ecologica Sinica,33(5):1425-1432.
胡鹏杰,李柱,钟道旭,等,2014.我国土壤重金属污染植物吸取修复研究进展[J].植物生理学报,50(5):577-584.HU P J,LI Z,ZHONG D X,et al.,2014.Research progress on the phytoextraction of heavy metal contaminated soils in China[J].Plant Physiology Journal,50(5):577-584.
姜黎,2009.几种竹对过量Cu胁迫的生理适应性研究[D].南京:南京农业大学:1-57.JIANG L,2009.Research on the physiological adaptability of bamboo stressed by excess copper[D].Nanjing:Nanjing Agricultural University:1-57.
金忠民,李丹,潘林,等,2016.抗性菌株JB13强化高羊茅对铅镉的富集[J].北方园艺(9):75-78.JIN Z M,LI D,PAN L,et al.,2016.Resistant strains of JB13 enhanced enrichment of lead and cadmium in Festuca ovina[J].Northern Horticulture(9):75-78.
李娟,高健,2016.黄条金刚竹、阔叶箬竹和菲白竹在干旱、冻害和重金属Pb胁迫下光合生理响应研究[J].竹子研究汇刊,35(1):22-29.LI J,GAO J,et al.,2016.Photosynthetic and physiological responses to drought,cold and Pb stresses in Pleioblastus kongosanensi,Indocalamus latifolius and Sasa fortune[J].Journal of Bamboo Research,35(1):22-29.
刘威,束文圣,蓝崇钰,2003.宝山堇菜(Viola baoshanensis):一种新的镉超富集植物[J].科学通报,48(19):2046-2049.LIU W,SHU W S,LAN C Y,et al.,2003.Viola baoshanensis:A new cadmium rich plant[J].Bulletin of Science and Technology,48(19):2046-2049.
刘小红,2005.九华铜矿重金属污染调查及耐铜植物的筛选、耐性机理研究[D].合肥:安徽农业大学:1-77.LIU X H,2005.Heavy metal contamination and copper tolerant plants in the vicinity of Jiuhua copper mine[D].Hefei:Anhui Agricultural University:1-77.
龙新宪,倪吾钟,叶正钱,等,2006.超积累生态型东南景天吸收锌的特性[J].生态学报,26(2):334-340.LONG X X,NI W Z,YE Z Q,et al.,2006.The characteristic of Zn uptake by the hyperaccumulating ecotype of Sedum alfredii Hance[J].Acta Ecologica Sinica,26(2):334-340.
陆静,2018.西南地区农业土壤污染状况及防治对策建议[J].南方农业,12(16):83-86.LU J,2018.The situation of agricultural soil pollution and countermeasures in southwest China[J].Southern agriculture,12(16):83-86.
罗于洋,赵磊,王树森,2010.铅超富集植物密毛白莲蒿对铅的富集特性研究[J].西北林学院学报,25(5):37-40.LUO Y Y,ZHAO L,WANG S S,et al.,2010.Absorption characteristics of Artemisia sacrorum var.messerschmidtiana to lead[J].Journal of Northwest Forestry University,25(5):37-40.
乔云蕾,2016.几种植物对土壤重金属镉、铬污染的修复潜力研究[D].金华:浙江师范大学:1-53.QIAO Y L,2016.Study on remedial of Cd and Cr contamination in soil by several plants[D].Jinhua:Zhejiang Normal University:1-53.
时宇,冉珊珊,黄黄,等,2018.黄石国家矿山公园草本植物重金属富集能力研究[J].生态环境学报,27(4):769-775.SHI Y,RAN S S,HUANG H,et al.,2018.Enrichment capability of herbaceous plants in Huangshi national mine park[J].Ecology and Environmental Sciences,27(4):769-775.
汪前山,2017.董铺水库周边植被现状分析及恢复建议[J].安徽水利水电职业技术学院学报,17(3):14-16.WANG Q S,2017.Status assessments and recovery recommendations of the plants around the Dongpu reservior[J].Journal of Anhui Technical College of Water Resources and Hydroelectric Power,17(3):14-16.
王兵,2011.竹子对重金属铅镉的累积规律及耐抗性研究[D].泰安:山东农业大学:1-78.WANG B,2011.Study of heavy metals lead and cadmium on the accumulation and tolerance of bamboos[D].Taian:Shandong Agricultural University:1-78.
王开运,2004.川西亚高山森林群落生态系统过程[M].成都:四川科学技术出版社:23-55.WANG K Y,2004.Ecosystem process of subalpine forest community in western Sichuan[M].Chengdu:Sichuan Science and Technology Press:23-55.
吴开贤,陈蕴,赵玲,等,2010.修剪干扰下高羊茅的生长与生物量分配[J].云南农业大学学报,25(1):102-106.WU K X,CHEN Y,ZHAO L,et al.,2010.The growth and biomass allocation of Festuca ovina under clipping disturbance[J].Journal of Yunnan Agricultural University,25(1):102-106.
谢丽萍,李焘,蒋翠文,等,2018.重金属镉、汞、铜和铅在荸荠体内的累积特性研究[J].西南农业学报,31(8):1712-1716.XIE L P,LI T,JIANG C W,et al.,2018.Study on accumulation characteristics of heavy metals of cadmium,mercury,copper and lead in Heleocharis dulcis[J].Southwest China Journal of Agricultural Sciences,31(8):1712-1716.
杨肖娥,龙新宪,倪吾钟,等,2002.东南景天(Sedumalfredii H):一种新的锌超积累植物[J].科学通报,47(13):1003-1006.YANG X E,LONG X X,NI W Z,et al.,2002.Sedumalfredii H:A new zinc hyperaccumulator plant[J].Bulletin of Science and Technology,47(13):1003-1006.
姚婧,陈雪梅,王友保,2008.Pb污染土壤对高羊茅种子萌发及幼苗生长的影响[J].上海交通大学学报(农业科学版),26(1):61-65.YAO J,CHEN X M,WANG Y B,2008.Effects of soils contaminated by lead on germination and seedling growth of festuca arundinacea L.[J].Journal of Shanghai Jiaotong University(Agricultural Science),26(1):61-65.
易同培,史军义,马丽莎,等,2008.中国竹类图志[M].北京:科学出版社:21-33.YI T P,SHI J Y,MA L S,et al.,2008.Chinese bamboo pictorial[M].Beijing:Science Press:21-33.
杨兵,廖斌,邓冬梅,等,2004.Cu2+对两种生态型鸭跖草Cu积累和抗氧化酶的影响[J].中国环境科学,24(1):10-14.YANG B,LIAO B,DENG D M,et al.,2004.Effect of Cu2+on Cu accumulation and antioxidative enzymes of two ecotype of Commelina communis[J].China Environmental Science,24(1):10-14.
尹瑞安,叶柳欣,郑世伟,等,2018.3种不同地下茎形态竹子的钾含量及积累特征[J].浙江农业科学,59(7):1111-1113,1116.YIN R A,YE L X,ZHENG S W,et al.,2018.Potassium content and accumulation characteristics of three kinds of bamboos with different underground stem morphology[J].Journal of Zhejiang Agricultural Sciences,59(7):1111-1113,1116.
张学权,2013.不同遮荫条件下牛鞭草生长特征分析[J].成都大学学报(自然科学版),32(1):12-14.ZHANG X Q,2013.Growth characteristics analysis of Hemarthria altissima different shading degrees[J].Journal of Chengdu University(Natural Science Edition),32(1):12-14.
张志坚,高健,蔡春菊,等,2011.铅胁迫下菲白竹的矿质营养吸收和分配[J].林业科学,47(1):153-157.ZHANG Z J,GAO J,CAI C J,et al.,2011.Absorption and distribution of mineral nutrients in Pleioblastus fortunei under lead stress[J].Scientia Silvae Sinicae,47(1):153-157.
周建军,周桔,冯仁国,2014.我国土壤重金属污染现状及治理战略[J].中国科学院院刊,29(3):315-320,350,272.ZHOU J J,ZHOU J,FENG R G,2014.Status of China's heavy metal contamination in soil and its remediation strategy[J].Bulletin of Chinese Academy of Sciences,29(3):315-320,350,272.
© 2004-2018 中国地质图书馆版权所有 京ICP备05064691号 京公网安备11010802017129号 地址:北京市海淀区学院路29号 邮编:100083 电话:办公室:(+86 10)66554848;文献借阅、咨询服务、科技查新:66554700 |