«ÉÏһƪ/Previous Article|±¾ÆÚĿ¼/Table of Contents|ÏÂһƪ/Next Article»

¡¶½­ËÕÅ©Òµ¿Æѧ¡·[ISSN:1002-1302/CN:32-1214/S]

¾í:

µÚ42¾í

ÆÚÊý:

2014Äê05ÆÚ

Ò³Âë:

301-305

À¸Ä¿:

×ÊÔ´Óë»·¾³

³ö°æÈÕÆÚ:

2014-05-25

ÎÄÕÂÐÅÏ¢/Info

Title:

Effect of afforestation on soil organic carbon reserve£ºa review

×÷Õß:

¸ßÑî;  ºúÕñç÷;  ФÎä;  ÓàÑó;  Ôø¼ÍÓÂ

Öйú¿óÒµ´óѧ(±±¾©)ÍÁµØ¸´¿ÑÓëÉú̬Öؽ¨Ñо¿Ëù/¿óɽÉú̬°²È«½ÌÓý²¿¹¤³ÌÑо¿ÖÐÐÄ£¬±±¾© 100083

Author(s):

Gao Yang; et al

¹Ø¼ü´Ê:

ÔìÁÖ; ÍÁÈÀÓлú̼; ÍÁµØÀûÓÃÀàÐÍ; Î³¶È±ä»¯; ÍÁÈÀÀàÐÍ; Ê÷ÖÖÑ¡Ôñ

Keywords:

-

·ÖÀàºÅ:

A

DOI:

-

ÎÄÏ×±êÖ¾Âë:

S153.6+2£»S714.5

ÕªÒª:

ÔìÁÖ×÷ΪһÖÖÖØÒªµÄÔö¼Ó̼»ã·½Ê½ÒѾ­»òÕýÔÚ±»ºÜ¶à¹ú¼ÒÓ¦Ó㬵«ÊÇÔìÁÖºóÍÁÈÀÓлú̼¿â´¢Á¿µÄ±ä»¯ºÍÓ°ÏìÒòËØÉв»Ã÷È·¡£ÔÚ×ܽáÁ˽üÄêÀ´µÄÏà¹ØÎÄÏ׺óÈÏΪ£ºÔìÁÖÇ°ÍÁµØÀûÓÃÀàÐÍ¡¢Î³¶È±ä»¯¡¢ÍÁÈÀÀàÐͺÍÊ÷ÖÖÑ¡Ôñ¶¼ÄܶÔÔìÁÖºóÍÁÈÀÓлú̼´¢Á¿µÄ±ä»¯²úÉúÖØÒªÓ°Ï죻ũÌïºÍÂãµØÔìÁÖºóÍÁÈÀÓлú̼»ãÏÔÖøÔö¼Ó£¬²ÝµØÔìÁÖºóÍÁÈÀÓлú̼±ä»¯µÄ²»È·¶¨ÐÔÊÇÓÉÁÖÁäµÄ²»Í¬µ¼Öµģ»Î´øµØÇøÔìÁÖºóÍÁÈÀÓлú̼»ã¿ìËÙÔö¼Ó£¬Ëæ×Åγ¶ÈµÄÉÏÉý£¬ÔìÁÖºóÍÁÈÀÓлú̼´¢Á¿ÏÈϽµºó´ïµ½»ò¸ßÓÚÔìÁÖÇ°µÄˮƽËùÐèÒªµÄʱ¼äÔ½À´Ô½³¤£»ÍÁÈÀð¤Á£Óë·ÛÁ£µÄº¬Á¿ÓëÔìÁÖºóÍÁÈÀÓлú̼¿â´¢Á¿³ÊÕýÏà¹Ø¹Øϵ£»Å©ÌïÔìÇÇľÁֺ͹àľÁÖÍÁÈÀÓлú̼´¢Á¿¶¼»áÏÔÖøÔö¼Ó£¬¶ø²ÝµØ×îºÃÑ¡ÔñÀ«Ò¶ÇÇľ£¬¹àľ¿ÉÒԹ㷺ӦÓÃÓÚÔìÁÖÇ°µÄ¸÷ÖÖÍÁµØÀûÓÃÀàÐÍ¡£

Abstract:

-

²Î¿¼ÎÄÏ×/References:

£Û1£ÝSchlesinger W H. Evidence from chronosequence studies for a low carbon-storage potential of soils£ÛJ£Ý. Nature£¬1990£¬348£º232-234.
£Û2£ÝJandl R£¬Lindner M£¬Vesterdal L£¬et al. How strongly can forest management influence soil carbon sequestration£¿£ÛJ£Ý. Geoderma£¬2007£¬137(3/4)£º253-268.
£Û3£ÝPaul K I£¬Polglase P J£¬Nyakuengama J G£¬et al. Change in soil carbon following afforestation£ÛJ£Ý. Forest ecology and management£¬2002£¬168(1/2/3)£º241-257.
£Û4£ÝWang C M£¬Ouyang H£¬Shao B£¬et al. Soil carbon changes following afforestation with Olga Bay larch(Larix olgensis Henry)in northeastern China£ÛJ£Ý. Journal of Integrative Plant Biology£¬2006£¬48(5)£º503-512.
£Û5£ÝZhang K£¬Dang H£¬Tan S£¬et al. Change in soil organic carbon following the ¡®Grain-for-Green¡¯ programme in China£ÛJ£Ý. Land Degradation & Development£¬2010£¬21(1)£º13-23.
£Û6£ÝKalinina O£¬Goryachkin S V£¬Karavaeva N A£¬et al. Self-restoration of post-agrogenic sandy soils in the southern taiga of Russia£ºSoil development£¬nutrient status£¬and carbon dynamics£ÛJ£Ý. Geoderma£¬2009£¬152(1/2)£º35-42.
£Û7£ÝLi Y£¬Xu M£¬Zou X£¬et al. Comparing soil organic carbon dynamics in plantation and secondary forest in wet tropics in Puerto Rico£ÛJ£Ý. Global Change Biology£¬2005£¬11(2)£º239-248.
£Û8£ÝDeGryze S£¬Six J£¬Paustian K£¬et al. Soil organic carbon pool changes following land-use conversions£ÛJ£Ý. Global Change Biology£¬2004£¬10(7)£º1120-1132.
£Û9£ÝArevalo C£¬Bhatti J S£¬Chang S X£¬et al. Ecosystem carbon stocks and distribution under different land-uses in north central Alberta£¬Canada£ÛJ£Ý. Forest Ecology and Management£¬2009£¬257(8)£º1776-1785.
£Û10£ÝLemma B£¬Kleja D B£¬Nilsson I£¬et al. Soil carbon sequestration under different exotic tree species in the southwestern highlands of Ethiopia£ÛJ£Ý. Geoderma£¬2006£¬136(3/4)£º886-898.
£Û11£ÝMartens D A£¬Reedy T E£¬Lewis D T. Soil organic carbon content and composition of 130-year crop£¬pasture and forest land-use managements£ÛJ£Ý. Global Change Biology£¬2004£¬10(1)£º65-78.
£Û12£ÝTang X£¬Liu S£¬Liu J£¬et al. Effects of vegetation restoration and slope positions on soil aggregation and soil carbon accumulation on heavily eroded tropical land of Southern China£ÛJ£Ý. Journal of Soils and Sediments£¬2010£¬10(3)£º505-513.
£Û13£ÝYao S£¬Qin J£¬Peng X£¬et al. The effects of vegetation on restoration of physical stability of a severely degraded soil in China£ÛJ£Ý. Ecological Engineering£¬2009£¬35(5)£º723-734.
£Û14£ÝFu X£¬Shao M£¬Wei X£¬et al. Soil organic carbon and total nitrogen as affected by vegetation types in Northern Loess Plateau of China£ÛJ£Ý. Geoderma£¬2010£¬155(1)£º31-35.
£Û15£ÝLaik R£¬Kumar K£¬Das D K£¬et al. Labile soil organic matter pools in a calciorthent after 18 years of afforestation by different plantations£ÛJ£Ý. Applied Soil Ecology£¬2009£¬42(2)£º71-78.
£Û16£ÝSu Y Z£¬Wang X F£¬Yang R£¬et al. Effects of sandy desertified land rehabilitation on soil carbon sequestration and aggregation in an arid region in China£ÛJ£Ý. Journal of Environmental management£¬2010£¬91(11)£º2109-2116.
£Û17£ÝSartori F£¬Lal R£¬Ebinger M H£¬et al. Changes in soil carbon and nutrient pools along a chronosequence of poplar plantations in the Columbia Plateau£¬Oregon£¬USA£ÛJ£Ý. Agriculture£¬Ecosystems & Environment£¬2007£¬122(3)£º325-339.
£Û18£ÝDon A£¬Rebmann C£¬Kolle O£¬et al. Impact of afforestation-associated management changes on the carbon balance of grassland£ÛJ£Ý. Global Change Biology£¬2009£¬15(8)£º1990-2002.
£Û19£ÝDowell R C£¬Gibbins D£¬Rhoads J L. Biomass production physiology and soil carbon dynamics in short-rotation-grown Populus deltoides and P. deltoids¡ÁP. nigra hybrids£ÛJ£Ý. Forest Ecology and Management£¬2009£¬257(1)£º134-142.
£Û20£ÝKirschbaum M U F£¬Guo L B£¬Gifford R M. Observed and modelled soil carbon and nitrogen changes after planting a Pinus radiata stand onto former pasture£ÛJ£Ý. Soil Biology and Biochemistry£¬2008£¬40(1)£º247-257.
£Û21£ÝJim¨¦nez J J£¬Lal R£¬Russo R O£¬et al. The soil organic carbon in particle-size separates under different regrowth forest stands of north eastern Costa Rica£ÛJ£Ý. Ecological Engineering£¬2008£¬34(4)£º300-310.
£Û22£ÝThuille A£¬Schulze E D. Carbon dynamics in successional and afforested spruce stands in Thuringia and the Alps£ÛJ£Ý. Global Change Biology£¬2006£¬12(2)£º325-342.
£Û23£ÝChen F S£¬Zeng D H£¬Fahey T J£¬et al. Organic carbon in soil physical fractions under different-aged plantations of Mongolian pine in semi-arid region of Northeast China£ÛJ£Ý. Applied Soil Ecology£¬2010£¬44(1)£º42-48.
£Û24£ÝLima A£¬Silva I R£¬Neves J C L£¬et al. Soil organic carbon dynamics following afforestation of degraded pastures with eucalyptus in southeastern Brazil£ÛJ£Ý. Forest Ecology and Management£¬2006£¬235(1)£º219-231.
£Û25£ÝCharro E£¬Gallardo J F£¬Moyano A. Degradability of soils under oak and pine in Central Spain£ÛJ£Ý. European Journal of Forest Research£¬2010£¬129(1)£º83-91.
£Û26£ÝRichards A E£¬Dalal R C£¬Schmidt S. Soil carbon turnover and sequestration in native subtropical tree plantations£ÛJ£Ý. Soil Biology and Biochemistry£¬2007£¬39(8)£º2078-2090.
£Û27£ÝLuan J W£¬Xiang C H£¬Liu S R£¬et al. Assessments of the impacts of Chinese fir plantation and natural regenerated forest on soil organic matter quality at Longmen mountain£¬Sichuan£¬China£ÛJ£Ý. Geoderma£¬2010£¬156(3/4)£º228-236.
£Û28£ÝAshagrie Y£¬Zech W£¬Guggenberger G. Transformation of a Podocarpus falcatus dominated natural forest into a monoculture Eucalyptus globulus plantation at Munesa£¬Ethiopia£ºsoil organic C£¬N and S dynamics in primary particle and aggregate-size fractions£ÛJ£Ý. Agriculture£¬Ecosystems & Environment£¬2005£¬106(1)£º89-98.
£Û29£ÝZerva A£¬Ball T£¬Smith K A£¬et al. Soil carbon dynamics in a Sitka spruce(Picea sitchensis(Bong.)Carr.)chronosequence on a peaty gley£ÛJ£Ý. Forest Ecology and Management£¬2005£¬205(1/2/3)£º227-240.
£Û30£ÝZerva A£¬Mencuccini M. Carbon stock changes in a peaty gley soil profile after afforestation with Sitka spruce(Picea sitchensis)£ÛJ£Ý. Annals of Forest Science£¬2005£¬62(8)£º873-880.
£Û31£ÝMarin-Spiotta E£¬Silver W L£¬Swanston C W£¬et al. Soil organic matter dynamics during 80 years of reforestation of tropical pastures£ÛJ£Ý. Global Change Biology£¬2009£¬15(6)£º1584-1597.
£Û32£ÝEpron D£¬Marsden C£¬M¬ðBou A T£¬et al. Soil carbon dynamics following afforestation of a tropical savannah with Eucalyptus in Congo£ÛJ£Ý. Plant and soil£¬2009£¬323(1/2)£º309-322.
£Û33£Ývan der Kamp J£¬Yassir I£¬Buurman P. Soil carbon changes upon secondary succession in Imperata grasslands(East Kalimantan£¬Indonesia)£ÛJ£Ý. Geoderma£¬2009£¬149(1/2)£º76-83.
£Û34£ÝGupta N£¬Kukal S S£¬Bawa S S£¬et al. Soil organic carbon and aggregation under poplar based agroforestry system in relation to tree age and soil type£ÛJ£Ý. Agroforestry Systems£¬2009£¬76(1)£º27-35.
£Û35£ÝTurner J£¬Lambert M J£¬Johnson D W. Experience with patterns of change in soil carbon resulting from forest plantation establishment in eastern Australia£ÛJ£Ý. Forest Ecology and Management£¬2005£¬220(1/2/3)£º259-269.
£Û36£ÝHu Y L£¬Zeng D H£¬Fan Z P£¬et al. Changes in ecosystem carbon stocks following grassland afforestation of semiarid sandy soil in the southeastern Keerqin Sandy Lands£¬China£ÛJ£Ý. Journal of Arid Environments£¬2008£¬72(12)£º2193-2200.
£Û37£ÝPinno B D£¬B¨¦langer N. Ecosystem carbon gains from afforestation in the Boreal Transition ecozone of Saskatchewan(Canada)are coupled with the devolution of Black Chernozems£ÛJ£Ý. Agriculture£¬Ecosystems & Environment£¬2008£¬123(1/2/3)£º56-62.
£Û38£ÝLaganiere J£¬Angers D A£¬Pare D. Carbon accumulation in agricultural soils after afforestation£ºa meta-analysis£ÛJ£Ý. Global Change Biology£¬2010£¬16(1)£º439-453.
£Û39£ÝDel Galdo I£¬Six J£¬Peressotti A£¬et al. Assessing the impact of land-use change on soil C sequestration in agricultural soils by means of organic matter fractionation and stable C isotopes£ÛJ£Ý. Global Change Biology£¬2003£¬9(8)£º1204-1213.
£Û40£ÝSix J£¬Callewaert P£¬Lenders S£¬et al. Measuring and understanding carbon storage in afforested soils by physical fractionation£ÛJ£Ý. Soil Science Society of America journal£¬2002£¬66(6)£º1981-1987.
£Û41£ÝMorris S J£¬Bohm S£¬Haile-Mariam S£¬et al. Evaluation of carbon accrual in afforested agricultural soils£ÛJ£Ý. Global Change Biology£¬2007£¬13(6)£º1145-1156.
£Û42£ÝLemma B£¬Kleja D B£¬Olsson M£¬et al. Factors controlling soil organic carbon sequestration under exotic tree plantations£ºa case study using the CO₂ fix model in southwestern Ethiopia£ÛJ£Ý. Forest Ecology and Management£¬2007£¬252(1/2/3)£º124-131.
£Û43£ÝDube F£¬Zagal E£¬Stolpe N£¬et al. The influence of land-use change on the organic carbon distribution and microbial respiration in a volcanic soil of the Chilean Patagonia£ÛJ£Ý. Forest Ecology and Management£¬2009£¬257(8)£º1695-1704.
£Û44£ÝFarley K A£¬Kelly E F£¬Hofstede R G M. Soil organic carbon and water retention after conversion of grasslands to pine plantations in the Ecuadorian Andes£ÛJ£Ý. Ecosystems£¬2004£¬7(7)£º729-739.
£Û45£ÝPinno B D£¬B¨¦langer N. Ecosystem carbon gains from afforestation in the Boreal Transition ecozone of Saskatchewan(Canada)are coupled with the devolution of Black Chernozems£ÛJ£Ý. Agriculture£¬Ecosystems & Environment£¬2008£¬123(1/2/3)£º56-62.
£Û46£Ýde Koning G H J£¬Veldkamp E£¬Lopez-Ulloa M. Quantification of carbon sequestration in soils following pasture to forest conversion in northwestern Ecuador£ÛJ£Ý. Global Biogeochemical Cycles£¬2003£¬17(4)£º1098.
£Û47£ÝLiao J D£¬Boutton T W£¬Jastrow J D. Storage and dynamics of carbon and nitrogen in soil physical fractions following woody plant invasion of grassland£ÛJ£Ý. Soil Biology and Biochemistry£¬2006£¬38(11)£º3184-3196.
£Û48£ÝSilver W L£¬Kueppers L M£¬Lugo A E£¬et al. Carbon sequestration and plant community dynamics following reforestation of tropical pasture£ÛJ£Ý. Ecological Applications£¬2004£¬14(4)£º1115-1127.
£Û49£ÝUssiri D A N£¬Lal R£¬Jacinthe P A. Soil properties and carbon sequestration of afforested pastures in reclaimed minesoils of Ohio£ÛJ£Ý. Soil Science Society of America Journal£¬2006£¬70(5)£º1797-1806.
£Û50£ÝLiu X£¬Li F M£¬Liu D Q£¬et al. Soil organic carbon£¬carbon fractions and nutrients as affected by land use in semi-arid region of Loess Plateau of China£ÛJ£Ý. Pedosphere£¬2010£¬20(2)£º146-152.
£Û51£ÝWang S K£¬Zhao X Y£¬Qu H£¬et al. Effects of shrub litter addition on dune soil microbial community in horqin sandy land£¬Northern China£ÛJ£Ý. Arid Land Research and Management£¬2011£¬25(3)£º203-216.
£Û52£ÝHang G£¬Zhao X Y£¬Li Y Q£¬et al. Restoration of shrub communities elevates organic carbon in arid soils of northwestern China£ÛJ£Ý. Soil Biology and Biochemistry£¬2012£¬47£º123-132.
£Û53£ÝZhou Q L£¬Jiang D M£¬Liu Z M. The return and loss of litter phosphorus in different types of sand dunes in Horqin Sandy Land£¬northeastern China£ÛJ£Ý. Journal of Arid Land£¬2012£¬4(4)£º431-440.
£Û54£ÝYang Z P£¬Zhang Q£¬Wang Y L£¬et al. Spatial and temporal variability of soil properties under Caragana microphylla shrubs in the northwestern Shanxi Loess Plateau£¬China£ÛJ£Ý. Journal of Arid Environments£¬2011£¬75(6)£º538-544.
£Û55£ÝWu Y P£¬Hu X W£¬Wang Y R. Growth£¬water relations£¬and stomatal development of Caragana korshinskii Kom and Zygophyllum xanthoxylum(Bunge)Maxim. seedlings in response to water deficits£ÛJ£Ý. New Zealand Journal of Agricultural Research£¬2009£¬52(2)£º185-193.
£Û56£ÝNair P K R£¬Nair V D£¬Gama-Rodriguesa E£¬et al. Soil carbon in agro forestry systems:an unexplored treasure?£ÛC£Ý. £Û2013-12-01£Ý.http://www.researchgate.net/publication/40506514_Soil_Carbon_in_Agroforestry_Systems_An_Unexplored_Treasure.
£Û57£ÝDavis M£¬Nordmeyer A£¬Henley D£¬et al. Ecosystem carbon accretion 10 years after afforestation of depleted subhumid grassland planted with three densities of Pinus nigra£ÛJ£Ý. Global Change Biology£¬2007£¬13(7)£º1414-1422.

ÏàËÆÎÄÏ×/References:

[1]ëøά³¬,ÁõÉÙÐù,ÁõÐÂÁÁ,µÈ.²»Í¬ÖÖֲģʽ¶ÔÓͲè³ÉÁÖÍÁÈÀÓлú̼¼°Ñø·ÖÌØÕ÷µÄÓ°Ïì[J].½­ËÕÅ©Òµ¿Æѧ,2013,41(05):323.
¡¡Teng Weichao,et al.Influence of different planting modes on organic carbon and nutrient characteristics in soils of ª«Camellia oleiferaª« forest[J].Jiangsu Agricultural Sciences,2013,41(05):323.
[2]ºúÇìºØ,Ð캣·å,ÕÅÏ°Ãô,µÈ.²»Í¬¹ÜÀí·½Ê½¶Ô¹óÖݵäÐÍůÐԲݵØÍÁÈÀÓлú̼µÄÓ°Ïì[J].½­ËÕÅ©Òµ¿Æѧ,2015,43(03):330.
¡¡Hu Qinghe,et al.Effect of different managements on spatial and temporal variations of soil organic carbon in warm temperate grassland of Guizhou Province[J].Jiangsu Agricultural Sciences,2015,43(05):330.
[3]Áõѧ¶«,³ÂÁÖ,Àîѧ±ó,µÈ.²ÝµØÉú̬ϵͳÍÁÈÀÓлú̼´¢Á¿µÄ¹ÀËã·½·¨×ÛÊö[J].½­ËÕÅ©Òµ¿Æѧ,2016,44(08):10.
¡¡Liu Xuedong,et al.Estimation method of soil organic carbon reserves in grassland ecosystem£º a review[J].Jiangsu Agricultural Sciences,2016,44(05):10.
[4]ÖÜÓýÖÇ,³ÂТÑî,Íõ·¼,µÈ.°²»ÕÊ¡»´ÄÏÊвÉú³ÁÏÝÉú̬ÐÞ¸´Çø±í²ãÍÁÈÀÓлú̼·Ö²¼[J].½­ËÕÅ©Òµ¿Æѧ,2016,44(09):439.
¡¡Zhou Yuzhi,et al.Distribution of organic carbon in topsoil of ecological remediation areas of coal mining subsidence in Huainan£¬Anhui Province[J].Jiangsu Agricultural Sciences,2016,44(05):439.
[5]ÑîÊ¿ºì,ÁõÏþ¾²,ÂÞͯԪ,µÈ.ÉúÎïÌ¿Ê©ÓöԽÚË®¹à¸Èµ¾ÌïÎÂÊÒÆøÌåÅÅ·ÅÓ°ÏìÑо¿½øÕ¹[J].½­ËÕÅ©Òµ¿Æѧ,2016,44(10):5.
¡¡Yang Shihong,et al.Effect of biochar application on greenhouse gases emission in paddy fields under water-saving irrigation£ºa review[J].Jiangsu Agricultural Sciences,2016,44(05):5.
[6]Ëïϼ,¶Å¿¡Áú,»Æ³¤¸£,µÈ.µäÐ͸ɺµ»ÄÄ®ÂÌÖÞÇø²»Í¬ÄêÏÞÔæÔ°ÍÁÈÀ̼¿âÌØÕ÷[J].½­ËÕÅ©Òµ¿Æѧ,2016,44(10):484.
¡¡Sun Xia,et al.Soil organic carbon characteristics of jujube orchards with different years in typical arid desert oasis region[J].Jiangsu Agricultural Sciences,2016,44(05):484.
[7]ÃÏÎÄÎä,Ö£ÀûÑÇ,´Þ³Ï,µÈ.Î书ɽÍË»¯²ÝµéÑø·Ö·Ö²¼¸ñ¾Ö¼°Ïà¹ØÐÔ[J].½­ËÕÅ©Òµ¿Æѧ,2017,45(03):237.
¡¡Meng Wenwu,et al.Nutrient distribution pattern and its correlation of degraded meadow of Wugong Mountain[J].Jiangsu Agricultural Sciences,2017,45(05):237.
[8]κÃÍ,ÌÆÖÒºñ,ÕÅ°®¾ý,µÈ.³¤ÆÚ²»Í¬Ê©·Ê¶Ô³±ÍÁ΢ÉúÎïÁ¿Ì¼¡¢µªµÄÓ°Ïì[J].½­ËÕÅ©Òµ¿Æѧ,2020,48(22):307.
¡¡Wei Meng,et al.Effects of long-term fertilization on microbial biomass carbon and nitrogen in fluvo-aquic soil[J].Jiangsu Agricultural Sciences,2020,48(05):307.
[9]ÍõºÆ,ºúÃ÷»Û,²ÌÈï,µÈ.³¤½­ÖÐÏÂÓε¾ÌïÇòÄÒùËØÏà¹ØÍÁÈÀµ°°×·Ö²¼¸ñ¾Ö¼°Æä¶Ô»·¾³µÄÏìÓ¦[J].½­ËÕÅ©Òµ¿Æѧ,2022,50(23):192.
¡¡Wang Hao,et al.Distribution patterns and response to environment of glomalin-related soil proteins in paddy fields across the middle and lower reaches of the Yangtze River[J].Jiangsu Agricultural Sciences,2022,50(05):192.
[10]»Æ¿­ÎÄ,ÂíÕä,É»¾ýÔÂ,µÈ.ÍÁÈÀÓлú̼Ëðʧ»úÖÆÑо¿½øÕ¹[J].½­ËÕÅ©Òµ¿Æѧ,2022,50(24):26.
¡¡Huang Kaiwen,et al.Research progress on mechanism of soil organic carbon losses[J].Jiangsu Agricultural Sciences,2022,50(05):26.

±¸×¢/Memo

±¸×¢/Memo:

ÊÕ¸åÈÕÆÚ£º2013-12-31
»ù½ðÏîÄ¿£ºÖÐÑë¸ßУ»ù±¾¿ÆÑÐÒµÎñ·ÑרÏî×ʽð(±àºÅ£º2010YD03)¡£
×÷Õß¼ò½é£º¸ßÑî(1988¡ª)£¬Å®£¬É½¶«Óí³ÇÈË£¬²©Ê¿Ñо¿Éú£¬Ñо¿·½ÏòΪúí·Ê¯É½¸´¿ÑÓëÉú̬Öؽ¨¡£Tel£º(010)62339045£»E-mail£ºgyang1002@163.com¡£

³£Óù¦ÄÜ

¸üÐÂÈÕÆÚ/Last Update: 2014-05-25