内蒙古高原等地湖泊表层沉积物孢粉与植被覆盖度定量关系研究

doi:10.12118/j.issn.1000-6060.2019.05.06

Abstract

Abstract:

Vegetation cover was an important factor in palaeo-climate simulation.The study of pollen-vegetation cover transfer function based on modern processes provides a way to reconstruct the past vegetation cover change by using pollen stratum data.The Inner Mongolia Plateau and its adjacent area,which is located at the marginal monsoon area of northern China and has a large climatic and vegetal gradient,provides us an ideal area to study the pollen-vegetation cover transfer functions.In this paper,we investigated pollen assemblages of lake central surface sediment from 46 lakes and reservoirs,and developed transfer functions between lake surface sediment pollen assemblage and Normalized Difference Vegetation Index (NDVI) using three different methods which include weighted average partial least squares (WA-PLS),local weighted average method (LWWA) and modern analogue technique (MAT).We used leave-one-out cross-validation,bootstrapping and autocorrelation test to evaluate the performance of those three pollen-NDVI transfer functions and select the most reliable to reconstruct the Holocene vegetation cover history of Huitengxile Plateau of central Inner Mongolia.As results,the redundancy analysis (RDA) was conducted on the pollen data and environmental data according to the linear data type of the pollen data,as indicated by the gradient length (i.e.,2.047) of the detrended correspondence analysis (DCA).The RDA plot displays that the NDVI points to the positive of the first axis where forest and forest steppe sites clustered,and has smaller angles with the Pinus and Betula and larger angles with the desert pollen type such as Nitraria,Ephedra and Tamaricaeae,which suggested that the NDVI index was closely related to the spatial distribution of pollen and thus the pollen-NDVI transfer functions could be reliably developed.The leave-one-out cross-validation and the bootstrapping test showed that the LWWA_Inv (R²_jack=0.57, R²_boot=0.57) and WA-PLS-3 (R²_jack=0.56, R²_boot=0.54) models have better performance than the MAT (R²_jack=0.53, R²_boot=0.58) model.The autocorrelation test suggests that both MAT model and WA-PLS model are greatly affected by spatial autocorrelation,and thus not suitable to develop pollen-NDVI transfer function.Therefore,the LWWA Inv model is suitable to reconstruct the past vegetation cover history (NDVI) for its overall good performance,and was used to reconstructed the NDVI history of Huitengxile Plateau of Inner Mongolia by applying to a fossil pollen record of a lacustrine sections from a unnamed small crater lake.The comparison shows there are broad consistence between pollen reconstructed NDVI and other pollen-based vegetation (i.e.,biome score in this paper),which further demonstrated the reliability of our pollen-NDVI transfer functions.Furthermore,we compared those regional vegetation evolution with those non-pollen based Holocene temperature and precipitation sequences.The result shows that the pollen-based vegetation sequences were correlated well with the non-pollen based precipitations but not correlated with regional temperature sequences,which possibly indicated the Holocene vegetation change was closely responded to precipitation but temperature in marginal monsoon area of northern China.

Key words: font-size:10.5pt, Inner Mongolia Plateau')">">Inner Mongolia Plateau, lake surface sediment, pollen assemblage, vegetation coverage, font-size:10.5pt, NDVI')">">NDVI, font-size:10.5pt, transfer function')">">transfer function

CHEN Dong-xue, WANG Wei, LIU Li-na, JIANG Ya-juan, LI Yan-yan, NIU Zhi-mei, MA Yu-zhen, HE Jiang. Lake central surface sediment-based pollen-vegetation cover transfer functions and its application in Inner Mongolia Plateau and adjacent area[J].Arid Land Geography, 2019, 42(5): 1011-1022.

0
/ / Recommend Inner Mongolia Plateau; lake surface sediment; pollen assemblage; vegetation coverage;NDVI;transfer function”. Please open it by linking:http://alg.xjegi.com/EN/abstract/abstract9576.shtml" name="neirong"> Inner Mongolia Plateau; lake surface sediment; pollen assemblage; vegetation coverage;NDVI;transfer function">

Add to citation manager EndNote|Reference Manager|ProCite|BibTeX|RefWorks

URL: http://alg.xjegi.com/EN/10.12118/j.issn.1000-6060.2019.05.06

http://alg.xjegi.com/EN/Y2019/V42/I5/1011

References ［48］

［1］	朱家文.IAP-DGVM和CoLM的耦合与模拟以及植被对气候的反馈作用研究［D］.北京:中国科学院大学,2014.［ZHU Jiawen. Studies of coupling IAP-DGVM with CoLM and the feedbacks of vegetation on climate［D］. Beijing:University of Chinese Academy of Sciences,2014.］
［2］	沈晓燕,张宇,王少影,等.若尔盖高原典型年份植被覆盖变化对2010年区域气候影响的数值模拟［J］.气候与环境研究,2015,20(4):443-453.［SHEN Xiaoyan,ZHANG Yu,WANG Shaoying,et al.A numerical simulation of the impact of vegetation cover changes in the Zoigê Plateau in typical years on the regional climate in 2010［J］.Climatic and Environmental Research,2015,20(4):443-453.］
［3］	TARASOV P E,WEBB T,ANDREEV A A,et al.Presentday and midHolocene biomes reconstructed from pollen and plant macrofossil data from the former Soviet Union and Mongolia［J］.Journal of Biogeography,1998,25(6):1029-1053.
［4］	HERZSCHUH U,BIRKS H J B,JIAN N,et al.Holocene land-cover changes on the Tibetan Plateau［J］.Holocene,2010,20(1):91-104.
［5］	LIU G,YIN Y,LIU H Y,et al.Quantifying regional vegetation cover variability in North China during the Holocene:Implications for climate feedback［J］.Plos One,2013,8(8):e71681.
［6］	TIAN F,CAO X Y,DALLMEYER A,et al.Quantitative woody cover reconstructions from eastern continental Asia of the last 22 kyr reveal strong regional peculiarities［J］.Quaternary Science Reviews,2016,137(137):33-44.
［7］	TARASOV P,WILLIAMS J W,ANDREEV A,et al.Satellite and pollen-based quantitative woody cover reconstructions for Northern Asia:Verification and application to late-Quaternary pollen data［J］.Earth & Planetary Science Letters,2007,264(1):284-298.
［8］	刘立娜,王维,马玉贞,等.呼伦湖表层沉积物花粉空间分布特征及影响因素探讨［J］.沉积学报,2015,33(4):744-753.［LIU Lina,WANG Wei,MA Yuzhen,et al.Spatial distribution characteristics and environmental influencing factors of pollen assemblage of lake surface sediments from Lake Hulun［J］.Acta Sedimentologica Sinica,2015,33(4):744-753.］
［9］	SUGITA S.Pollen representation of vegetation in quaternary sediments:Theory and method in patchy vegetation［J］.Journal of Ecology,1994,82(4):881-897.
［10］	COLIN P I.Pollen representation,source area,and basin size:Toward a unified theory of pollen analysis［J］.Quaternary Research,1985,23(1):76-86.
［11］	李岩岩.内蒙古辉腾锡勒地区13980~4820 cal.yr BP植被和气候变化研究［D］.呼和浩特:内蒙古大学,2014.［LI Yanyan.Vegetation and climate changed during 13980~4820 cal.yr BP in Huitengxile area of Inner Mongolia,a multiple indicator investigation of lake sediment of HTL［D］. Hohhot:Inner Mongolia University,2014.］
［12］	秦伟,朱清科,张学霞,等. 植被覆盖度及其测算方法研究进展［J］. 西北农林科技大学学报(自然科学版),2006,34(9):163-170.［QIN Wei,ZHU Qingke,ZHANG Xuexia,et al.Review of vegetation covering and its measuring and calculating method［J］.Journal of Northwest A&F University (Natural Science Edition),2006,34(9):163-170.］
［13］	周兆叶,储少林,王志伟,等. 基于NDVI的植被覆盖度的变化分析——以甘肃省张掖市甘州区为例［J］. 草业科学,2008,25(12):23-29.［ZHOU Zhaoye,CHU Shaolin,WANG Zhiwei,et al.Analysis of vegetation coverage change based on NDVI:A case study in Ganzhou Area,Zhangye City,Gansu［J］.Pratacultural Science,2008,25(12):23-29.］
［14］	FANG J Y,PIAO S L,HE J S,MA W H.Increasing terrestrial vegetation activity in China,1982—1999［J］.Science in China,2004,47(3):229-240.
［15］	LI Z T,KAFATOS M.Interannual variability of vegetation in the United States and its relation to El Ni[AKn~D]o/Southern Oscillation［J］.Remote Sensing of Environment,2000,71(3):239-247.
［16］	CHOUDHURY B J,AHMED N U,IDSO S B,et al.Relations between evaporation coefficients and vegetation indices studied by model simulations［J］.Remote Sensing of Environment,1994,50(1):1-17.
［17］	GILLIES R R,KUSTAS W P,HUMES K S.A verification of the “triangle” method for obtaining surface soil water content and energy fluxes from remote measurements of the Normalized Difference Vegetation Index (NDVI) and surface e［J］.International Journal of Remote Sensing,1997,18(15):3145-3166.
［18］	KOBAYASHI,HIDEKI,DENNIS G.Atmospheric conditions for monitoring the longterm vegetation dynamics in the Amazon using normalized difference vegetation index［J］.Remote Sensing of Environment,2005,97(4):519-525.
［19］	CIHLAR J,LY H,LI Z Q,et al.Multitemporal,multichannel AVHRR data sets for land biosphere studies:Artifacts and corrections［J］.Remote Sensing of Environment,1997,60(1):35-57.
［20］	耿丽英,马明国.长时间序列[WTBX]NDVI[WTBZ]数据重建方法比较研究进展［J］.遥感技术与应用,2014,29(2):362-368.［GENG Liying,MA Mingguo.Advance in method comparison of reconstructing remote sensing time series data sets［J］.Remote Sensing Technology and Application,2014,29(2):362-368.］
［21］	盛承禹.中国气候总论［M］.北京:科学出版社,1986.［SHENG Chengyu.China climate pandect［M］.Beijing:Science Press,1986.］
［22］	中国科学院中国植被图编辑委员会.中国植被图集［M］.北京:科学出版社,2001.［Chinese Vegetation Map Editorial Committee of the Chinese Academy of Sciences.Chinese vegetation atlas［M］.Beijing:Science Press,2001.］
［23］	WCS/CIESN.Last of the wild data version 2:Global human influence index(HII)［DB/OL］.New York:Wildlife Conservation Society (WCS) and Center for International Earth Science Information Network (CIESIN).［2018-11-09］.http://sedac.ciesin.columbia.edu/data/set/wildareas-v2-human-nfluence-index-geographic.
［24］	SANDERSON E W,LEVY M J A,REDFORD K H,et al.The human footprint and the last of the wild［J］.Bioscience,2002,52(10):891-904.
［25］	LI J Y,ZHAO Y,XU Q H,et al.Human influence as a potential source of bias in pollenbased quantitative climate reconstructions［J］.Quaternary Science Reviews,2014,99:112-121.
［26］	BROOKS S J.A 1000-year chironomid-based salinity reconstruction from varved sediments of Sugan Lake,Qaidam Basin,arid Northwest China,and its palaeoclimatic significance［J］.Chinese Science Bulletin,2009,54(20):3749-3759.
［27］	ZHAO Y,YU Z C,CHEN F H,et al.Sensitive response of desert vegetation to moisture change based on a near-annual resolution pollen record from Gahai Lake in the Qaidam Basin,Northwest China［J］.Global & Planetary Change,2008,62(1):107-114.
［28］	VIDAL G.A palynological preparation method［J］.Palynology,1988,12(1):215-220.
［29］	李文漪,肖尚明,刘光琇,等.花粉分析指南［M］.广西:广西人民出版社,1987.［LI Wenxi,XIAO Shangming,LIU Guanxiu,et al.Guide to pollen analysis［M］.Guangxi:Guangxi People Press,1987.］
［30］	宛涛,卫智军,杨静,等.内蒙古草地现代植物花粉形态［M］.北京:中国农业出版社,1999:1-135.［WAN Tao,WEI Zhijun,YANG Jing,et al.Flora of grassland modern pollen Inner Mongolia［M］.Beijing:China Agriculture Press,1999:1-135.］
［31］	王伏雄,钱南芬,张玉龙,等.中国植物花粉形态［M］.2版.北京:科学出版社,1995.［WANG Fuxiong,QIAN Nanfeng,ZHANG Yulong,et al.Pollen flora of China［M］.2nd ed.Beijing:Science Press,1995.］
［32］	王亚军,马玉贞,鲁瑞洁,等.祁连山东延余脉——兴隆山树木径向生长记录的公元1845年来夏季NDVI变化［J］.地理研究,2016,35(4):653-663.［WANG Yajun,MA Yuzhen,LU Ruijie,et al.Summer NDVI variability recorded by tree radial growth in the Xinglong Mountain,the eastward extension of the Qilian Mountains,since 1845 AD［J］.Geographical Research,2016,35(4):653-663.］
［33］	HILL M O,GAUCH H G.Detrended correspondence analysis:An improved ordination technique［J］.Vegetation,1980,42(1/3):47-58.
［34］	JUGGINS S.C2 Version 1.5:Software for ecological and palaeoecological data analysis and visualisation［M］.Newcastle upon Tyne:Newcastle University Press,2007.
［35］	HALL P,WILSON S R.Two guidelines for bootstrap hypothesis testing［J］.Biometrics,1991,47(2):757-762.
［36］	TELFORD R,BIRKS H.Evaluation of transfer functions in spatially structured environments［J］.Quaternary Science Reviews,2009,28(13):1309-1316.
［37］	TELFORD R,TRACHSEL M.Palaeo Sig:Significance tests for palaeoenvironmental reconstructions,R package version 1.1-3［M］.Bergen:University of Bergen Press,2015.
［38］	LEPS J,SMILAUER P.Multivariate analysis of ecological data using CANOCO［M］.New York:Cambridge University Press,2003.
［39］	JUGGINS S,BIRKS H J B.Quantitative environmental reconstructions from biological data［M］.Dordrecht:Springer Netherlands Press,2012.
［40］	JUGGINS S.The European diatom database(EDDI):A new tool for palaeoenvironmental reconstruction［M］.Newcastle upon Tyne:Newcastle University Press,2001.
［41］	CHEN F,XU Q,CHEN J,et al.East Asian summer monsoon precipitation variability since the last deglaciation［J］.Scientific Reports,2015,5(1):11186.
［42］	WEN R L,XIAO J L,CHANG Z G,et al.Holocene climate changes in the mid-high-latitude-monsoon margin reflected by the pollen record from Hulun Lake,Northeastern Inner Mongolia［J］.Quaternary Research,2010,73(2):293-303.
［43］	XIAO J L,XU Q H,NAKAMURA T,et al.Holocene vegetation variation in the Daihai Lake region of North-Central China:A direct indication of the Asian monsoon climatic history［J］.Quaternary Science Reviews,2004,23(14):1669-1679.
［44］	WEN R L,XIAO J L,FAN J W,et al.Pollen evidence for a mid-Holocene East Asian summer monsoon maximum in Northern China［J］.Quaternary Science Reviews,2017,17(6):29-35.
［45］	MARCOTT S A,SHAKUN J D,CLARK P U,et al.A reconstruction of regional and global temperature for the past 11300 years［J］.Science,2013,339(6 124):1198-1201.
［46］	JI J,SHEN J,BALSAM W,et al.Asian monsoon oscillations in the northeastern QinghaiTibet Plateau since the late glacial as interpreted from visible reflectance of Qinghai Lake sediments［J］.Earth & Planetary Science Letters,2005,233(1):61-70.
［47］	LU H Y,YI S W,LIU Z Y,et al.Variation of East Asian monsoon precipitation during the past 21 k.y.and potential CO2 forcing［J］.Geology,2013,41(9):1023-1026.
［48］	BERGER A,LOUTRE M F.Insolation values for the climate of the last 10 million years［J］.Quaternary Science Reviews,1991,10:297-337.

[1]	WANG Zhen, LI Junli, ZHANG Jiudan, WU Haoru, GUO Xuefei. Influences of ecological water conveyance on Populus euphratica forest restoration in the middle reaches of Tarim River [J]. Arid Land Geography, 2023, 46(1): 94-102.
[2]	LIU Yuting,ZHANG Qifei,LIU Jingshi,GUAN Hanxiao,MENG Fanxue. Temporal and spatial characteristics of fractional vegetation coverage and its response to climatic factors in southern Xinjiang in recent 20 years: A case of Taxkorgan Tajik Autonomous County [J]. Arid Land Geography, 2022, 45(5): 1481-1489.
[3]	WANG Hua, YANG Qian-peng, TIAN Yun-jie, GUO Shan-chuan, TANG Peng-fei. Vegetation coverage monitoring in the Central Asian countries using multi-temporal Landsat images [J]. Arid Land Geography, 2020, 43(4): 1023-1032.
[4]	SUN Tian-yao, LI Xue-mei, XU Min, ZHANG Meng-sheng. Spatialtemporal variations of vegetation coverage in the Tarim River Basin from 2000 to 2018 [J]. Arid Land Geography, 2020, 43(2): 415-424.
[5]	YUE Jian, MU Gui-jin, TANG Zi-hua, YANG Xue-feng, LIN Yong-chong, XU Li-shuai. Remote sensing estimation models for vegetation coverage in desert regions of Xinjiang based on NDVI [J]. Arid Land Geography, 2020, 43(1): 153-160.
[6]	FENG Ke-peng, TIAN Jun-cang, SHEN Hui. Temperature variation characteristics of northwest China based on K-means clustering partition in the past half century [J]. Arid Land Geography, 2019, 42(6): 1239-1252.
[7]	NA Yin-tai, QIN Fu-ying, JIA Gen-suo, YANG Jie, BAO Yu-hai. Change trend and regional differentiation of precipitation over the Mongolian Plateau in recent 54 years [J]. Arid Land Geography, 2019, 42(6): 1253-1261.
[8]	MOU Huan, ZHAO Li, SUN Shuo-yang, TANG Hao, JIA Jian. Comparative analysis of two blizzard weather mechanisms in the northern piedmonts of Tianshan Mountains [J]. Arid Land Geography, 2019, 42(6): 1262-1272.
[9]	LI Zhen-jie, JIN Li-li, HE Qing, MIAO Qi-long, ALI Mamtimin. Characteristics of temperature distribution and profiles in Urumqi City and its suburb [J]. Arid Land Geography, 2019, 42(6): 1273-1281.
[10]	SUN Yan-qiao, TANG Da-zhang, SANG Jian-ren, WANG Yang, LYU Jing-jing, TIAN Lei. Quality control method and efficiency analysis on temperature data by RPG-HATPRO-G4 type ground-based microwave radiometer [J]. Arid Land Geography, 2019, 42(6): 1282-1290.
[11]	LIAN Lu-yao, LIU Bin-hui. Change characteristics of dry and wet spells in northwest China during the past 58 years [J]. Arid Land Geography, 2019, 42(6): 1301-1309.
[12]	WANG Bing, LI Qi-quan, LUO Lin, WANG Chang-quan, YANG Juan, YU Liang-zhi. Change characteristics of soil surface temperature and air temperature in the mountainous region of southern Sichuan from 1981 to 2011 [J]. Arid Land Geography, 2019, 42(6): 1322-1329.
[13]	PAN Mei-hui, XUE Wen-xuan, WU Yong-qiu, HUANG Wen-min, MA Jian-jun, YANG An-na, CHEN Yu-lin. Grain size characteristics of the climbing dunes in Dinggye area of Tibet [J]. Arid Land Geography, 2019, 42(6): 1337-1345.
[14]	MA Jian, LIU Xian-de, LI Guang, ZHAO Wei-jun, WANG Shun-li, JING Wen-mao, WANG Rong-xin, ZHAO Yong-hong. Evaluation on soil fertility quality of Picea crassifolia forest in middle Qilian Mountains [J]. Arid Land Geography, 2019, 42(6): 1368-1377.
[15]	BAO Qing-ling, DING Jian-li, WANG Jing-zhe, CAI Liang-hong. Hyperspectral detection of soil organic matter content based on random forest algorithm [J]. Arid Land Geography, 2019, 42(6): 1404-1414.

Lake central surface sediment-based pollen-vegetation cover transfer functions and its application in Inner Mongolia Plateau and adjacent area

PDF (PC)

Like

Knowledge

Abstract

Cite this article

share this article

References ［48］

Related Articles 15

Metrics

Comments

Recommended 0