Abstract
A comparison of structure and pattern of the soil seed bank was made between active and stabilized sand dunes in northeastern Inner Mongolia, China. The objective of this paper was to determine the significance of seed bank in vegetation restoration of sand dunes. The results showed that (1) average seed density decreased from stabilized sand dune to interdune lowland of stabilized sand dune, to interdune lowland of active sand dune, and to active sand dune; (2) horizontally, along the transect from interdune lowland to ecotone and to sand dune top, a ‘V’ shaped pattern was presented in the active dune system, and a reverse ‘V’ shaped pattern in the stabilized sand dune system; (3) vertically, the proportion (accounting for the total seeds) of seeds found in 0–20 mm soil profile decreased from stabilized sand dune to interdune lowland of stabilized sand dune, to interdune lowland of active sand dune, and to active sand dune. The same order was also found in 20–50 mm and 50–100 mm soil profiles; (4) the Sokal and Sneath similarity indices in the species-composition between soil seed bank and above-ground vegetation were ranked as: the stabilized sand dune (24%) > the interdune lowland of active sand dune (21%) > the interdune lowland of stabilized sand dune (18%) > the active sand dune (5%); and (5) vegetation restoration of active sand dunes depends on the dispersal of seeds from nearby plant communities on the interdune lowlands. Much effort must be made to preserve the lowlands, as lowlands are the most important seed reservoir in the active sand dune field.
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References
J P Bakker E S Bakker E Rosen G L Verweij R M Bekker (1996a) ArticleTitlePerspectives of restoration of dry Alvar communities forn the seed bank after Juniper encroachment J. Veg. Sci. 7 165–176
J P Bakker A P Grootjans M Hermy P Poschlod (2000) ArticleTitleHow to define targets for ecological restoration – Introduction Appl. Veg. Sci. 3 3–6 Occurrence Handle10.1111/j.1654-109X.2000.tb00033.x
J P Bakker P Poschlod R J Strykstra R M Bekker K Thompsom (1996b) ArticleTitleSeed banks and seed dispersal: important topics in restoration ecology Acta Bot. Neerl. 45 461–490
R M Bekker G L Verweij R E N Smith R Reine J P Bakker S Schneider (1997) ArticleTitleSoil seed banks in European grasslands: does land use affect regeneration perspectives? J. Appl. Ecol. 34 1293–1310
J C Chambers J A MacMahon (1994) ArticleTitleA day in the life of a seed: Movements and fates of seeds and their implications for natural and managed systems Annu. Rev. Ecol. Syst. 25 263–292 Occurrence Handle10.1146/annurev.es.25.110194.001403
J C Chambers J A MacMahon J H Haefner (1991) ArticleTitleSeed entrapment in alpine ecosystems: effects of soil particle size and diaspore morphology Ecology 72 1668–1677
E R Chang R L Jefferies T J Carleton (2001) ArticleTitleRelationship between vegetation and soil seed banks in an arctic coastal marsh J. Ecol. 89 367–384 Occurrence Handle10.1046/j.1365-2745.2001.00549.x
J P Grime (2001) Plant Strategies, Vegetation Processes, and Ecosystem Properties John Willey & Sons Chichester
P J Grubb (1977) ArticleTitleThe maintenance of species-richness in plant communities: the importance of the regeneration niche Biol. Rev. 52 107–145
Q Guo J H Brown T J Valone (2000) ArticleTitleConstrains of seed size on plant distributions and abundance Ecology 81 2149–2155
Q Guo P W Rundel D W Goodall (1998) ArticleTitleHorizontal and vertical distribution of desert seed banks: patterns, causes, and implications J. Arid Environ. 38 465–478 Occurrence Handle10.1006/jare.1997.0353
Y Gutterman S Ginott (1994) ArticleTitleLong-term protected “seed bank” in dry inflorescences of Asteriscus pygmaeus: achene dispersal mechanism and germination J. Arid Environ. 26 149–163 Occurrence Handle10.1006/jare.1994.1019
M Kassas (1995) ArticleTitleDesertification: a general review J. Arid Environ. 30 115–128 Occurrence Handle10.1016/S0140-1963(05)80063-1
M A Leck V T Parker R L Simpson (1989) Ecology of Soil Seed Banks Academic Press San Diego
J Lichter (2000) ArticleTitleColonization constraints during primary succession on coastal Lake Michigan sand dunes J. Ecol. 88 825–839 Occurrence Handle10.1046/j.1365-2745.2000.00503.x
M J Liddle J L Parlange A Bulow-Olsen (1987) ArticleTitleA simple method for measuring diffusion rates and predation of seed on the soil surface J. Ecol. 75 1–8
X Liu H Zhao A Zhao (1996) Wind-sandy Environment and Vegetation in the Horqin Sandy Land, Chinda Science Press Beijing
Z Liu Q Yan Y Luo H Wang R Li X Li D Jiang (2004) ArticleTitleComparison of mucilage secreting of achenes under different rainfall in 5 Artemisia species Acta Eco. Sin. 25 1497–1501
R A Meissner J M Facelli (1999) ArticleTitleEffects of sheep exclusion on the soil seed bank and annual vegetation in chenopod shrublands of South Australia J. Arid Environ. 42 117–128 Occurrence Handle10.1006/jare.1999.0515
A T Moles D W Hodson C J Webb (2000) ArticleTitleSeed size and shape and persistence in the soil in the New Zealand flora Oikos 89 541–545 Occurrence Handle10.1034/j.1600-0706.2000.890313.x
T G O’Connor G A Pickett (1992) ArticleTitleThe influence of grazing on seed production and seed bank of some African savanna grassland J. Appl. Ecol. 29 247–260
A Okubo S A Levin (1989) ArticleTitleA theoretical framework for data analysis of wind dispersal of seeds and pollen Ecology 70 329–338
C E Paker D L Venable (1996) ArticleTitleSeed bank in desert annuals: implications for persistence and coexistence in variable environments Ecology 77 1427–1435
J Reichman (1984) ArticleTitleSpatial and temporal variation of seed distributions in Sonoran desert soils J. Biogeogr. 11 1–11
R R Sokal P H A Sneath (1963) Principles of Numerical Taxonomy W.H. Freeman and Company San Francisco
Thompson K 1992 The functional ecology of seed banks. In Ed. M Fenner. pp. 231–258, CAB international, Wallinford.
K Thompson S R Band J G Hodgson (1993) ArticleTitleSeed size and shape predict persistence in soil Funct. Ecol. 7 236–241
K Thompson J P Grime (1979) ArticleTitleSeasonal variation in the seed banks of herbaceous species in ten contrasting habitats J. Ecol. 67 893–921
K van Rheede van oudtshoorn M W Rooyen Particlevan (1999) Dispersal Biology of Desert Plants Springer-Verlag Berlin
G Wang X Liang (1995) ArticleTitleThe dynamics of seed bank on Shapotou artificially stabilized dunes Acta Bot. Sin. 37 231–237
E A Weiher Werf Particlevan der K Thompson (1999) ArticleTitleChallenging Theophrastus: a common core list of plant traits for functional ecology J.Veg. Sci. 10 609–620
S A Whipple (1978) ArticleTitleThe relationship of buried, germinating seeds to vegetation in an old-growth Colorado subalpine forest Can. J. Bot. 56 1505–1509 Occurrence Handle10.1139/b78-176
E T F Witkowski R D Garner (2000) ArticleTitleSpatial distribution of soil seed banks of three African savanna woody species at two contrasting sites Plant Ecol. 149 91–106 Occurrence Handle10.1023/A:1009850706843
Q Yan Z Liu Y Luo H Wang (2004) ArticleTitleA comparative study on diaspore weight and shape of 78 species in the Horqin Steppe Acta Ecol. Sin. 24 2422–2429
S Yu M Sternberg G Jiang P Kutiel (2003) ArticleTitleHeterogeneity in soil seed banks in a Mediterranean coastal sand dune Acta Bot. Sin. 45 536–543
Z Zhu (1963) Study on the Dynamic Processes of Sand Dune Evolution under Wind Action Science Press Beijing
Z Zhu G Chen (1994) Sandy Desertification in China Science Press Beijing
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Qiaoling, Y., Zhimin, L., Jiaojun, Z. et al. Structure, Pattern and Mechanisms of Formation of Seed Banks in Sand Dune Systems in Northeastern Inner Mongolia, China. Plant Soil 277, 175–184 (2005). https://doi.org/10.1007/s11104-005-6836-6
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DOI: https://doi.org/10.1007/s11104-005-6836-6