Tree species impact the terrestrial cycle of silicon through various uptakes

Cornelis, Jean-Thomas; Delvaux, Bruno; Ranger, J.; Iserentant, Anne

doi:10.1007/s10533-009-9369-x

Request a copy

Article (Scientific journals)

Tree species impact the terrestrial cycle of silicon through various uptakes

Cornelis, Jean-Thomas; Delvaux, Bruno; Ranger, J. et al.

2010 • In Biogeochemistry

Peer Reviewed verified by ORBi

Permalink
https://hdl.handle.net/2268/177244

DOI
10.1007/s10533-009-9369-x

Files (1)Send to Details Statistics Bibliography Similar publications

Files

Full Text

Cornelis et al. 2010_Biogeo.pdf

Publisher postprint (393.21 kB)

Request a copy

All documents in ORBi are protected by a user license.

Send to

RIS BibTex APA Chicago Permalink X Linkedin

Details

Keywords :

Phytolith; Silicon cycle; temperate forest; Tree species

Abstract :

[en] Abstract : The quantification of silicon (Si) uptake by tree species is a mandatory step to study the role of forest vegetations in the global cycle of Si. Forest tree species can impact the hydrological output of dissolved Si (DSi) through root induced weathering of silicates but also through Si uptake and restitution via litterfall. Here, monospecific stands of Douglas fir, Norway spruce, Black pine, European beech and oak established in identical soil and climate conditions were used to quantify Si uptake, immobilization and restitution. We measured the Si contents in various compartments of the soil-tree system and we further studied the impact of the recycling of Si by forest trees on the DSi pool. Si is mainly accumulated in leaves and needles in comparison with other tree compartments (branches, stembark and stemwood). The immobilization of Si in tree biomass represents less than 15% of the total Si uptake. Annual Si uptake by oak and European beech stands is 18.5 and 23.3 kg ha(-1) year(-1), respectively. Black pine has a very low annual Si uptake (2.3 kg ha(-1) year(-1)) in comparison with Douglas fir (30.6 kg ha(-1) year(-1)) and Norway spruce (43.5 kg ha(-1) year(-1)). The recycling of Si by forest trees plays a major role in the continental Si cycle since tree species greatly influence the uptake and restitution of Si. Moreover, we remark that the annual tree uptake is negatively correlated with the annual DSi output at 60 cm depth. The land-ocean fluxes of DSi are certainly influenced by geochemical processes such as weathering of primary minerals and formation of secondary minerals but also by biological processes such as root uptake.

Disciplines :

Earth sciences & physical geography

Author, co-author :

Cornelis, Jean-Thomas ; Université de Liège - ULiège > BIOSE > Échanges Eau-Sol-Plante

Delvaux, Bruno

Ranger, J.

Iserentant, Anne

Language :

English

Title :

Tree species impact the terrestrial cycle of silicon through various uptakes

Publication date :

2010

Journal title :

Biogeochemistry

ISSN :

0168-2563

eISSN :

1573-515X

Publisher :

Springer Science & Business Media B.V., Dordrecht, Netherlands

Peer reviewed :

Peer Reviewed verified by ORBi

Additional URL :

http://hdl.handle.net/2078.1/34207

Available on ORBi :

since 23 January 2015

Statistics

Number of views

35 (6 by ULiège)

Number of downloads

1 (1 by ULiège)

More statistics

Scopus citations^®

116

Scopus citations^®
without self-citations

101

OpenCitations

110

Bibliography

Alexandre A, Meunier JD, Colin F, Koud JM (1997) Plant impact on the biogeochemical cycle of silicon and related weathering processes. Geochim Cosmochim Acta 61: 677-682.
Barré P, Berger G, Velde B (2009) How element translocation by plants may stabilize illitic clays in the surface of temperate soils. Geoderma 151: 22-30.
Bartoli F (1983) The biogeochemical cycle of silicon in two temperate forest ecosystems. Environ Biogeochem Ecol Bull 35: 469-476.
Bartoli F (1985) Cristallochemistry and surface-properties of biogenic opal. Soil Sci Soc Am J 36(3): 335-350.
Bartoli F, Souchier B (1978) Cycle et rôle du silicium d'origine végétale dans les écosystèmes forestiers tempérés. Ann Sci For 35: 187-202.
Bartoli F, Wilding LP (1980) Dissolution of biogenic opal as a function of its physical and chemical properties. Soil Sci Soc Am J 44: 873-878.
Bartoli F, Burtin G, Herbillon AJ (1991) Disaggregation and clay dispersion of oxisols: Na resin, a recommended methodology. Geoderma 49: 301-317.
Berner RA (1997) The rise of plants and their effect on weathering and atmospheric CO2. Science 276: 544.
Blecker SW, McCulley RL, Chadwick OA, Kelly EF (2006) Biologic cycling of silica across a grassland bioclimosequence. Global Biogeochem Cycles 20: GB3023.
Bonneau M, Brêthes A, Lacaze JF, Lelong F, Levy G, Nys C, Souchier B (1977) Modification de la fertilité des sols sous boisement artificiel de résineux purs. C. R. Fin d'Etude D. G. R. S. T., Nancy-Champenoux, p 88.
Breda N, Soudani K, Bergonzini JC (2002) Mesure de l'indice foliaire en forêt. Doc GIP ECOFOR Paris Laballery, Clamecy imp, p 157.
Brethes A, Brun JJ, Jabiol B, Ponge J, Toutain F (1995) Classification of forest humus forms: a French proposal. Ann Sci For 52: 535-546.
Carnelli AL, Madella M, Theurillat JP (2001) Biogenic silica production in selected alpine plant species and plant communities. Ann Bot 87: 425-434.
Chao TT, Sanzolone RF (1992) Decomposition techniques. J Geochem Explor 44: 65-106.
Conley DJ (2002) Terrestrial ecosystems and the global biogeochemical silica cycle. Global Biogeochem Cycles 16(4): 1121.
Conley DJ, Likens GE, Buso DC, Saccone L, Bailey SW, Johnson CE (2008) Deforestation causes increased dissolved silicate losses in the Hubbard Brook Epxerimental Forest. Global Change Biol 14: 1-7.
Derry LA, Kurtz AC, Ziegler K, Chadwick OA (2005) Biological control of terrestrial silica cycling and export fluxes to watersheds. Nature 433: 728-731.
Drees LR, Wilding LP, Smeck NE, Senkayi AL (1989) Silica in soils: quartz and disorders polymorphs. In: Dixon JB, Weed SB (eds) Minerals in soil environments. Soil Science Society of America, Madison, pp 914-974.
Drénou C (2006) Les racines, face cache des arbres. IDF, Paris.
Drever JI (1994) The effect of land plants on weathering rates of silicates minerals. Geochim Cosmochim Acta 58: 2325-2332.
Epstein E (1999) Silicon. Annu Rev Plant Phys 50: 641-664.
Exley C (1998) Silicon in life: a bioinorganic solution to bioorganic essentiality. J Inorg Biochem 69: 139-144.
Farmer VC, Delbos E, Miller JD (2005) The role of phytolith formation and dissolution in controlling concentrations of silica in soil solutions and streams. Geoderma 127: 71-79.
Fitzapatrick RW, Chittleborough DJ (2002) Titanium and Zirconium minerals. In: Dixon JB, Schulze DG (eds) Soil mineralogy with environmental applications. Soil Science Society of America, Madison, pp 667-690.
Fraysse F, Pokrovsky OS, Schott J, Meunier J-D (2006) Surface properties, solubility and dissolution kinetics of bamboo phytoliths. Geochim Cosmochim Acta 70: 1939-1951.
Fraysse F, Pokrovsky OS, Schott J, Meunier J-D (2009) Surface chemistry and reactivity of plant phytoliths in aqueous solutions. Chem Geol 258: 197-206.
Fulweiler RW, Nixon SW (2005) Terrestrial vegetation and the seasonal cycle of dissolved silica in a Southern New England coastal river. Biogeochemistry 74(1): 115-130.
Gaillardet J, Dupre B, Allegre CJ (1999) Geochemistry of large river suspended sediments: silicate weathering or recycling tracer? Geochim Cosmochim Acta 63(23-24): 4037-4051.
Garvin CJ (2006) An exploratory study of the terrestrial biogeochemical silicon cycle at a forested watershed in northern Vermon. Dissertation, Cornell University.
Geis JW (1973) Biogenic silica in selected species of deciduous angiosperms. Soil Sci 116(2): 113-119.
Gérard F, François M, Ranger J (2002) Processes controlling silica concentration in leaching and capillary soil solutions of an acidic brown forest soil (Rhône, France). Geoderma 107: 197-226.
Gérard F, Mayer KU, Hodson MJ, Ranger J (2008) Modelling the biogeochemical cycle of silicon in soils: application to a temperate forest ecosystem. Geochim Cosmochim Acta 72(3): 741-758.
Giesler R, Ilvesniemi H, Nyberg L, van Hees P, Starr M, Bishop K, Kareinen T, Lundström US (2000) Distribution and mobilization of Al, Fe and Si in three podzolic soil profiles in relation to the humus layer. Geoderma 94: 149-263.
Granier A, Bréda N, Biron P, Villette S (1999) A lumped water balance model to evaluate duration and intensity of drought constraints in forest stands. Ecol Model 116: 269-283.
Henriet C, Draye X, Dorel M, Bodarwe L, Delvaux B (2008a) Leaf silicon content in banana (Musa spp.) reveals the weathering stage of volcanic ash soils in Guadeloupe. Plant Soil 313: 71-82.
Henriet C, De Jaeger N, Dorel M, Opfergelt S, Delvaux B (2008b) The reserve of weatherable primary silicates impacts the accumulation of biogenic silicon in volcanic ash soils. Biogeochemistry 90: 209-223.
Herbauts J, Dehalu FA, Gruber W (1994) Quantitative-determination of plant opal content in soils, using a combined method of heavy liquid separation and alkali dissolution. Eur J Soil Sci 45: 379-385.
Hodson MJ, Sangster AG (1999) Aluminium/silicon interactions in conifers. J Inorg Biochem 76: 89-98.
Hodson MJ, White PJ, Mead A, Broadley MR (2005) Phylogenetic variation in the silicon composition of plants. Ann Bot 96: 1027-1046.
IUSS Working Group WRB (2006) World reference base for soil resources 2006, 2nd edn. World soil resources reports no. 103. FAO, Rome.
Jackson RB, Canadell J, Ehleringer JR, Mooney HA, Sala OE, Schulze E-D (1996) A global analysis of root distributions for terrestrial biomes. Oecologia 108: 389-411.
Jaffrain J, Gérard F, Meyer M, Ranger J (2007) Assessing the quality of dissolved organic matter in forest soils using ultraviolet absorption spectrophotometry. Soil Sci Soc Am J 71: 1851-1855.
Johnson-Maynard JL, Graham RC, Shouse PJ, Quideau SA (2005) Base cation and silicon biogeochemistry under pine and scrub oak monocultures: implications for weathering rates. Geoderma 126: 353-365.
Jones LHP, Handreck KA (1965) Studies of silica in the oat plant. III. Uptake of silica from soils by plant. Plant Soil 23(1): 79-96.
Kelly EF (1990) Methods for extracting opal phytoliths from soil and plant material. In: Workshop on biotic indicators of global change, Seatlle, Washington.
Kelly EF, Chadwick OA, Hilinski TE (1998) The effect of plants on mineral weathering. Biogeochemistry 42: 21-53.
Kleber M, Scwendenmann L, Veldkamp E, Röbner J, Jahn R (2007) Halloysite versus gibbsite: silicon cycling as a pedogenetic process in two lowland neotropical rain forest soils of La Selva, Costa Rica. Geoderma 138: 1-11.
Klein RL, Geis JW (1978) Biogenic silica in the pinaceae. Soil Sci 126(3): 145-156.
Levrel G, Ranger J (2006) Effet des substitutions d'essences forestières sur les propriétés physiques d'un Alocrisol (site expérimental de la forêt de Breuil-Chenue/Morvan). Etude et gestion des sols 13: 71-88.
Liang Y, Sun W, Zhu YG, Christie P (2007) Mechanisms of silicon-mediated alleviation of abiotic stresses in higher plants: a review. Environ Pollut 147: 422-428.
Likens GE, Pierce RS, Eaton JS, Johnson NM (1977) Biogeochemistry of a forested ecosystem. Springer, Verlag.
Lucas Y (2001) The role of plants in controlling rates and products of weathering: importance of biological pumping. Annu Rev Earth Planet Sci 29: 135-163.
Lucas Y, Luizao FJ, Chauvel A, Rouiller J, Nahon D (1993) The relation between biological activity of the rain forest and mineral composition of soils. Science 260: 521-523.
Ma JF, Takahashi E (2002) Soil, fertilizer, and plant silicon research in Japan. Elsevier, Amsterdam.
Ma JF, Yamaji N (2006) Silicon uptake and accumulation in higher plants. Trends Plant Sci 11(8): 392-397.
Madella M, Alexandre A, Ball T (2005) International code for phytolith nomenclature 1. 0. Ann Bot 96: 253-260.
Markewitz D, Richter D (1998) The bio in aluminium and silicon geochemistry. Biogeochemistry 42: 235-252.
Marschner H (1995) Mineral nutrition of higher plants, 2nd edn. Academic Press, London.
Mehra OP, Jackson ML (1960) Iron oxides removal from soils and clays by dithionite-citrate system buffered with sodium bicarbonate. In: Proceeding of 7th national conference clays clay minerals, Washington, pp 317-327.
Meunier JD, Colin F, Alarcon C (1999) Biogenic silica storage in soils. Geology 27: 835-838.
Moulton KL, West J, Berner RA (2000) Solute flux and mineral mass balance approaches to the quantification of plant effects on silicate weathering. Am J Sci 300: 539-570.
Opfergelt S, Delvaux B, André L, Cardinal D (2008) Plant silicon isotopic signature might reflect soil weathering degree. Biogeochemistry 91: 163-175.
Peel MC, Finlayson BL, McMahon TA (2007) Updated world map of the Köppen-Geiger climate classification. Hydrol Earth Syst Sci 11: 1633-1644.
Puhe J (2003) Growth and development of the root system of Norway spruce (Picea abies) in forest stands: a review. Forest Ecol Manag 175: 253-273.
Rai D, Kittrick JA (1989) Mineral equilibria and the soil system. In: Dixon J, Weed S (eds) Minerals in soil environments. Soil Science Society of America, Madison, pp 161-198.
Ranger J, Bonneau M (1984) Effets prévisibles de l'intensification de la production et des récoltes sur la fertilité des sols de forêt. Le cycle biologique en forêt. Rev For Fr XXXVI: 93-122.
Ranger J, Marques R, Colin-Belgrand M, Flammang N, Gelhaye D (1995) The dynamics of biomass and nutrient accumulation in a Douglas-fir (Pseudotsuga menziesii Franco) stand studied using a chronosequence approach. For Ecol Manag 72: 167-183.
Ranger J, Marques R, Colin-Belgrand M (1997) Nutrients dynamics during the development of a Douglas fir (Pseudotsuga menziesii Mirb.) stand. Acta Oecol 18: 73-91.
Ranger J (ed), Andreux F (ed), Bienaime S, Berthelin J, Bonnaud P, Boudot JP, Brechet C, Buee M, Calmet JP, Chaussod R, Gelhaye D, Gelhaye L, Gerard F, Jaffrain J, Lejon D, Le Tacon F, Leveque J, MauriceJP, Merlet D, Moukoumi J, Munier-Lamy C, Nourrisson G, Pollier B, Ranjard L, SimonssonM, Turpault MP, Vairelles D, Zeller B (2004) Effet des substitutions d'essence sur le fonctionnement organo-minéral de l'écosystème forestier, sur les communautés microbiennes et sur la diversité des communautés fongiques mycorhiziennes et saprophytes (cas du dispositif experimental de Breuil - Morvan). Rapport final du contrat INRA-GIP Ecofor 2001-24, n°INRA 1502A Nancy: INRA-Champenoux, Biogéochimie des écosystèmes forestiers, p 202.
Raven JA (1983) The transport and function of silicon in plants. Biol Rev 58: 179-207.
Richmond KE, Sussman M (2003) Got silicon? The non-essential beneficial plant nutrient. Curr Opin Plant Biol 6(3): 268-272.
Rouiller J, Burtin G, Souchier B (1972) La dispersion des sols dans l'analyse granulométrique. Méthode utilisant les résines échangeuses d'ions. ENSAIA Nancy 14: 194-205.
Rustad LE, Cronan CS (1995) Biogeochemical controls of aluminium chemistry in the O horizon of a red spruce (Picea rubens Sarg.) stand in central Maine, USA. Biogeochemistry 29: 107-129.
Saccone L, Conley DJ, Koning E, Sauer D, Sommer M, Kaczorek D (2007) Assessing the extraction and quantification of amorphous silica in soils of forest and grassland ecosystems. Eur J Soil Sci 58: 1446-1459.
Saint-André L, Thongo M'Bou A, Mabiala A, Mouvondy W, Jourdan C, Roupsard O, Deleporte Ph, Hamel O, Nouvellon Y (2005) Age-related equations for above- and below-ground biomass of a Eucalyptus hybrid in Congo. For Ecol Manag 205: 199-214.
Sicard C, Saint-Andre L, Gelhaye D, Ranger J (2005) Effect of initial fertilization on biomass and nutrient content of Norway spruce and Douglas fir plantations at the same site. Trees Struct Funct 20: 229-246.
Smetacek V (1999) Diatoms and the ocean carbon cycle. Protist 150: 25-32.
Smithson F (1956) Plant opal in soil. Nature 178: 107.
Sommer M, Kaczorek D, Kuzyakov Y, Breuer J (2006) Silicon pools and fluxes in soils and landscapes-a review. J Plant Nutr Soil Sci 169: 310-329.
Street-Perrott FA, Barker P (2008) Biogenic silica: a neglected component of the coupled global continental biogeochemical cycles of carbon and silicon. Earth Surf Proc Land 33: 1436-1457.
Tréguer P, Nelson DM, van Bennekom AJ, De Master DJ, Leynaert A, Quéguiner B (1995) The silica balance in the world ocean: a reestimate. Science 268: 375-379.
Volk T (1987) Feedbacks between weathering and atmospheric CO2 over the last 100 million years. Am J Sci 287: 763-779.
Watteau F, Villemin G (2001) Ultrastructural study of the biogeochemical cycle of silicon in the soil and litter of a temperate forest. Eur J Soil Sci 52: 385-396.
Wedepohl KH (1995) The composition of the continental crust. Geochim Cosmochim Acta 59: 1217-1232.
Wilding LP, Drees LR (1974) Contributions of forest opal and associated crystalline phases to fine silt and clay fractions of soils. Clay Clay Miner 22: 295-306.
Ziegler K, Chadwick OA, Brzezinski MA, Kelly EF (2005) Natural variations of δ30Si ratios during progressive basalt weathering, Hawaiian Island. Geochim Cosmochim Acta 69: 4597-4610.