W. Amelung, M. V. Cheshire, and G. Guggenberger, Determination of neutral and acidic sediments: gas chromatographic mass spectrometric analysis of trimethylsilyl derivatives, p.303

G. L. Cowie and J. I. Hedges, Carbohydrate sources in a coastal marine environment, Geochim, p.305

S. Cosmochim, D. C. Hu, M. H. Coleman, P. F. Beare, and . Hendrix, Soil carbohydrates in aggrading and 307 degrading agroecosystems: influences of fungi and aggregates, Hänninen, Concentrations of monosaccharides in humic substances in the 310 early stages of humification, pp.2075-2087, 1984.

P. Rovira, V. R. Vallejo-]-s, J. Ogier, P. Disnar, G. Albéric et al., Labile, recalcitrant, and inert organic matter in Mediterranean forest soils, Soil Biology and Biochemistry, vol.39, issue.1, pp.202-215, 2007.
DOI : 10.1016/j.soilbio.2006.07.021

. Largeau, Organic matter sources and early diagenetic degradation in a tropical peaty marsh 318 (Tritivakely, Madagascar), Org. Geochem, pp.31-421, 2000.

C. Rumpel and M. Dignac, Gas chromatographic analysis of monosaccharides in a forest soil profile: Analysis by gas chromatography after trifluoroacetic acid hydrolysis and reduction???acetylation, 322 [10] S. Spielvogel, J. Prietzel, I. Kögel-Knabner, Changes of lignin phenol and neutral sugar 323 pools in different soil types of a high-elevation forest ecosystem 25 years after forest dieback 324, pp.1478-1481, 2006.
DOI : 10.1016/j.soilbio.2005.09.017

. Appl, 327 [12] L. Grasset, A. Amblès, Structural study of soil humic acids and humin using a new 328, Pyrol, vol.89, pp.2-16, 2010.

J. Thermochemolysis-technique, 1-12. 329 [13] D. Fabbri, R. Helleur, Characterisation of the tetramethylammonium hydroxide technique for the characterization of lignin in vascular plants: thermochemolysis with 336 tetramethylammonium hydroxide (TMAH), Appl. Pyrol. Org. Geochem, vol.4716, issue.337, pp.169-175, 1995.

. Aplincourt, Comparative study of ligno-cellulosic material from wheat straw and of pure and 339 mixed standard compounds via solid state 13 C NMR spectroscopy, conventional pyrolysis and 340 TMAH thermochemolysis, Characterization of organic matter in 342 soils by thermochemolysis using tetramethylammonium hydroxide (TMAH), pp.277-293, 2003.

. J. Am, C. Tanczos, H. Schwarzinger, J. Schmidt, T. Balla et al., On the mechanism of thermally assisted hydrolysis and methylation of 345 carbohydrates: the contribution of aldol and retroaldol reactionsMS analysis of model 348 uronic acids of pectin and hemicellulose Characterization of 350 neutral sugars and uronic acids after methanolysis and trimethyl-silylation for recognition of 351 plant gums Carbohydrate signatures of aquatic 353 macrophytes and their dissolved degradation products as determined by a sensitive high- 354 performance ion chromatography method, [22] L. Comont, F. Laggoun-Défarge, J.-R. Disnar, Evolution of organic matter indicators in 356 response to major environmental changes: the case of a formerly cutover peatbog, pp.583-589, 1991.

M. E. Moers, J. J. Boon, J. W. De-leeuw, M. Baas, and P. A. Schenck, Carbohydrate 359 speciation and Py-MS mapping of peat samples from a subtropical open marsh environment, Org. Geochem, vol.37, issue.358, pp.1736-1751, 2006.

. Geochim, . E. Cosmochim-]-m, M. Moers, J. W. Baas, J. J. De-leeuw et al., Occurrence and origin 10 Quantitative gas chromatography of mixtures of 371 simple sugars CPMAS 13 C NMR and IR 373 spectra of spruce and pine litter and of the Klason lignin fraction at different stages of 374 decomposition, Preston, J.R. Nault, J.A. Trofymow, Chemical Changes During 6 Years of 376, pp.60-63, 1111.

L. A. Wysocki, T. R. Filley, T. S. Bianchi-]-r, C. L. Clymo, . A. Bryant et al., Comparison of two methods for the analysis of 385 lignin in marine sediments: CuO oxidation versus tetramethylammonium hydroxide (TMAH) 386 thermochemolysis Diffusion and mass flow of dissolved carbon dioxide, methane, 388 and dissolved organic carbon in a 7-m deep raised peat bog, CuO oxidation method and the method of thermochemolysis with tetramethylammonium 383 hydroxide Decomposition activity of peat 391 soils in geogenous mires in Sasakami, central Japan Ecology of ligninolytic fungi associated with leaf litter decomposition, pp.881-888, 1995.

R. C. Res, A. D. Cooke, and . Whipps, Ecophysiology of fungi, monde des tourbières et des marais : France, [38] F. Delarue, F. Laggoun-Défarge, J.R. Disnar, N. Lottier, S. Gogo, Organic matter sources, pp.955-974, 1993.