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effect of changing substrate quality, nutrient and moisture conditions on microbial activity and its C use efficiency. References Adams J.M., Faire H., Faire-Richard L., McGlade J.M., Woodward F.I.,1990. Increases in terrestrial carbon storage 30 from the last glacial maximum to the present. Nature 348, 711–714. Binkley D., Stape J.L., Takahashi E.N., Ryan M.G., 2006. Tree-girdling to separate root and heterotrophic respiration in two Eucalyptus stands in Brazil. Oecologia, 148, 447-454. Bhupinderpal-Singh, Nordgren A., Ottosson Lofvenius M., Hogberg M.N., Mellander P.-E., Hogberg P., 2003. Tree root and soil heterotrophic respiration as revealed by girdling of boreal Scots pine forest: extending observations beyond the first year. Plant Cell Envir 26, 1287-1296. Brady N.C., Wail R.R., 1999. The nature and properties of soils, 12th edn. Prentice-Hall, New Jersey. Bol R., Amelung W., Friedrich C., 2004. Role of aggregate surfaces and core fraction in the sequestration of carbon from dung in a temperate grassland soil. Europ J. Soil Sci 55, 71–77. Carlier L., De Vliegher A., van Cleemput O., Boeckx P. 2004. Importance and functions of European grasslands. Proceedings of the joint workshop of working group 1, 2, 3 and 4 of the COST Action 627 “ Carbon storage in European grasslands” , Ghent, 3-6 June 2004. 7-16. Conant R.T., Paustian K., Elliott E.T., 2001. Grassland management and conversion into grassland: effects on soil carbon. Ecol Appl 11, 343–355. Davidson E.A., Janssens I.A., 2006. Temperature sensitivity of soil carbon decomposition and feedbacks to climate change. Nature 440, 165-173. Dolman A.J., Moors E.J., Grunwald T., Berbigier P., 2002. Factors controlling forest atmosphere exchange of water, energy and carbon in European forests. In: Valentini R. (Ed.), Fluxes of carbon, water and energy of European forests. Springer, Berlin. Dugas W.A., Heuer M.L., Mayeux H.S., 1999. Carbon dioxide fluxes over Bermuda grass, native prairie, and sorghum. Agric Forest Meteor 93, 121–139. Flanagan L.B., Wever L.A., Carlson P.J., 2002. Seasonal and interannual variation in carbon dioxide exchange and carbon balance in a northern temperate grassland. Glob Change Biol 8, 599–615. Frank A.B., Dugas W.A., 2001. Carbon dioxide fluxes over a northern, semiarid, mixed-grass prairie. Agric Forest Meteor 108, 317–326. Goh K.M., Rafter T.A., Stout J.D., Walker T.W., 1976. The accumulation of soil organic matter and its carbon isotope content in a chronosequence of soils developed on aeolian sand in New Zealand. J Soil Sci 27, 89–100 Goulden M.L., Munger J.W., Fan S.M., Daube B.C., Wofsy S.C., 1996. Exchange of carbon dioxide by a deciduous forest: response of interannual climate variability. Science 271, 1576–1578. Hanson P.J., Edwards N.T., Garten C.T., Andrews J.A., 2000. Separating root and soil microbial contributions to soil respiration: A review of methods and observations. Biogeochem 48, 115- 146. Högberg P., Nordgren A., Buchmann N., Taylor A.F.S., Ekblad A., Hogberg M.N., Nyberg G., Ottosson-Lofvenius M. Read D.J., 2001. Large-scale forest girdling shows that current photosynthesis drives soil respiration. Nature 411, 789-792. Holt J.A., Coventry RJ., 1990. Nutrient cycling in Australian savannas. J. Biogeogr 17, 427-432.
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Page 4 and 5: explain diurnal and seasonal change
Page 6 and 7: sull’intensità del flusso respir
Page 8 and 9: 8 3.2.4. Data analyses and definiti
Page 11 and 12: 1. INTRODUCTION AND OVERVIEW 11
Page 13 and 14: times as much carbon as the terrest
Page 15 and 16: Fig. 3 Different soil C pools with
Page 17 and 18: 1.3. Soil respiration sources Soil
Page 19 and 20: conditions, like soil type, plants
Page 21 and 22: For grasslands, the nature, frequen
Page 23 and 24: (a) (b) (c) Fig.7 Amplero (AQ, Ital
Page 25 and 26: magnitude of root respiration and o
Page 27 and 28: efficiency, indicating future posit
Page 29: approaches for studying of the cont
Page 33: Vleeshouwers L.M., Verhagen A. 2002
Page 36 and 37: 2.1. Introduction 36 Soil respirati
Page 38 and 39: 38 In the year 2005 ten PVC collars
Page 40 and 41: 2.2.4. Biochemical analyses Microbi
Page 42 and 43: 42 Variation of soil respiration fr
Page 44 and 45: CO 2 efflux (mmol m -2 s -1 ) 44 CO
Page 46 and 47: 46 All diurnal measurements of root
Page 48 and 49: 48 Q10 R 2 p Rs 2.51 0.77 0.000 Ra
Page 50 and 51: the photosynthesis and its followin
Page 52 and 53: 2.3.3. Inter-annual variation of so
Page 54 and 55: 54 RS RHET 8 6 6 4 25 4 2 2 25 20 T
Page 56 and 57: 2.4. Discussion 2.4.1. Partitioning
Page 58 and 59: measurements, the possibility to fi
Page 60 and 61: and Schlesinger, 1992; Moyano et al
Page 62 and 63: Janssens I.A., Pilegaard K., 2003.
Page 64: Xu X., Kuzyakov Y., Wanek W., Richt
Page 67 and 68: 3.1. Introduction Soil respiration
Page 69 and 70: Our experiment was conducted in a m
Page 71 and 72: Lactic acid 13 C 13 CO2 Root-derive
Page 73 and 74: At the end of the process, the subl
Page 75 and 76: where, MAs - the mean age of the co
Page 77 and 78: 13C of respiration ( o / oo ) 155 1
Page 79 and 80: Total Label Recovered (TLR, %) Ra R
Page 81 and 82:
GPP (mmol m -2 s -1 ) 25 20 15 10 5
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frequent and possibly they missed t
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3.4.3. Destructive vs. Non-destruct
Page 87 and 88:
Gavrichkova O., Kuzyakov Y., 2008.
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Chapter source: 90 4. THE EFFCT OF
Page 92 and 93:
Bardgett et al. (1997) showed that
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94 Partitioning plots were installe
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Microbial C was calculated as a dif
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taken from 1 µg N-NO2 ml -1 soluti
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ates between clipped and unclipped
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Fig. 7 Total (Rs), root (Ra)- and m
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104 Rh, (CO 2 , mmolm -2 s -1 ) 7 6
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Fig. 11 Cumulative microbial respir
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108 After the calculation of synthe
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Fig. 16: a) Relationship between sy
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an annual mowing the measurement wa
Page 114 and 115:
mineral N available to plants and N
Page 116 and 117:
Cambardella C.A., Elliott E.T., (19
Page 118 and 119:
Rice C.W., Moorman T.B., Beare M, 1
Page 120 and 121:
120
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5.1. Introduction 122 Nitrogen (N)
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specie, c) an additional aim was to
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5.2.4. Sampling and analyses 126 Na
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the differences between N and contr
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130 specific root respiration (max
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Fig. 4 a) Intensity of 14 CO2 efflu
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Fig. 6 a) values above zero: root-d
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136 Zea mays: A clear diurnal dynam
Page 138 and 139:
plants. The growth stage could cont
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nitrates. At temperatures of 15 - 2
Page 142 and 143:
experiment could be responsible for
Page 144 and 145:
Horwath W.R., Pretziger K.S., Paul,
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146
Page 148 and 149:
148 6.1 . Introduction In studies o
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Regression analyses technique, whic
Page 152 and 153:
152 The respiratory response with g
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154 100% 80% 60% 40% 20% 0% 85% 13%
Page 156 and 157:
6.3.2. 2008: Mesh- exclusion vs. re
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6.4. Discussion 6.4.1. Mesh-exclusi
Page 160 and 161:
introduction in a small soil sample
Page 162 and 163:
component, expressing a total soil
Page 164 and 165:
Kucera C.L., Kirkham D.R., 1971. So
Page 166:
Acknowledgements This work was poss
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