Differential controls by climate and substrate over the heterotrophic and rhizospheric components of soil respiration

The partitioning of soil respiration rates into the component processes of rhizospheric respiration (because of live roots and those microorganisms that subsist on root exudations) and heterotrophic respiration (because of decomposer microorganisms that subsist on the oxidation of soil organic matte...

Celý popis

Uloženo v:

Podrobná bibliografie
Vydáno v:	Global change biology Ročník 12; číslo 2; s. 205 - 216
Hlavní autoři:	Scott-Denton, Laura E, Rosenstiel, Todd N, Monson, Russell K
Médium:	Journal Article
Jazyk:	angličtina
Vydáno:	Oxford, UK Oxford, UK : Blackwell Science Ltd 01.02.2006 Blackwell Science Ltd Blackwell Publishing Ltd
Témata:	Ameriflux biological activity in soil Biomass Carbon carbon cycle carbon dioxide Climate Colorado coniferous forests Dissolved organic carbon Drought Extreme drought forest girdling forest soils gas emissions girdling Growing season lodgepole pine Low temperature microbial biomass Microorganisms Organic matter photosynthates Pine needles Pine trees Pinus contorta Respiration rhizosphere root root exudates root respiration Roots Snowmelt soil CO2 efflux Soil dynamics soil microorganisms soil moisture Soil organic matter Soil permeability soil respiration soil temperature soil water Spring sucrose Summer translocation (plant physiology) Trees water stress Winter Colorado
ISSN:	1354-1013, 1365-2486
On-line přístup:	Získat plný text
Tagy:	Přidat tag Žádné tagy, Buďte první, kdo vytvoří štítek k tomuto záznamu!

Abstract	The partitioning of soil respiration rates into the component processes of rhizospheric respiration (because of live roots and those microorganisms that subsist on root exudations) and heterotrophic respiration (because of decomposer microorganisms that subsist on the oxidation of soil organic matter) is difficult to accomplish through experimental observation. In order to minimize disturbance to the soil and maximize preservation of the natural relationships among roots, rhizospheric microorganisms, and decomposers, we conducted a girdling experiment in a subalpine forest dominated by lodgepole pine trees. In two separate years, we girdled trees in small forest plots (5-7 m in diameter) and trenched around the plots to sever invading roots in order to experimentally stop the transport of photosynthate from needles to roots, and eliminate rhizospheric respiration. Soil respiration rates in plots with trees girdled over 1 year prior to measurement were higher than those in plots with trees girdled 2-3 months prior to measurement. These results suggest that any stimulation of respiration because of the experimental artifact of fine root death and addition of labile carbon to the pool of decomposer substrates is slow, and occurs beyond the first growing season after girdling. Compared with control plots with nongirdled trees, soil respiration rates in plots with girdled trees were reduced by 31-44% at the mid-summer respiratory maximum. An extreme drought during one of the 2 years used for observations caused greater reductions in the heterotrophic component of soil respiration compared with the rhizospheric component. In control plots, we observed a pulse in K₂SO₄-extractable carbon during the spring snowmelt period, which was absent in plots with girdled trees. In control plots, soil microbial biomass increased from spring to summer, coincident with a seasonal increase in the rhizospheric component of soil respiration. In plots with girdled trees, the seasonal increase in microbial biomass was lower than in control plots. These results suggest that the observed seasonal increase in rhizospheric respiration rate in control plots was because of an increase in rhizospheric microbial biomass following 'soil priming' by a spring-time pulse in dissolved organic carbon. Winter-time, beneath-snow microbial biomass was relatively high in control plots. Soil sucrose concentrations were approximately eight times higher during winter than during spring or summer, possibly being derived from the mechanical damage of shallow roots that use sucrose as protection against low-temperature extremes. The winter-time sucrose pulse was not observed in plots with girdled trees. The results of this study demonstrate that (1) the rhizospheric component of soil respiration rate at this site is significant in magnitude, (2) the heterotrophic component of soil respiration rate is more susceptible to seasonal drought than the rhizospheric component, and (3) the trees in this ecosystem exert a major control over soil carbon dynamics by 'priming' the soil with sugar exudates during the late-spring snowmelt period and releasing high concentrations of sucrose to the soil during winter.
AbstractList	The partitioning of soil respiration rates into the component processes of rhizospheric respiration (because of live roots and those microorganisms that subsist on root exudations) and heterotrophic respiration (because of decomposer microorganisms that subsist on the oxidation of soil organic matter) is difficult to accomplish through experimental observation. In order to minimize disturbance to the soil and maximize preservation of the natural relationships among roots, rhizospheric microorganisms, and decomposers, we conducted a girdling experiment in a subalpine forest dominated by lodgepole pine trees. In two separate years, we girdled trees in small forest plots (5–7 m in diameter) and trenched around the plots to sever invading roots in order to experimentally stop the transport of photosynthate from needles to roots, and eliminate rhizospheric respiration. Soil respiration rates in plots with trees girdled over 1 year prior to measurement were higher than those in plots with trees girdled 2–3 months prior to measurement. These results suggest that any stimulation of respiration because of the experimental artifact of fine root death and addition of labile carbon to the pool of decomposer substrates is slow, and occurs beyond the first growing season after girdling. Compared with control plots with nongirdled trees, soil respiration rates in plots with girdled trees were reduced by 31–44% at the mid‐summer respiratory maximum. An extreme drought during one of the 2 years used for observations caused greater reductions in the heterotrophic component of soil respiration compared with the rhizospheric component. In control plots, we observed a pulse in K 2 SO 4 ‐extractable carbon during the spring snowmelt period, which was absent in plots with girdled trees. In control plots, soil microbial biomass increased from spring to summer, coincident with a seasonal increase in the rhizospheric component of soil respiration. In plots with girdled trees, the seasonal increase in microbial biomass was lower than in control plots. These results suggest that the observed seasonal increase in rhizospheric respiration rate in control plots was because of an increase in rhizospheric microbial biomass following ‘soil priming’ by a spring‐time pulse in dissolved organic carbon. Winter‐time, beneath‐snow microbial biomass was relatively high in control plots. Soil sucrose concentrations were approximately eight times higher during winter than during spring or summer, possibly being derived from the mechanical damage of shallow roots that use sucrose as protection against low‐temperature extremes. The winter‐time sucrose pulse was not observed in plots with girdled trees. The results of this study demonstrate that (1) the rhizospheric component of soil respiration rate at this site is significant in magnitude, (2) the heterotrophic component of soil respiration rate is more susceptible to seasonal drought than the rhizospheric component, and (3) the trees in this ecosystem exert a major control over soil carbon dynamics by ‘priming’ the soil with sugar exudates during the late‐spring snowmelt period and releasing high concentrations of sucrose to the soil during winter. The partitioning of soil respiration rates into the component processes of rhizospheric respiration (because of live roots and those microorganisms that subsist on root exudations) and heterotrophic respiration (because of decomposer microorganisms that subsist on the oxidation of soil organic matter) is difficult to accomplish through experimental observation. In order to minimize disturbance to the soil and maximize preservation of the natural relationships among roots, rhizospheric microorganisms, and decomposers, we conducted a girdling experiment in a subalpine forest dominated by lodgepole pine trees. In two separate years, we girdled trees in small forest plots (5-7 m in diameter) and trenched around the plots to sever invading roots in order to experimentally stop the transport of photosynthate from needles to roots, and eliminate rhizospheric respiration. Soil respiration rates in plots with trees girdled over 1 year prior to measurement were higher than those in plots with trees girdled 2-3 months prior to measurement. These results suggest that any stimulation of respiration because of the experimental artifact of fine root death and addition of labile carbon to the pool of decomposer substrates is slow, and occurs beyond the first growing season after girdling. Compared with control plots with nongirdled trees, soil respiration rates in plots with girdled trees were reduced by 31-44% at the mid-summer respiratory maximum. An extreme drought during one of the 2 years used for observations caused greater reductions in the heterotrophic component of soil respiration compared with the rhizospheric component. In control plots, we observed a pulse in K₂SO₄-extractable carbon during the spring snowmelt period, which was absent in plots with girdled trees. In control plots, soil microbial biomass increased from spring to summer, coincident with a seasonal increase in the rhizospheric component of soil respiration. In plots with girdled trees, the seasonal increase in microbial biomass was lower than in control plots. These results suggest that the observed seasonal increase in rhizospheric respiration rate in control plots was because of an increase in rhizospheric microbial biomass following 'soil priming' by a spring-time pulse in dissolved organic carbon. Winter-time, beneath-snow microbial biomass was relatively high in control plots. Soil sucrose concentrations were approximately eight times higher during winter than during spring or summer, possibly being derived from the mechanical damage of shallow roots that use sucrose as protection against low-temperature extremes. The winter-time sucrose pulse was not observed in plots with girdled trees. The results of this study demonstrate that (1) the rhizospheric component of soil respiration rate at this site is significant in magnitude, (2) the heterotrophic component of soil respiration rate is more susceptible to seasonal drought than the rhizospheric component, and (3) the trees in this ecosystem exert a major control over soil carbon dynamics by 'priming' the soil with sugar exudates during the late-spring snowmelt period and releasing high concentrations of sucrose to the soil during winter. The partitioning of soil respiration rates into the component processes of rhizospheric respiration (because of live roots and those microorganisms that subsist on root exudations) and heterotrophic respiration (because of decomposer microorganisms that subsist on the oxidation of soil organic matter) is difficult to accomplish through experimental observation. In order to minimize disturbance to the soil and maximize preservation of the natural relationships among roots, rhizospheric microorganisms, and decomposers, we conducted a girdling experiment in a subalpine forest dominated by lodgepole pine trees. In two separate years, we girdled trees in small forest plots (5–7 m in diameter) and trenched around the plots to sever invading roots in order to experimentally stop the transport of photosynthate from needles to roots, and eliminate rhizospheric respiration. Soil respiration rates in plots with trees girdled over 1 year prior to measurement were higher than those in plots with trees girdled 2–3 months prior to measurement. These results suggest that any stimulation of respiration because of the experimental artifact of fine root death and addition of labile carbon to the pool of decomposer substrates is slow, and occurs beyond the first growing season after girdling. Compared with control plots with nongirdled trees, soil respiration rates in plots with girdled trees were reduced by 31–44% at the mid‐summer respiratory maximum. An extreme drought during one of the 2 years used for observations caused greater reductions in the heterotrophic component of soil respiration compared with the rhizospheric component. In control plots, we observed a pulse in K2SO4‐extractable carbon during the spring snowmelt period, which was absent in plots with girdled trees. In control plots, soil microbial biomass increased from spring to summer, coincident with a seasonal increase in the rhizospheric component of soil respiration. In plots with girdled trees, the seasonal increase in microbial biomass was lower than in control plots. These results suggest that the observed seasonal increase in rhizospheric respiration rate in control plots was because of an increase in rhizospheric microbial biomass following ‘soil priming’ by a spring‐time pulse in dissolved organic carbon. Winter‐time, beneath‐snow microbial biomass was relatively high in control plots. Soil sucrose concentrations were approximately eight times higher during winter than during spring or summer, possibly being derived from the mechanical damage of shallow roots that use sucrose as protection against low‐temperature extremes. The winter‐time sucrose pulse was not observed in plots with girdled trees. The results of this study demonstrate that (1) the rhizospheric component of soil respiration rate at this site is significant in magnitude, (2) the heterotrophic component of soil respiration rate is more susceptible to seasonal drought than the rhizospheric component, and (3) the trees in this ecosystem exert a major control over soil carbon dynamics by ‘priming’ the soil with sugar exudates during the late‐spring snowmelt period and releasing high concentrations of sucrose to the soil during winter. The partitioning of soil respiration rates into the component processes of rhizospheric respiration (because of live roots and those microorganisms that subsist on root exudations) and heterotrophic respiration (because of decomposer microorganisms that subsist on the oxidation of soil organic matter) is difficult to accomplish through experimental observation. In order to minimize disturbance to the soil and maximize preservation of the natural relationships among roots, rhizospheric microorganisms, and decomposers, we conducted a girdling experiment in a subalpine forest dominated by lodgepole pine trees. In two separate years, we girdled trees in small forest plots (5-7 m in diameter) and trenched around the plots to sever invading roots in order to experimentally stop the transport of photosynthate from needles to roots, and eliminate rhizospheric respiration. Soil respiration rates in plots with trees girdled over 1 year prior to measurement were higher than those in plots with trees girdled 2-3 months prior to measurement. These results suggest that any stimulation of respiration because of the experimental artifact of fine root death and addition of labile carbon to the pool of decomposer substrates is slow, and occurs beyond the first growing season after girdling. Compared with control plots with nongirdled trees, soil respiration rates in plots with girdled trees were reduced by 31-44% at the mid-summer respiratory maximum. An extreme drought during one of the 2 years used for observations caused greater reductions in the heterotrophic component of soil respiration compared with the rhizospheric component. In control plots, we observed a pulse in K2SO4-extractable carbon during the spring snowmelt period, which was absent in plots with girdled trees. In control plots, soil microbial biomass increased from spring to summer, coincident with a seasonal increase in the rhizospheric component of soil respiration. In plots with girdled trees, the seasonal increase in microbial biomass was lower than in control plots. These results suggest that the observed seasonal increase in rhizospheric respiration rate in control plots was because of an increase in rhizospheric microbial biomass following 'soil priming' by a spring-time pulse in dissolved organic carbon. Winter-time, beneath-snow microbial biomass was relatively high in control plots. Soil sucrose concentrations were approximately eight times higher during winter than during spring or summer, possibly being derived from the mechanical damage of shallow roots that use sucrose as protection against low-temperature extremes. The winter-time sucrose pulse was not observed in plots with girdled trees. The results of this study demonstrate that (1) the rhizospheric component of soil respiration rate at this site is significant in magnitude, (2) the heterotrophic component of soil respiration rate is more susceptible to seasonal drought than the rhizospheric component, and (3) the trees in this ecosystem exert a major control over soil carbon dynamics by 'priming' the soil with sugar exudates during the late-spring snowmelt period and releasing high concentrations of sucrose to the soil during winter.[PUBLICATION ABSTRACT] The partitioning of soil respiration rates into the component processes of rhizospheric respiration (because of live roots and those microorganisms that subsist on root exudations) and heterotrophic respiration (because of decomposer microorganisms that subsist on the oxidation of soil organic matter) is difficult to accomplish through experimental observation. In order to minimize disturbance to the soil and maximize preservation of the natural relationships among roots, rhizospheric microorganisms, and decomposers, we conducted a girdling experiment in a subalpine forest dominated by lodgepole pine trees. In two separate years, we girdled trees in small forest plots (5-7 m in diameter) and trenched around the plots to sever invading roots in order to experimentally stop the transport of photosynthate from needles to roots, and eliminate rhizospheric respiration. Soil respiration rates in plots with trees girdled over 1 year prior to measurement were higher than those in plots with trees girdled 2-3 months prior to measurement. These results suggest that any stimulation of respiration because of the experimental artifact of fine root death and addition of labile carbon to the pool of decomposer substrates is slow, and occurs beyond the first growing season after girdling. Compared with control plots with nongirdled trees, soil respiration rates in plots with girdled trees were reduced by 31-44% at the mid-summer respiratory maximum. An extreme drought during one of the 2 years used for observations caused greater reductions in the heterotrophic component of soil respiration compared with the rhizospheric component. In control plots, we observed a pulse in K sub(2)SO sub(4)-extractable carbon during the spring snowmelt period, which was absent in plots with girdled trees. In control plots, soil microbial biomass increased from spring to summer, coincident with a seasonal increase in the rhizospheric component of soil respiration. In plots with girdled trees, the seasonal increase in microbial biomass was lower than in control plots. These results suggest that the observed seasonal increase in rhizospheric respiration rate in control plots was because of an increase in rhizospheric microbial biomass following 'soil priming' by a spring-time pulse in dissolved organic carbon. Winter-time, beneath-snow microbial biomass was relatively high in control plots. Soil sucrose concentrations were approximately eight times higher during winter than during spring or summer, possibly being derived from the mechanical damage of shallow roots that use sucrose as protection against low-temperature extremes. The winter-time sucrose pulse was not observed in plots with girdled trees. The results of this study demonstrate that (1) the rhizospheric component of soil respiration rate at this site is significant in magnitude, (2) the heterotrophic component of soil respiration rate is more susceptible to seasonal drought than the rhizospheric component, and (3) the trees in this ecosystem exert a major control over soil carbon dynamics by 'priming' the soil with sugar exudates during the late-spring snowmelt period and releasing high concentrations of sucrose to the soil during winter.
Author	Monson, Russell K Rosenstiel, Todd N Scott-Denton, Laura E
Author_xml	– sequence: 1 fullname: Scott-Denton, Laura E – sequence: 2 fullname: Rosenstiel, Todd N – sequence: 3 fullname: Monson, Russell K
BookMark	eNqNkktv1DAUhSNUJNrCb8BiwS7B73EWIMFAZ5AqEIKKpZU4N8RDJg62Q2f49TgT1EU31As_4u8cO_f4Ijsb3ABZhgguSGqvdgVhUuSUK1lQjEWBCZa8ODzKzu82zua54DnBhD3JLkLYYYwZxfI8m97btgUPQ7RVj4wbond9QPURmd7uqwioGhoUpjpEP6_cb_AodoA6iOBdosfOmhPkO_vHhbEDnz4Ytx_TRYcYkGtRcLZHHsJok4l1w9PscVv1AZ79Gy-zm6sP39bb_Prz5uP67XVuBMM8b6ipW9EaroDXwBvJVFtxTpmpgTBKhSppRTlhq5KKpiW0KXHaNLUiUIMEdpm9XHxH735NEKLe22Cg76sB3BQ0l4oTrPh_QVJyJqRUCXxxD9y5yQ_pJzTFgjCsKE2QWiDjXQgeWj36VEx_1ATrOTW903M4eg5Hz6npU2r6kKRv7kmNjaeapfrb_iEGrxeDW9vD8cEH68363TxL-nzR2xDhcKev_E8tV2wl9PdPG72i23K7_aK0SPzzhW8rp6sf3gZ985Wmh5aMhUo9-wvhhM0j
CitedBy_id	crossref_primary_10_1016_j_agrformet_2019_107619 crossref_primary_10_1007_s00442_013_2844_z crossref_primary_10_1371_journal_pone_0159131 crossref_primary_10_1111_j_1365_3040_2006_01610_x crossref_primary_10_1007_s11368_016_1440_3 crossref_primary_10_1371_journal_pone_0126337 crossref_primary_10_1016_j_soilbio_2025_109983 crossref_primary_10_1890_ES11_00225_1 crossref_primary_10_1016_j_catena_2022_106207 crossref_primary_10_1111_nph_13303 crossref_primary_10_1038_s41467_020_17790_5 crossref_primary_10_1016_j_soilbio_2015_07_023 crossref_primary_10_1890_12_0150_1 crossref_primary_10_1002_jeq2_20104 crossref_primary_10_1016_j_ejsobi_2014_11_003 crossref_primary_10_1111_j_1469_8137_2010_03321_x crossref_primary_10_1007_s11104_017_3258_1 crossref_primary_10_1016_j_agrformet_2011_10_007 crossref_primary_10_5194_bg_8_3457_2011 crossref_primary_10_1007_s11368_013_0799_7 crossref_primary_10_1016_j_apsoil_2011_10_014 crossref_primary_10_1111_nph_12568 crossref_primary_10_3832_ifor4097_016 crossref_primary_10_1016_j_soilbio_2013_03_015 crossref_primary_10_1051_agro_2010007 crossref_primary_10_1007_s10021_008_9215_3 crossref_primary_10_1007_s10533_010_9534_2 crossref_primary_10_1007_s10021_019_00394_6 crossref_primary_10_1371_journal_pone_0080937 crossref_primary_10_1007_s11104_015_2730_z crossref_primary_10_1016_j_foreco_2015_01_031 crossref_primary_10_1111_1365_2435_13300 crossref_primary_10_1002_ldr_2986 crossref_primary_10_1111_j_1469_8137_2006_01836_x crossref_primary_10_1007_s00442_007_0804_1 crossref_primary_10_1038_s41598_018_34969_5 crossref_primary_10_1038_s43247_024_01810_z crossref_primary_10_1111_nph_14972 crossref_primary_10_3389_fpls_2019_00157 crossref_primary_10_1007_s11284_013_1079_0 crossref_primary_10_1007_s11676_022_01516_y crossref_primary_10_1016_j_envpol_2010_11_025 crossref_primary_10_1016_j_foreco_2006_09_030 crossref_primary_10_1088_1748_9326_8_2_024017 crossref_primary_10_1111_ele_12097 crossref_primary_10_1007_s11104_018_3751_1 crossref_primary_10_1002_ppp3_10181 crossref_primary_10_1111_j_1365_2486_2006_01234_x crossref_primary_10_1016_j_agrformet_2008_11_013 crossref_primary_10_1016_j_soilbio_2007_10_003 crossref_primary_10_1016_j_jes_2015_08_019 crossref_primary_10_1007_s00442_015_3227_4 crossref_primary_10_1016_j_foreco_2009_01_036 crossref_primary_10_1016_j_soilbio_2015_06_027 crossref_primary_10_1111_j_1365_2745_2010_01740_x crossref_primary_10_1002_ece3_5762 crossref_primary_10_1016_j_soilbio_2014_04_013 crossref_primary_10_1016_j_soilbio_2010_12_014 crossref_primary_10_1111_j_1365_2435_2008_01495_x crossref_primary_10_1007_s00248_008_9387_6 crossref_primary_10_1007_s11104_018_03900_2 crossref_primary_10_1016_j_agee_2025_109672 crossref_primary_10_3390_f10010008 crossref_primary_10_1016_j_fcr_2016_09_014 crossref_primary_10_1111_j_1365_3040_2010_02185_x crossref_primary_10_3389_ffgc_2019_00011 crossref_primary_10_1002_ldr_2161 crossref_primary_10_1002_ecs2_1426 crossref_primary_10_1007_s11676_023_01636_z crossref_primary_10_3390_rs13132571 crossref_primary_10_1016_j_soilbio_2020_107752 crossref_primary_10_3390_f7100221 crossref_primary_10_1007_s42729_021_00713_8 crossref_primary_10_1111_ajgw_12279 crossref_primary_10_1002_2014JG002802 crossref_primary_10_1002_hyp_7870 crossref_primary_10_1371_journal_pone_0117490 crossref_primary_10_1016_j_soilbio_2018_09_007 crossref_primary_10_1093_treephys_tpy020 crossref_primary_10_1007_s10533_018_0472_8 crossref_primary_10_1007_s11104_010_0533_9 crossref_primary_10_1007_s11676_020_01262_z crossref_primary_10_5194_bg_21_2005_2024 crossref_primary_10_1111_j_1574_6941_2006_00240_x crossref_primary_10_1016_j_soilbio_2013_06_002 crossref_primary_10_1002_ecs2_1655 crossref_primary_10_1016_j_soilbio_2012_09_016 crossref_primary_10_1016_j_scitotenv_2012_04_027 crossref_primary_10_1016_j_catena_2024_107906 crossref_primary_10_1111_ele_14349 crossref_primary_10_3390_atmos10110708 crossref_primary_10_1007_s40974_016_0034_7 crossref_primary_10_1007_s00442_014_2948_0 crossref_primary_10_1007_s10533_013_9872_y crossref_primary_10_1016_j_agrformet_2011_01_009 crossref_primary_10_1016_j_geoderma_2021_115404 crossref_primary_10_1029_2022GL101147 crossref_primary_10_1371_journal_pone_0136344 crossref_primary_10_1016_j_catena_2021_105617 crossref_primary_10_1371_journal_pone_0155881 crossref_primary_10_1007_s10533_008_9252_1 crossref_primary_10_1002_2013JG002575 crossref_primary_10_1111_nph_16704 crossref_primary_10_1016_j_soilbio_2011_07_011 crossref_primary_10_1007_s11104_009_9986_0 crossref_primary_10_1073_pnas_1008885107 crossref_primary_10_5194_bg_7_2901_2010 crossref_primary_10_2136_sssaj2014_10_0431 crossref_primary_10_1007_s12665_016_5528_2 crossref_primary_10_1007_s11104_022_05674_0 crossref_primary_10_1007_s10533_007_9069_3 crossref_primary_10_1016_j_soilbio_2014_07_027 crossref_primary_10_1016_j_geodrs_2020_e00290 crossref_primary_10_1016_j_soilbio_2014_03_006 crossref_primary_10_1111_j_1469_8137_2009_03050_x crossref_primary_10_1016_j_soilbio_2015_05_017 crossref_primary_10_1016_j_ecolmodel_2008_02_007 crossref_primary_10_2136_sssaj2006_0389 crossref_primary_10_1111_j_1469_8137_2009_03001_x crossref_primary_10_1007_s12155_014_9416_x crossref_primary_10_1016_j_agrformet_2011_04_011 crossref_primary_10_1007_s11104_013_1944_1 crossref_primary_10_1111_j_1365_2486_2008_01830_x crossref_primary_10_1016_j_agrformet_2019_01_028 crossref_primary_10_1016_j_soilbio_2010_11_010 crossref_primary_10_1016_j_scitotenv_2015_07_023 crossref_primary_10_1017_S0021859622000132 crossref_primary_10_1016_j_foreco_2012_09_028 crossref_primary_10_1007_s10021_023_00863_z crossref_primary_10_1007_s10533_016_0201_0 crossref_primary_10_1111_j_1749_8198_2011_00420_x crossref_primary_10_1111_j_1365_2486_2011_02516_x crossref_primary_10_1111_gcb_14471 crossref_primary_10_1016_j_scitotenv_2019_06_318 crossref_primary_10_1007_s00442_017_3853_0 crossref_primary_10_1007_s11676_024_01710_0 crossref_primary_10_1016_j_foreco_2009_02_018 crossref_primary_10_5194_soil_2_403_2016 crossref_primary_10_1007_s10021_014_9839_4 crossref_primary_10_1016_j_still_2023_105856 crossref_primary_10_1016_j_agrformet_2007_11_003 crossref_primary_10_1016_j_agrformet_2022_109086 crossref_primary_10_1007_s00374_014_0901_3 crossref_primary_10_1007_s00374_019_01347_w crossref_primary_10_1016_j_soilbio_2008_01_011 crossref_primary_10_1016_j_catena_2025_109055 crossref_primary_10_1016_j_soilbio_2017_09_010 crossref_primary_10_3390_f9040184 crossref_primary_10_1890_06_0908_1 crossref_primary_10_1007_s10342_008_0250_6 crossref_primary_10_1016_j_ecolind_2011_08_013 crossref_primary_10_1007_s10021_007_9120_1 crossref_primary_10_1080_17550874_2014_904950 crossref_primary_10_1016_j_scitotenv_2013_12_071 crossref_primary_10_1111_j_1365_2486_2006_01291_x crossref_primary_10_1016_j_agrformet_2016_06_003 crossref_primary_10_1016_S1002_0160_15_60066_2 crossref_primary_10_5194_bg_16_2269_2019 crossref_primary_10_1111_j_1469_8137_2007_02079_x crossref_primary_10_5194_bg_16_1097_2019 crossref_primary_10_1016_j_agrformet_2013_08_010 crossref_primary_10_1007_s10021_010_9401_y crossref_primary_10_1016_j_ejsobi_2018_01_005 crossref_primary_10_1016_S1002_0160_13_60056_9 crossref_primary_10_1002_ecy_2985 crossref_primary_10_1016_j_scitotenv_2017_10_092 crossref_primary_10_1038_s41598_021_88914_0 crossref_primary_10_1016_j_funeco_2011_01_004 crossref_primary_10_1002_2015JG003228 crossref_primary_10_1016_j_soilbio_2010_04_018 crossref_primary_10_1016_j_agrformet_2020_107958 crossref_primary_10_1016_j_foreco_2021_119241 crossref_primary_10_1111_pce_12602 crossref_primary_10_1007_s11676_016_0337_8 crossref_primary_10_1016_j_soilbio_2017_06_021 crossref_primary_10_3390_f8070241 crossref_primary_10_1016_j_agrformet_2011_09_015 crossref_primary_10_1016_j_scitotenv_2020_139634 crossref_primary_10_1016_j_ecoleng_2011_03_024 crossref_primary_10_1016_j_soilbio_2007_03_024 crossref_primary_10_2136_sssaj2018_07_0248 crossref_primary_10_1029_2005GB002684 crossref_primary_10_3120_0024_9637_60_2_95 crossref_primary_10_1007_s11104_018_3777_4 crossref_primary_10_1111_ejss_12670 crossref_primary_10_1111_j_1365_2486_2008_01757_x crossref_primary_10_1139_cjfr_2013_0334 crossref_primary_10_1007_s10533_006_9065_z crossref_primary_10_1016_j_agrformet_2012_05_017 crossref_primary_10_1111_j_1469_8137_2007_02204_x crossref_primary_10_1016_j_ecolind_2024_112180 crossref_primary_10_1016_j_foreco_2020_118660 crossref_primary_10_1007_s00374_016_1087_7 crossref_primary_10_1111_1365_2745_13896 crossref_primary_10_1111_j_1574_6941_2009_00733_x crossref_primary_10_1016_j_agee_2012_12_012 crossref_primary_10_1111_j_1574_6941_2012_01420_x crossref_primary_10_1016_j_agrformet_2012_05_022 crossref_primary_10_1016_j_soilbio_2018_04_029 crossref_primary_10_1016_j_apsoil_2011_12_002 crossref_primary_10_1111_j_1365_2486_2012_02721_x crossref_primary_10_5194_bg_12_7349_2015 crossref_primary_10_1016_j_soilbio_2021_108184 crossref_primary_10_1007_s11104_015_2750_8 crossref_primary_10_1111_j_1365_2486_2012_02696_x crossref_primary_10_1111_j_1365_2486_2011_02484_x crossref_primary_10_1007_s00374_016_1100_1 crossref_primary_10_1007_s11284_010_0722_2 crossref_primary_10_1016_j_scitotenv_2018_06_111 crossref_primary_10_1111_j_1365_2486_2007_01433_x crossref_primary_10_1007_s00442_006_0565_2 crossref_primary_10_1002_ecs2_4092 crossref_primary_10_5194_bg_11_4289_2014 crossref_primary_10_1111_ejss_12777 crossref_primary_10_1111_j_1365_2486_2008_01609_x crossref_primary_10_1016_j_agrformet_2014_09_013 crossref_primary_10_1007_s11104_010_0394_2 crossref_primary_10_1111_j_1365_2435_2011_01845_x crossref_primary_10_1111_pce_12716 crossref_primary_10_1007_s10533_014_0008_9 crossref_primary_10_1007_s11104_014_2159_9 crossref_primary_10_1016_j_agrformet_2007_06_001 crossref_primary_10_1007_s10533_008_9233_4 crossref_primary_10_1007_s11427_015_4935_z crossref_primary_10_1111_nph_13955 crossref_primary_10_3389_fmicb_2014_00261
Cites_doi	10.1038/35081058 10.1029/94GB02723 10.1016/S0038-0717(99)00068-1 10.1007/s00442-004-1540-4 10.1029/2001GB001821 10.1046/j.1365-3040.2003.01053.x 10.1046/j.1365-3040.1997.d01-56.x 10.1046/j.1469-8137.2002.00417.x 10.1086/286095 10.1029/2003GB002119 10.1007/s10533-004-2946-0 10.1023/A:1006289905991 10.1046/j.1365-2486.1999.00214.x 10.1139/x26-180 10.1016/0038-0717(94)00242-S 10.1038/35009084 10.1016/S0038-0717(00)00077-8 10.1029/2003GB002035 10.1029/94GB00993 10.1016/0038-0717(93)90147-4 10.1023/A:1006244819642 10.1139/x03-090 10.1046/j.1365-2486.2002.00480.x 10.1038/35009076 10.1007/s00248-001-1057-x 10.1029/2000GB001365 10.1016/S0168-1923(01)00290-8 10.1038/25119 10.1093/treephys/24.4.415 10.1016/S0038-0717(01)00020-7 10.1890/0012-9658(1999)080[1150:TMAORR]2.0.CO;2 10.1016/S0038-0717(03)00007-5 10.1007/s004420050363 10.1007/s004420100667 10.1038/351304a0 10.1029/2002WR001738 10.1034/j.1600-0889.1992.t01-1-00001.x 10.1111/j.1469-8137.2004.01053.x 10.1016/0038-0717(96)00124-1 10.1073/pnas.94.16.8284 10.1029/98GB01035 10.1023/A:1004757405147 10.1093/treephys/16.8.719 10.1023/A:1026192607512 10.1029/1999GB001248 10.1128/aem.62.4.1428-1430.1996 10.1002/1522-2624(200208)165:4<382::AID-JPLN382>3.0.CO;2-# 10.1016/0038-0717(89)90157-0
ContentType	Journal Article
Copyright	2005 Blackwell Publishing Ltd
Copyright_xml	– notice: 2005 Blackwell Publishing Ltd
DBID	FBQ BSCLL AAYXX CITATION 7SN 7UA C1K F1W H97 L.G 7T7 7TG 8FD FR3 KL. P64 7S9 L.6
DOI	10.1111/j.1365-2486.2005.01064.x
DatabaseName	AGRIS Istex CrossRef Ecology Abstracts Water Resources Abstracts Environmental Sciences and Pollution Management ASFA: Aquatic Sciences and Fisheries Abstracts Aquatic Science & Fisheries Abstracts (ASFA) 3: Aquatic Pollution & Environmental Quality Aquatic Science & Fisheries Abstracts (ASFA) Professional Industrial and Applied Microbiology Abstracts (Microbiology A) Meteorological & Geoastrophysical Abstracts Technology Research Database Engineering Research Database Meteorological & Geoastrophysical Abstracts - Academic Biotechnology and BioEngineering Abstracts AGRICOLA AGRICOLA - Academic
DatabaseTitle	CrossRef Aquatic Science & Fisheries Abstracts (ASFA) Professional Ecology Abstracts Aquatic Science & Fisheries Abstracts (ASFA) 3: Aquatic Pollution & Environmental Quality ASFA: Aquatic Sciences and Fisheries Abstracts Water Resources Abstracts Environmental Sciences and Pollution Management Meteorological & Geoastrophysical Abstracts Technology Research Database Engineering Research Database Industrial and Applied Microbiology Abstracts (Microbiology A) Meteorological & Geoastrophysical Abstracts - Academic Biotechnology and BioEngineering Abstracts AGRICOLA AGRICOLA - Academic
DatabaseTitleList	CrossRef AGRICOLA Aquatic Science & Fisheries Abstracts (ASFA) Professional Meteorological & Geoastrophysical Abstracts
DeliveryMethod	fulltext_linktorsrc
Discipline	Meteorology & Climatology Biology Environmental Sciences
EISSN	1365-2486
EndPage	216
ExternalDocumentID	978659701 10_1111_j_1365_2486_2005_01064_x GCB1064 ark_67375_WNG_72H9HHQ8_5 US201301058301
Genre	article Feature
GeographicLocations	Colorado
GeographicLocations_xml	– name: Colorado
GroupedDBID	-DZ .3N .GA .Y3 05W 0R~ 10A 1OB 1OC 29I 31~ 33P 3SF 4.4 50Y 50Z 51W 51X 52M 52N 52O 52P 52S 52T 52U 52W 52X 53G 5GY 5HH 5LA 5VS 66C 702 7PT 8-0 8-1 8-3 8-4 8-5 8UM 930 A03 AAESR AAEVG AAHHS AANLZ AAONW AASGY AAXRX AAZKR ABCQN ABCUV ABEFU ABEML ABHUG ABJNI ABPTK ABPVW ACAHQ ACBWZ ACCFJ ACCZN ACGFS ACPOU ACPRK ACSCC ACXBN ACXME ACXQS ADAWD ADBBV ADDAD ADEOM ADIZJ ADKYN ADMGS ADOZA ADXAS ADZMN ADZOD AEEZP AEIGN AEIMD AENEX AEQDE AEUQT AEUYR AFBPY AFEBI AFFPM AFGKR AFPWT AFRAH AFVGU AFZJQ AGJLS AHEFC AIURR AIWBW AJBDE AJXKR ALAGY ALMA_UNASSIGNED_HOLDINGS ALUQN AMBMR AMYDB ASPBG ATUGU AUFTA AVWKF AZBYB AZFZN AZVAB BAFTC BDRZF BFHJK BHBCM BMNLL BMXJE BNHUX BROTX BRXPI BY8 C45 CAG COF CS3 D-E D-F DC6 DCZOG DDYGU DPXWK DR2 DRFUL DRSTM DU5 EBS ECGQY EJD ESX F00 F01 F04 FBQ FEDTE FZ0 G-S G.N GODZA H.T H.X HF~ HVGLF HZI HZ~ IHE IX1 J0M K48 LATKE LC2 LC3 LEEKS LH4 LITHE LOXES LP6 LP7 LUTES LW6 LYRES MEWTI MK4 MRFUL MRSTM MSFUL MSSTM MXFUL MXSTM N04 N05 N9A NF~ O66 O9- OVD P2P P2W P2X P4D PALCI PQQKQ Q.N Q11 QB0 R.K RIWAO RJQFR ROL RX1 SAMSI SUPJJ TEORI UB1 UQL VOH W8V W99 WBKPD WIH WIK WNSPC WOHZO WQJ WRC WUP WXSBR WYISQ XG1 Y6R ZZTAW ~02 ~IA ~KM ~WT AAHBH AAHQN AAMMB AAMNL AANHP AAYCA ACRPL ACYXJ ADNMO AEFGJ AEYWJ AFWVQ AGHNM AGQPQ AGXDD AGYGG AHBTC AIDQK AIDYY AIQQE AITYG ALVPJ BSCLL HGLYW OIG AAYXX CITATION O8X 7SN 7UA C1K F1W H97 L.G 7T7 7TG 8FD FR3 KL. P64 7S9 L.6
ID	FETCH-LOGICAL-c5304-d2cbf5fc48e4be4d638fa4423cbe13225892a24137925df12d9023ccb81ebe6e3
IEDL.DBID	DRFUL
ISICitedReferencesCount	256
ISICitedReferencesURI	http://www.webofscience.com/api/gateway?GWVersion=2&SrcApp=Summon&SrcAuth=ProQuest&DestLinkType=CitingArticles&DestApp=WOS_CPL&KeyUT=000234974900006&url=https%3A%2F%2Fcvtisr.summon.serialssolutions.com%2F%23%21%2Fsearch%3Fho%3Df%26include.ft.matches%3Dt%26l%3Dnull%26q%3D
ISSN	1354-1013
IngestDate	Fri Jul 11 14:41:51 EDT 2025 Tue Oct 07 09:23:00 EDT 2025 Mon Nov 10 03:05:03 EST 2025 Sat Nov 29 06:02:07 EST 2025 Tue Nov 18 22:35:48 EST 2025 Wed Jan 22 16:23:27 EST 2025 Tue Nov 11 03:30:45 EST 2025 Wed Dec 27 19:15:22 EST 2023
IsPeerReviewed	true
IsScholarly	true
Issue	2
Language	English
License	http://onlinelibrary.wiley.com/termsAndConditions#vor
LinkModel	DirectLink
MergedId	FETCHMERGED-LOGICAL-c5304-d2cbf5fc48e4be4d638fa4423cbe13225892a24137925df12d9023ccb81ebe6e3
Notes	http://dx.doi.org/10.1111/j.1365-2486.2005.01064.x istex:B8E4955FB868F6038CE93E14FD69B02192400065 ArticleID:GCB1064 ark:/67375/WNG-72H9HHQ8-5 SourceType-Scholarly Journals-1 ObjectType-Feature-1 content type line 14 ObjectType-Article-1 ObjectType-Feature-2 content type line 23
PQID	205130822
PQPubID	30327
PageCount	12
ParticipantIDs	proquest_miscellaneous_46841084 proquest_miscellaneous_19435668 proquest_journals_205130822 crossref_primary_10_1111_j_1365_2486_2005_01064_x crossref_citationtrail_10_1111_j_1365_2486_2005_01064_x wiley_primary_10_1111_j_1365_2486_2005_01064_x_GCB1064 istex_primary_ark_67375_WNG_72H9HHQ8_5 fao_agris_US201301058301
PublicationCentury	2000
PublicationDate	February 2006
PublicationDateYYYYMMDD	2006-02-01
PublicationDate_xml	– month: 02 year: 2006 text: February 2006
PublicationDecade	2000
PublicationPlace	Oxford, UK
PublicationPlace_xml	– name: Oxford, UK – name: Oxford
PublicationTitle	Global change biology
PublicationYear	2006
Publisher	Oxford, UK : Blackwell Science Ltd Blackwell Science Ltd Blackwell Publishing Ltd
Publisher_xml	– name: Oxford, UK : Blackwell Science Ltd – name: Blackwell Science Ltd – name: Blackwell Publishing Ltd
References	Hanson PJ, Edwards NT, Garten CT et al. (2000) Separating root and soil microbial contributions to soil respiration: a review of methods and observations. Biogeochemistry, 48, 115-146. Hibbard K, Law B, Reichstein M et al. (2004) An analysis of soil respiration across Northern Hemisphere temperate ecosystems. Biogeochemistry, 73, 29-70. Högberg P, Ekblad A (1996) Substrate induced respiration measured in situ in a C3-plant ecosystem using additions of C4-sucrose. Soil Biology and Biochemistry, 28, 1131-1138. Subke J-A, Hahn V, Battipaglia G et al. (2004) Feedback interactions between needle litter decomposition and rhizospheric activity. Oecologia, 139, 551-559. Trumbore SE (1997) Potential response of soil organic carbon to global environmental change. Proceedings of the National Academy of Science, USA, 94, 8284-8291. Bhupinderpal-Singh NA, Ottosson LM, Högberg MN et al. (2003) Tree root and soil heterotrophic respiration as revealed by girdling of boreal Scots pine forest: extending observations beyond the first year. Plant, Cell and Environment, 26, 1287-1296. Hood E, McKnight DM, Williams MW (2003) Sources and chemical character of dissolved organic carbon (DOC) across a alpine/subalpine ecotone, Green Lakes Valley, Colorado Front Range, USA. Water Resources Research, 39, Art No. 1188. Lavigne MB, Boutin R, Foster RJ et al. (2003) Soil respiration responses to temperature are controlled more by roots than by decomposition in balsam fir ecosystems. Canadian Journal of Forest Research, 33, 1744-1753. Monson RK, Turnipseed AA, Sparks JP et al. (2002) Carbon sequestion in a high-elevation, subalpine forest. Global Change Biology, 8, 459-478. Jenkinson DS, Adams DE, Wild A (1991) Model estimates of CO2 emissions from soil in response to global warming. Nature, 351, 304-306. Ekblad A, Högberg P (2001) Natural abundance of 13C in CO2 respired from forest soils reveals speed of link between tree photosynthesis and root respiration. Oecologia, 127, 305-308. Lee MS, Nakane K, Nakatsubo T (2003) Seasonal changes in the contribution of root respiration to total soil respiration in a cool-temperate deciduous forest. Plant and Soil, 255, 311-318. Raich JW, Potter CS (1995) Global patterns of carbon dioxide emissions from soils. Global Biogeochemical Cycles, 9, 23-36. De Nobili M, Contin C, Mondini C et al. (2001) Soil microbial biomass is triggered into activity by trace amounts of substrate. Soil Biology and Biochemistry, 33, 1163-1170. Ögren E, Nilsson T, Sundblad LG (1997) Relationship between respiratoty depletion of sugars and loss of cold hardiness in coniferous seedlings over-wintering at raised temperatures: indications of different sensitivities of spruce and pine. Plant Cell and Environment, 10, 247-253. Wan SQ, Luo YQ (2003) Substrate regulation of soil respiration in a tallgrass prarie: results of a clipping and shading experiment. Global Biogeochemical Cycles, 17, Art. No. 1054. Savage KE, Davidson EA (2001) Interannual variation of soil respiration in two New England forests. Global Biogeochemical Cycles, 15, 337-350. Giardina CP, Ryan MG (2000) Evidence that decomposition rates of organic carbon in mineral soil do not vary with temperature. Nature, 404, 858-861. Xiao X, Melillo JM, Kicklighter DW (1998) Transient climate change and net ecosystem production of the terrestrial biosphere. Global Biogeochemical Cycles, 12, 345-360. Kuzyakov Y (2002) Factors affecting rhizosphere priming effects. Journal of Plant Nutrition and Soil Science, 165, 382-396. Lipson DA, Schmidt SK, Monson RK (2000) Carbon availability and temperature control the post-snowmelt decline in alpine soil microbial biomass. Soil Biology and Biochemistry, 32, 441-448. Hedges LV, Gurevitch J, Curtis PS (1999) The meta-analysis of response ratios in experimental ecology. Ecology, 80, 1150-1156. Stoyan H, De-Polli H, Bohm S et al. (2000) Spatial heterogeneity of soil respiration and related properties at the plant scale. Plant and Soil, 222, 203-214. Pendall E, Bridgham S, Hanson PJ et al. (2004) Belowground process responses to elevated CO2 and temperature: a discussion of observations, measurement methods and models. New Phytologist, 162, 311-322. Law BE, Ryan MG, Anthoni PM (1999) Seasonal and annual respiration of a ponderosa pine ecosystem. Global Change Biology, 5, 169-182. Reichstein M, Rey A, Freibauer A et al. (2003) Modeling temporal and large-scale variability of soil respiration from soil water variability, temperature and vegetation productivity indices. Global Biogeochemical Cycles, 17, Art. No. 1104. Casals P, Romanya J, Cortina J (2000) CO2 efflux from a Mediterranean semi-arid forest soil. I. Seasonality and effects of stoniness. Biogeochemistry, 48, 261-281. Boone RD, Nadelhoffer KJ, Canary JD et al. (1998) Roots exert a strong influence on the temperature sensitivity of soil respiration. Nature, 396, 570-572. Raich JW, Schlesinger WH (1992) The global carbon dioxide flux in soil respiration and its relationship to vegetation and climate. Tellus, Ser B, 44, 81-99. Pendall E, Del Grosso S, King JY et al. (2003) Elevated atmospheric CO2 effects and soil water feedbacks on soil respiration components in a Colorado grassland. Global Biogeochemical Cycles, 17, 1046-1059. Högberg P, Nordgren A, Buchmann N et al. (2001) Large-scale forest girdling shows that current photosynthesis drives soil respiration. Nature, 411, 789-792. Lipson DA, Schadt CW, Schmidt SK (2002) Changes in microbial community structure and function following snow melt in an alpine soil. Microbial Ecology, 43, 307-314. Gu LH, Post WM, King AW (2004) Fast labile carbon turnover obscures sensitivity of heterotrophic respiration from soil to temperature: a model analysis. Global Biogeochemical Cycles, 18, Art No. GB1022. Högberg M, Högberg P (2002) Extramatrical ectomycorrhizal mycelium contributes one-third of microbial biomass and produces, together with associated roots, half the dissolved organic carbon in a forest soil. New Phytologist, 154, 791-795. Turnipseed AA, Blanken PD, Anderson DE et al. (2002) Surface energy balance above a high-elevation, subalpine forest. Agricultural and Forest Meteorology, 110, 177-201. Valentini R, Matteucci G, Dolman AJ et al. (2000) Respiration as the main determinant of carbon balance in European forests. Nature, 404, 861-865. Xu M, Qi Y (2001) Spatial and seasonal variations of Q10 determined by soil respiration measurements at a Sierra Nevada forest. Global Biogeochemical Cycles, 15, 687-696. Lavigne MB, Foster RJ, Goodine G (2004) Seasonal and annual changes in soil respiration in relation to soil temperature, water potential and trenching. Tree Physiology, 24, 415-424. Caldwell MM, Dawson TE, Richards TH (1998) Hydraulic lift: consequences of water efflux from the roots of plants. Oecologia, 113, 151-161. Shen J, Bartha R (1996) Priming effect of substrate addition in soil-based biodegradation tests. Applied Environmental Microbiology, 62, 1428-1430. Zogg GP, Zak DR, Burton AJ et al. (1996) Fine root respiration in northern hardwood forests in relation to temperature and nitrogen. Tree Physiology, 16, 719-725. Schimel DS, Braswell BH, Holland EA et al. (1994) Climatic, edaphic and biotic controls over storage and turnover of carbon in soils. Global Biogeochemical Cycles, 8, 279-293. Mary B, Fresenau C, Morel JL et al. (1993) C and N cycling during decomposition of root mucilage, roots and glucose in soil. Soil Biology and Biochemistry, 25, 1005-1014. Kirschbaum MUF (1995) The temperature dependence of soil organic matter decomposition and the effect of global warming on soil organic carbon storage. Soil Biology and Biochemistry, 27, 753-760. Scott-Denton LE, Sparks KL, Monson RK (2003) Spatial and temporal controls of soil respiration rate in a high-elevation, subalpine forest. Soil Biology and Biochemistry, 35, 525-534. Sutinen ML, Mäkitalo K, Sutinen R (1996) Freezing dehydration damages roots of containerized Scots pine (Pinus sylvestris) seedlings overwintering under subarctic conditions. Canadian Journal of Forestry Research, 25, 1602-1609. Buchmann N (2000) Biotic and abiotic factors controlling soil respiration rates in Picea abies stands. Soil Biology and Biochemistry, 32, 1625-1635. Dalenberg JW, Jager G (1989) Priming effect of some organic additions to 14C-labelled soil. Soil Biology and Biochemistry, 21, 443-448. Osenberg CW, Sarnelle O, Cooper SD (1997) Effect size in ecological experiments: the application of biological models in meta-analysis. American Naturalist, 150, 798-812. 1991; 351 1993; 25 1995; 9 1989; 21 2000; 48 2002; 154 1997; 150 2002; 110 2004; 162 2004; 24 2002; 8 2003; 35 2003; 39 2003; 17 1998; 396 1998; 113 1999; 80 1996; 16 1999; 5 2003; 255 2003; 33 2001; 127 1994; 8 2004; 73 1996; 28 1997; 94 2004; 18 1995; 27 2002; 165 1997; 10 2000; 32 2000; 404 2002; 43 2003; 26 1996; 62 2001; 15 2000; 222 2001; 33 1996; 25 1992; 44 2004; 139 1998; 12 2001; 411 Reichstein M (e_1_2_6_34_1) 2003; 17 e_1_2_6_32_1 e_1_2_6_30_1 e_1_2_6_19_1 e_1_2_6_13_1 e_1_2_6_36_1 e_1_2_6_11_1 e_1_2_6_17_1 e_1_2_6_15_1 e_1_2_6_38_1 e_1_2_6_43_1 e_1_2_6_20_1 e_1_2_6_41_1 e_1_2_6_9_1 e_1_2_6_5_1 e_1_2_6_7_1 e_1_2_6_24_1 e_1_2_6_49_1 e_1_2_6_3_1 e_1_2_6_22_1 e_1_2_6_28_1 e_1_2_6_45_1 e_1_2_6_26_1 Shen J (e_1_2_6_40_1) 1996; 62 Wan SQ (e_1_2_6_47_1) 2003; 17 e_1_2_6_10_1 e_1_2_6_31_1 e_1_2_6_50_1 e_1_2_6_14_1 e_1_2_6_35_1 e_1_2_6_12_1 e_1_2_6_33_1 e_1_2_6_18_1 e_1_2_6_39_1 e_1_2_6_16_1 e_1_2_6_37_1 e_1_2_6_42_1 e_1_2_6_21_1 e_1_2_6_8_1 e_1_2_6_4_1 e_1_2_6_6_1 e_1_2_6_25_1 e_1_2_6_48_1 e_1_2_6_23_1 e_1_2_6_2_1 e_1_2_6_29_1 e_1_2_6_44_1 e_1_2_6_27_1 e_1_2_6_46_1
References_xml	– reference: Wan SQ, Luo YQ (2003) Substrate regulation of soil respiration in a tallgrass prarie: results of a clipping and shading experiment. Global Biogeochemical Cycles, 17, Art. No. 1054. – reference: Bhupinderpal-Singh NA, Ottosson LM, Högberg MN et al. (2003) Tree root and soil heterotrophic respiration as revealed by girdling of boreal Scots pine forest: extending observations beyond the first year. Plant, Cell and Environment, 26, 1287-1296. – reference: Subke J-A, Hahn V, Battipaglia G et al. (2004) Feedback interactions between needle litter decomposition and rhizospheric activity. Oecologia, 139, 551-559. – reference: Ekblad A, Högberg P (2001) Natural abundance of 13C in CO2 respired from forest soils reveals speed of link between tree photosynthesis and root respiration. Oecologia, 127, 305-308. – reference: Högberg M, Högberg P (2002) Extramatrical ectomycorrhizal mycelium contributes one-third of microbial biomass and produces, together with associated roots, half the dissolved organic carbon in a forest soil. New Phytologist, 154, 791-795. – reference: Pendall E, Bridgham S, Hanson PJ et al. (2004) Belowground process responses to elevated CO2 and temperature: a discussion of observations, measurement methods and models. New Phytologist, 162, 311-322. – reference: Lipson DA, Schadt CW, Schmidt SK (2002) Changes in microbial community structure and function following snow melt in an alpine soil. Microbial Ecology, 43, 307-314. – reference: Schimel DS, Braswell BH, Holland EA et al. (1994) Climatic, edaphic and biotic controls over storage and turnover of carbon in soils. Global Biogeochemical Cycles, 8, 279-293. – reference: Hanson PJ, Edwards NT, Garten CT et al. (2000) Separating root and soil microbial contributions to soil respiration: a review of methods and observations. Biogeochemistry, 48, 115-146. – reference: Högberg P, Ekblad A (1996) Substrate induced respiration measured in situ in a C3-plant ecosystem using additions of C4-sucrose. Soil Biology and Biochemistry, 28, 1131-1138. – reference: Raich JW, Potter CS (1995) Global patterns of carbon dioxide emissions from soils. Global Biogeochemical Cycles, 9, 23-36. – reference: Law BE, Ryan MG, Anthoni PM (1999) Seasonal and annual respiration of a ponderosa pine ecosystem. Global Change Biology, 5, 169-182. – reference: Gu LH, Post WM, King AW (2004) Fast labile carbon turnover obscures sensitivity of heterotrophic respiration from soil to temperature: a model analysis. Global Biogeochemical Cycles, 18, Art No. GB1022. – reference: Turnipseed AA, Blanken PD, Anderson DE et al. (2002) Surface energy balance above a high-elevation, subalpine forest. Agricultural and Forest Meteorology, 110, 177-201. – reference: Ögren E, Nilsson T, Sundblad LG (1997) Relationship between respiratoty depletion of sugars and loss of cold hardiness in coniferous seedlings over-wintering at raised temperatures: indications of different sensitivities of spruce and pine. Plant Cell and Environment, 10, 247-253. – reference: Kirschbaum MUF (1995) The temperature dependence of soil organic matter decomposition and the effect of global warming on soil organic carbon storage. Soil Biology and Biochemistry, 27, 753-760. – reference: Valentini R, Matteucci G, Dolman AJ et al. (2000) Respiration as the main determinant of carbon balance in European forests. Nature, 404, 861-865. – reference: Casals P, Romanya J, Cortina J (2000) CO2 efflux from a Mediterranean semi-arid forest soil. I. Seasonality and effects of stoniness. Biogeochemistry, 48, 261-281. – reference: Trumbore SE (1997) Potential response of soil organic carbon to global environmental change. Proceedings of the National Academy of Science, USA, 94, 8284-8291. – reference: Scott-Denton LE, Sparks KL, Monson RK (2003) Spatial and temporal controls of soil respiration rate in a high-elevation, subalpine forest. Soil Biology and Biochemistry, 35, 525-534. – reference: Dalenberg JW, Jager G (1989) Priming effect of some organic additions to 14C-labelled soil. Soil Biology and Biochemistry, 21, 443-448. – reference: Hedges LV, Gurevitch J, Curtis PS (1999) The meta-analysis of response ratios in experimental ecology. Ecology, 80, 1150-1156. – reference: Boone RD, Nadelhoffer KJ, Canary JD et al. (1998) Roots exert a strong influence on the temperature sensitivity of soil respiration. Nature, 396, 570-572. – reference: Högberg P, Nordgren A, Buchmann N et al. (2001) Large-scale forest girdling shows that current photosynthesis drives soil respiration. Nature, 411, 789-792. – reference: Caldwell MM, Dawson TE, Richards TH (1998) Hydraulic lift: consequences of water efflux from the roots of plants. Oecologia, 113, 151-161. – reference: Giardina CP, Ryan MG (2000) Evidence that decomposition rates of organic carbon in mineral soil do not vary with temperature. Nature, 404, 858-861. – reference: Mary B, Fresenau C, Morel JL et al. (1993) C and N cycling during decomposition of root mucilage, roots and glucose in soil. Soil Biology and Biochemistry, 25, 1005-1014. – reference: Savage KE, Davidson EA (2001) Interannual variation of soil respiration in two New England forests. Global Biogeochemical Cycles, 15, 337-350. – reference: Kuzyakov Y (2002) Factors affecting rhizosphere priming effects. Journal of Plant Nutrition and Soil Science, 165, 382-396. – reference: Lavigne MB, Boutin R, Foster RJ et al. (2003) Soil respiration responses to temperature are controlled more by roots than by decomposition in balsam fir ecosystems. Canadian Journal of Forest Research, 33, 1744-1753. – reference: Osenberg CW, Sarnelle O, Cooper SD (1997) Effect size in ecological experiments: the application of biological models in meta-analysis. American Naturalist, 150, 798-812. – reference: Hood E, McKnight DM, Williams MW (2003) Sources and chemical character of dissolved organic carbon (DOC) across a alpine/subalpine ecotone, Green Lakes Valley, Colorado Front Range, USA. Water Resources Research, 39, Art No. 1188. – reference: Hibbard K, Law B, Reichstein M et al. (2004) An analysis of soil respiration across Northern Hemisphere temperate ecosystems. Biogeochemistry, 73, 29-70. – reference: Shen J, Bartha R (1996) Priming effect of substrate addition in soil-based biodegradation tests. Applied Environmental Microbiology, 62, 1428-1430. – reference: Sutinen ML, Mäkitalo K, Sutinen R (1996) Freezing dehydration damages roots of containerized Scots pine (Pinus sylvestris) seedlings overwintering under subarctic conditions. Canadian Journal of Forestry Research, 25, 1602-1609. – reference: Xiao X, Melillo JM, Kicklighter DW (1998) Transient climate change and net ecosystem production of the terrestrial biosphere. Global Biogeochemical Cycles, 12, 345-360. – reference: Reichstein M, Rey A, Freibauer A et al. (2003) Modeling temporal and large-scale variability of soil respiration from soil water variability, temperature and vegetation productivity indices. Global Biogeochemical Cycles, 17, Art. No. 1104. – reference: Stoyan H, De-Polli H, Bohm S et al. (2000) Spatial heterogeneity of soil respiration and related properties at the plant scale. Plant and Soil, 222, 203-214. – reference: Monson RK, Turnipseed AA, Sparks JP et al. (2002) Carbon sequestion in a high-elevation, subalpine forest. Global Change Biology, 8, 459-478. – reference: Buchmann N (2000) Biotic and abiotic factors controlling soil respiration rates in Picea abies stands. Soil Biology and Biochemistry, 32, 1625-1635. – reference: Pendall E, Del Grosso S, King JY et al. (2003) Elevated atmospheric CO2 effects and soil water feedbacks on soil respiration components in a Colorado grassland. Global Biogeochemical Cycles, 17, 1046-1059. – reference: Xu M, Qi Y (2001) Spatial and seasonal variations of Q10 determined by soil respiration measurements at a Sierra Nevada forest. Global Biogeochemical Cycles, 15, 687-696. – reference: De Nobili M, Contin C, Mondini C et al. (2001) Soil microbial biomass is triggered into activity by trace amounts of substrate. Soil Biology and Biochemistry, 33, 1163-1170. – reference: Lavigne MB, Foster RJ, Goodine G (2004) Seasonal and annual changes in soil respiration in relation to soil temperature, water potential and trenching. Tree Physiology, 24, 415-424. – reference: Jenkinson DS, Adams DE, Wild A (1991) Model estimates of CO2 emissions from soil in response to global warming. Nature, 351, 304-306. – reference: Raich JW, Schlesinger WH (1992) The global carbon dioxide flux in soil respiration and its relationship to vegetation and climate. Tellus, Ser B, 44, 81-99. – reference: Lee MS, Nakane K, Nakatsubo T (2003) Seasonal changes in the contribution of root respiration to total soil respiration in a cool-temperate deciduous forest. Plant and Soil, 255, 311-318. – reference: Zogg GP, Zak DR, Burton AJ et al. (1996) Fine root respiration in northern hardwood forests in relation to temperature and nitrogen. Tree Physiology, 16, 719-725. – reference: Lipson DA, Schmidt SK, Monson RK (2000) Carbon availability and temperature control the post-snowmelt decline in alpine soil microbial biomass. Soil Biology and Biochemistry, 32, 441-448. – volume: 8 start-page: 279 year: 1994 end-page: 293 article-title: Climatic, edaphic and biotic controls over storage and turnover of carbon in soils publication-title: Global Biogeochemical Cycles – volume: 110 start-page: 177 year: 2002 end-page: 201 article-title: Surface energy balance above a high‐elevation, subalpine forest publication-title: Agricultural and Forest Meteorology – volume: 396 start-page: 570 year: 1998 end-page: 572 article-title: Roots exert a strong influence on the temperature sensitivity of soil respiration publication-title: Nature – volume: 48 start-page: 261 year: 2000 end-page: 281 article-title: CO efflux from a Mediterranean semi‐arid forest soil. I. Seasonality and effects of stoniness publication-title: Biogeochemistry – volume: 165 start-page: 382 year: 2002 end-page: 396 article-title: Factors affecting rhizosphere priming effects publication-title: Journal of Plant Nutrition and Soil Science – volume: 44 start-page: 81 year: 1992 end-page: 99 article-title: The global carbon dioxide flux in soil respiration and its relationship to vegetation and climate publication-title: Tellus, Ser B – volume: 26 start-page: 1287 year: 2003 end-page: 1296 article-title: Tree root and soil heterotrophic respiration as revealed by girdling of boreal Scots pine forest: extending observations beyond the first year publication-title: Plant, Cell and Environment – volume: 8 start-page: 459 year: 2002 end-page: 478 article-title: Carbon sequestion in a high‐elevation, subalpine forest publication-title: Global Change Biology – volume: 43 start-page: 307 year: 2002 end-page: 314 article-title: Changes in microbial community structure and function following snow melt in an alpine soil publication-title: Microbial Ecology – volume: 15 start-page: 687 year: 2001 end-page: 696 article-title: Spatial and seasonal variations of Q determined by soil respiration measurements at a Sierra Nevada forest publication-title: Global Biogeochemical Cycles – volume: 32 start-page: 1625 year: 2000 end-page: 1635 article-title: Biotic and abiotic factors controlling soil respiration rates in stands publication-title: Soil Biology and Biochemistry – volume: 35 start-page: 525 year: 2003 end-page: 534 article-title: Spatial and temporal controls of soil respiration rate in a high‐elevation, subalpine forest publication-title: Soil Biology and Biochemistry – volume: 33 start-page: 1744 year: 2003 end-page: 1753 article-title: Soil respiration responses to temperature are controlled more by roots than by decomposition in balsam fir ecosystems publication-title: Canadian Journal of Forest Research – volume: 9 start-page: 23 year: 1995 end-page: 36 article-title: Global patterns of carbon dioxide emissions from soils publication-title: Global Biogeochemical Cycles – volume: 18 year: 2004 article-title: Fast labile carbon turnover obscures sensitivity of heterotrophic respiration from soil to temperature publication-title: Global Biogeochemical Cycles – volume: 154 start-page: 791 year: 2002 end-page: 795 article-title: Extramatrical ectomycorrhizal mycelium contributes one‐third of microbial biomass and produces, together with associated roots, half the dissolved organic carbon in a forest soil publication-title: New Phytologist – volume: 404 start-page: 858 year: 2000 end-page: 861 article-title: Evidence that decomposition rates of organic carbon in mineral soil do not vary with temperature publication-title: Nature – volume: 10 start-page: 247 year: 1997 end-page: 253 article-title: Relationship between respiratoty depletion of sugars and loss of cold hardiness in coniferous seedlings over‐wintering at raised temperatures publication-title: Plant Cell and Environment – volume: 113 start-page: 151 year: 1998 end-page: 161 article-title: Hydraulic lift publication-title: Oecologia – volume: 12 start-page: 345 year: 1998 end-page: 360 article-title: Transient climate change and net ecosystem production of the terrestrial biosphere publication-title: Global Biogeochemical Cycles – volume: 5 start-page: 169 year: 1999 end-page: 182 article-title: Seasonal and annual respiration of a ponderosa pine ecosystem publication-title: Global Change Biology – volume: 404 start-page: 861 year: 2000 end-page: 865 article-title: Respiration as the main determinant of carbon balance in European forests publication-title: Nature – volume: 25 start-page: 1005 year: 1993 end-page: 1014 article-title: C and N cycling during decomposition of root mucilage, roots and glucose in soil publication-title: Soil Biology and Biochemistry – volume: 351 start-page: 304 year: 1991 end-page: 306 article-title: Model estimates of CO emissions from soil in response to global warming publication-title: Nature – volume: 32 start-page: 441 year: 2000 end-page: 448 article-title: Carbon availability and temperature control the post‐snowmelt decline in alpine soil microbial biomass publication-title: Soil Biology and Biochemistry – volume: 150 start-page: 798 year: 1997 end-page: 812 article-title: Effect size in ecological experiments publication-title: American Naturalist – volume: 94 start-page: 8284 year: 1997 end-page: 8291 article-title: Potential response of soil organic carbon to global environmental change publication-title: Proceedings of the National Academy of Science, USA – volume: 21 start-page: 443 year: 1989 end-page: 448 article-title: Priming effect of some organic additions to C‐labelled soil publication-title: Soil Biology and Biochemistry – volume: 17 year: 2003 article-title: Modeling temporal and large‐scale variability of soil respiration from soil water variability, temperature and vegetation productivity indices publication-title: Global Biogeochemical Cycles – volume: 15 start-page: 337 year: 2001 end-page: 350 article-title: Interannual variation of soil respiration in two New England forests publication-title: Global Biogeochemical Cycles – volume: 27 start-page: 753 year: 1995 end-page: 760 article-title: The temperature dependence of soil organic matter decomposition and the effect of global warming on soil organic carbon storage publication-title: Soil Biology and Biochemistry – volume: 162 start-page: 311 year: 2004 end-page: 322 article-title: Belowground process responses to elevated CO and temperature publication-title: New Phytologist – volume: 16 start-page: 719 year: 1996 end-page: 725 article-title: Fine root respiration in northern hardwood forests in relation to temperature and nitrogen publication-title: Tree Physiology – volume: 255 start-page: 311 year: 2003 end-page: 318 article-title: Seasonal changes in the contribution of root respiration to total soil respiration in a cool‐temperate deciduous forest publication-title: Plant and Soil – volume: 17 start-page: 1046 year: 2003 end-page: 1059 article-title: Elevated atmospheric CO effects and soil water feedbacks on soil respiration components in a Colorado grassland publication-title: Global Biogeochemical Cycles – volume: 80 start-page: 1150 year: 1999 end-page: 1156 article-title: The meta‐analysis of response ratios in experimental ecology publication-title: Ecology – volume: 222 start-page: 203 year: 2000 end-page: 214 article-title: Spatial heterogeneity of soil respiration and related properties at the plant scale publication-title: Plant and Soil – volume: 411 start-page: 789 year: 2001 end-page: 792 article-title: Large‐scale forest girdling shows that current photosynthesis drives soil respiration publication-title: Nature – volume: 33 start-page: 1163 year: 2001 end-page: 1170 article-title: Soil microbial biomass is triggered into activity by trace amounts of substrate publication-title: Soil Biology and Biochemistry – volume: 62 start-page: 1428 year: 1996 end-page: 1430 article-title: Priming effect of substrate addition in soil‐based biodegradation tests publication-title: Applied Environmental Microbiology – volume: 48 start-page: 115 year: 2000 end-page: 146 article-title: Separating root and soil microbial contributions to soil respiration publication-title: Biogeochemistry – volume: 28 start-page: 1131 year: 1996 end-page: 1138 article-title: Substrate induced respiration measured in situ in a C ‐plant ecosystem using additions of C ‐sucrose publication-title: Soil Biology and Biochemistry – volume: 127 start-page: 305 year: 2001 end-page: 308 article-title: Natural abundance of C in CO respired from forest soils reveals speed of link between tree photosynthesis and root respiration publication-title: Oecologia – volume: 17 year: 2003 article-title: Substrate regulation of soil respiration in a tallgrass prarie publication-title: Global Biogeochemical Cycles – volume: 24 start-page: 415 year: 2004 end-page: 424 article-title: Seasonal and annual changes in soil respiration in relation to soil temperature, water potential and trenching publication-title: Tree Physiology – volume: 139 start-page: 551 year: 2004 end-page: 559 article-title: Feedback interactions between needle litter decomposition and rhizospheric activity publication-title: Oecologia – volume: 39 year: 2003 article-title: Sources and chemical character of dissolved organic carbon (DOC) across a alpine/subalpine ecotone, Green Lakes Valley, Colorado Front Range, USA publication-title: Water Resources Research – volume: 25 start-page: 1602 year: 1996 end-page: 1609 article-title: Freezing dehydration damages roots of containerized Scots pine ( ) seedlings overwintering under subarctic conditions publication-title: Canadian Journal of Forestry Research – volume: 73 start-page: 29 year: 2004 end-page: 70 article-title: An analysis of soil respiration across Northern Hemisphere temperate ecosystems publication-title: Biogeochemistry – ident: e_1_2_6_17_1 doi: 10.1038/35081058 – ident: e_1_2_6_35_1 doi: 10.1029/94GB02723 – ident: e_1_2_6_27_1 doi: 10.1016/S0038-0717(99)00068-1 – ident: e_1_2_6_42_1 doi: 10.1007/s00442-004-1540-4 – ident: e_1_2_6_33_1 doi: 10.1029/2001GB001821 – ident: e_1_2_6_2_1 doi: 10.1046/j.1365-3040.2003.01053.x – ident: e_1_2_6_30_1 doi: 10.1046/j.1365-3040.1997.d01-56.x – ident: e_1_2_6_16_1 doi: 10.1046/j.1469-8137.2002.00417.x – ident: e_1_2_6_31_1 doi: 10.1086/286095 – ident: e_1_2_6_11_1 doi: 10.1029/2003GB002119 – ident: e_1_2_6_14_1 doi: 10.1007/s10533-004-2946-0 – ident: e_1_2_6_6_1 doi: 10.1023/A:1006289905991 – ident: e_1_2_6_24_1 doi: 10.1046/j.1365-2486.1999.00214.x – ident: e_1_2_6_43_1 doi: 10.1139/x26-180 – ident: e_1_2_6_20_1 doi: 10.1016/0038-0717(94)00242-S – ident: e_1_2_6_46_1 doi: 10.1038/35009084 – ident: e_1_2_6_4_1 doi: 10.1016/S0038-0717(00)00077-8 – volume: 17 year: 2003 ident: e_1_2_6_34_1 article-title: Modeling temporal and large‐scale variability of soil respiration from soil water variability, temperature and vegetation productivity indices publication-title: Global Biogeochemical Cycles doi: 10.1029/2003GB002035 – ident: e_1_2_6_38_1 doi: 10.1029/94GB00993 – ident: e_1_2_6_28_1 doi: 10.1016/0038-0717(93)90147-4 – ident: e_1_2_6_12_1 doi: 10.1023/A:1006244819642 – ident: e_1_2_6_22_1 doi: 10.1139/x03-090 – ident: e_1_2_6_29_1 doi: 10.1046/j.1365-2486.2002.00480.x – ident: e_1_2_6_10_1 doi: 10.1038/35009076 – ident: e_1_2_6_26_1 doi: 10.1007/s00248-001-1057-x – ident: e_1_2_6_48_1 doi: 10.1029/2000GB001365 – ident: e_1_2_6_45_1 doi: 10.1016/S0168-1923(01)00290-8 – ident: e_1_2_6_3_1 doi: 10.1038/25119 – ident: e_1_2_6_23_1 doi: 10.1093/treephys/24.4.415 – ident: e_1_2_6_8_1 doi: 10.1016/S0038-0717(01)00020-7 – volume: 17 year: 2003 ident: e_1_2_6_47_1 article-title: Substrate regulation of soil respiration in a tallgrass prarie publication-title: Global Biogeochemical Cycles – ident: e_1_2_6_13_1 doi: 10.1890/0012-9658(1999)080[1150:TMAORR]2.0.CO;2 – ident: e_1_2_6_39_1 doi: 10.1016/S0038-0717(03)00007-5 – ident: e_1_2_6_5_1 doi: 10.1007/s004420050363 – ident: e_1_2_6_9_1 doi: 10.1007/s004420100667 – ident: e_1_2_6_19_1 doi: 10.1038/351304a0 – ident: e_1_2_6_18_1 doi: 10.1029/2002WR001738 – ident: e_1_2_6_36_1 doi: 10.1034/j.1600-0889.1992.t01-1-00001.x – ident: e_1_2_6_32_1 doi: 10.1111/j.1469-8137.2004.01053.x – ident: e_1_2_6_15_1 doi: 10.1016/0038-0717(96)00124-1 – ident: e_1_2_6_44_1 doi: 10.1073/pnas.94.16.8284 – ident: e_1_2_6_49_1 doi: 10.1029/98GB01035 – ident: e_1_2_6_41_1 doi: 10.1023/A:1004757405147 – ident: e_1_2_6_50_1 doi: 10.1093/treephys/16.8.719 – ident: e_1_2_6_25_1 doi: 10.1023/A:1026192607512 – ident: e_1_2_6_37_1 doi: 10.1029/1999GB001248 – volume: 62 start-page: 1428 year: 1996 ident: e_1_2_6_40_1 article-title: Priming effect of substrate addition in soil‐based biodegradation tests publication-title: Applied Environmental Microbiology doi: 10.1128/aem.62.4.1428-1430.1996 – ident: e_1_2_6_21_1 doi: 10.1002/1522-2624(200208)165:4<382::AID-JPLN382>3.0.CO;2-# – ident: e_1_2_6_7_1 doi: 10.1016/0038-0717(89)90157-0
SSID	ssj0003206
Score	2.3419106
Snippet	The partitioning of soil respiration rates into the component processes of rhizospheric respiration (because of live roots and those microorganisms that...
SourceID	proquest crossref wiley istex fao
SourceType	Aggregation Database Enrichment Source Index Database Publisher
StartPage	205
SubjectTerms	Ameriflux biological activity in soil Biomass Carbon carbon cycle carbon dioxide Climate Colorado coniferous forests Dissolved organic carbon Drought Extreme drought forest girdling forest soils gas emissions girdling Growing season lodgepole pine Low temperature microbial biomass Microorganisms Organic matter photosynthates Pine needles Pine trees Pinus contorta Respiration rhizosphere root root exudates root respiration Roots Snowmelt soil CO2 efflux Soil dynamics soil microorganisms soil moisture Soil organic matter Soil permeability soil respiration soil temperature soil water Spring sucrose Summer translocation (plant physiology) Trees water stress Winter
Title	Differential controls by climate and substrate over the heterotrophic and rhizospheric components of soil respiration
URI	https://api.istex.fr/ark:/67375/WNG-72H9HHQ8-5/fulltext.pdf https://onlinelibrary.wiley.com/doi/abs/10.1111%2Fj.1365-2486.2005.01064.x https://www.proquest.com/docview/205130822 https://www.proquest.com/docview/19435668 https://www.proquest.com/docview/46841084
Volume	12
WOSCitedRecordID	wos000234974900006&url=https%3A%2F%2Fcvtisr.summon.serialssolutions.com%2F%23%21%2Fsearch%3Fho%3Df%26include.ft.matches%3Dt%26l%3Dnull%26q%3D
hasFullText	1
inHoldings	1
isFullTextHit
isPrint
journalDatabaseRights	– providerCode: PRVWIB databaseName: Wiley Online Library Full Collection 2020 customDbUrl: eissn: 1365-2486 dateEnd: 99991231 omitProxy: false ssIdentifier: ssj0003206 issn: 1354-1013 databaseCode: DRFUL dateStart: 19970101 isFulltext: true titleUrlDefault: https://onlinelibrary.wiley.com providerName: Wiley-Blackwell
link	http://cvtisr.summon.serialssolutions.com/2.0.0/link/0/eLvHCXMwrV1bb9MwFD6CDiReuBSmhTHwA9pbUJPYifMI3bo-jIpbYW-W7SRbRZVMyYq2f885jtetEkgT4qVK2-PcfPz5s_35HIC3EimIyWMRJokWIc9Go9AUZRWKUkaJ0NhhOcn_9-NsNpMnJ_knr3-ivTB9fIj1hBu1DIfX1MC16TYbuVNocZn6qREc3fB3yCe3YnRjMYCtgy-T-fEal5PYZdrEW-AIPlGyqev547k2Oqv7lW6QwtLbv9zgo7dZreuWJk_-5wM9hceenLL3vTc9g3tlPYSHfbrKqyFsH97sikMzDwvdEIKPSL2b1pmxfTZeLpAHu2_PYXXgU7AglCyZV8Z3zFwx68xKpuuCdYhfLk4uI0kpQ1bKzkio06D1-dnCOqOW9IEdxUHAH0gL39QkA2FNxbpmsWStlw2gq72A-eTw23ga-lwPoRXJiIdFbE0lKstlyU3JC4SFSnPketaUNGAWMo81rQFm6FhFFcVFjmzDWiMjdMO0TLZhUONVd4BZERe0I1ebKiO6YqJUmCJKTWUrZJMygOy6UpX1gdApH8dS3RoQYU0oqglK0ymUqwl1GUC0LnneBwO5Q5kd9BulTxGz1fxrTCvFdBf4GcC-c6b1uXT7k3R2mVA_Zkcqi6f5dPpZKhHA7rW3KQ8xHV5ERBRrKA7gzfpfxAZa8NF12aw6FeVIhtNU_t2Cp5JHI8kDSJ1r3vmx1NH4Ax29_NeCu_Con80iZdArGFy0q3IPHthfF4uufe3b7m847j-z
linkProvider	Wiley-Blackwell
linkToHtml	http://cvtisr.summon.serialssolutions.com/2.0.0/link/0/eLvHCXMwrV1bb9MwFD6CDQQvXMqmhQHzA9pbUJPYifMI3boiuorLCnuzYidhFVUyJSva_j3nOF5YJZAmxEuVtse5-fPxZ_vzOQCvJVIQnYbCj6JM-DwZDn2dF6UvChlEIsMOy0r-v06T2UyenqYfXTog2gvTxYfoJ9yoZVh_TQ2cJqTXW7mVaHEZu7kRHN7wN0goNzmiCuG-efB5PJ_2jjkKbapNvAeO3ieI1oU9fzzXWm91t8xq5LD0-i_XCOlNWmv7pfHj__pET-CRo6fsbYenp3CnqAZwv0tYeTWA7cPf--LQzDmGdgDeMZLvurFmbJ-NlgtkwvbbM1gduCQs6EyWzGnjW6avmLFmBcuqnLXowWykXEaiUoa8lJ2RVKdG6_OzhbFGDSkEW4qEgD-QGr6uSAjC6pK19WLJGiccQLBtwXx8eDKa-C7bg29ENOR-HhpditJwWXBd8ByrsMw4sj2jCxoyC5mGGa0CJgitvAzCPEW-YYyWAQIxLqJt2KjwqjvAjAhz2pOb6TIhwqKDWOg8iHVpSuST0oPkulaVcaHQKSPHUt0YEmFNKKoJStQplK0JdelB0Jc878KB3KLMDgJHZd_Ra6v5l5DWiuku8NODfYum_lxZ84OUdolQ32ZHKgkn6WTySSrhwe413JRzMi1eRAQUbSj0YK__F70DLflkVVGvWhWkSIfjWP7dgseSB0PJPYgtNm_9WOpo9I6Onv9rwT14MDk5nqrp-9mHXXjYzW2RTugFbFw0q-Il3DM_LxZt88o15F9iU0Oj
linkToPdf	http://cvtisr.summon.serialssolutions.com/2.0.0/link/0/eLvHCXMwrV1bb9MwFD6CDhAvXArTwoD5Ae0tqEnsxHmEdl0RpRqXwt6s2LFZRdVUyYq2f885blZWCaQJ8VKl7XFuPv782f58DsAriRRE57EIk6QQIc96vVCX1oXCyigRBXZYXvL_dZxNJvL0ND9p0wHRXph1fIjNhBu1DI_X1MDtsnTbrdxLtLhM27kRHN7w10godzjllOnAzuDTcDreAHMS-1SbeA8c0SdKtoU9fzzXVm912xUVclh6_RdbhPQ6rfX90vDhf32iR_CgpafszdqfHsMtu-jC3XXCyssu7B793heHZi0wNF0IPiD5rmpvxg5Zfz5DJuy_PYHVoE3CgmAyZ602vmH6khlvZlmxKFmDCOYj5TISlTLkpeyMpDoVWi_PZsYb1aQQbCgSAv5AavhqQUIQVjnWVLM5q1vhADrbU5gOj770R2Gb7SE0IunxsIyNdsIZLi3XlpcIDK7gyPaMtjRkFjKPC1oFzNC1ShfFZY58wxgtI3TE1Ca70FngVfeAGRGXtCe30C4jwqKjVOgySrUzDvmkDCC7qlVl2lDolJFjrq4NibAmFNUEJeoUyteEuggg2pRcrsOB3KDMHjqOKr4jaqvp55jWiuku8DOAQ-9Nm3MV9Q9S2mVCfZscqywe5aPRR6lEAPtX7qZakGnwIiKiaENxAAebfxEdaMmnWNhq1agoRzqcpvLvFjyVPOpJHkDqffPGj6WO-2_p6Nm_FjyAeyeDoRq_m7zfh_vrqS2SCT2Hznm9si_gjvl5Pmvql207_gWGX0Me
openUrl	ctx_ver=Z39.88-2004&ctx_enc=info%3Aofi%2Fenc%3AUTF-8&rfr_id=info%3Asid%2Fsummon.serialssolutions.com&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Ajournal&rft.genre=article&rft.atitle=Differential+controls+by+climate+and+substrate+over+the+heterotrophic+and+rhizospheric+components+of+soil+respiration&rft.jtitle=Global+change+biology&rft.au=Scott-Denton%2C+Laura+E&rft.au=Rosenstiel%2C+Todd+N&rft.au=Monson%2C+Russell+K&rft.date=2006-02-01&rft.issn=1354-1013&rft.volume=12&rft.issue=2+p.205-216&rft.spage=205&rft.epage=216&rft_id=info:doi/10.1111%2Fj.1365-2486.2005.01064.x&rft.externalDBID=NO_FULL_TEXT
thumbnail_l	http://covers-cdn.summon.serialssolutions.com/index.aspx?isbn=/lc.gif&issn=1354-1013&client=summon
thumbnail_m	http://covers-cdn.summon.serialssolutions.com/index.aspx?isbn=/mc.gif&issn=1354-1013&client=summon
thumbnail_s	http://covers-cdn.summon.serialssolutions.com/index.aspx?isbn=/sc.gif&issn=1354-1013&client=summon