The effect of soil warming on bulk soil vs. rhizosphere respiration

Iain P. Hartley; Andreas Heinemeyer; Sam P. Evans; Phil Ineson

doi:10.1111/j.1365-2486.2007.01454.x

The effect of soil warming on bulk soil vs. rhizosphere respiration

Iain P. Hartley, Andreas Heinemeyer, Sam P. Evans, Phil Ineson

Research output: Contribution to journal › Article › peer-review

Abstract

There has been considerable debate on whether root/rhizosphere respiration or bulk soil respiration is more sensitive to long-term temperature changes. We investigated the response of belowground respiration to soil warming by 3 degrees C above ambient in bare soil plots and plots planted with wheat and maize. Initially, belowground respiration responded more to the soil warming in bare soil plots than in planted plots. However, as the growing season progressed, a greater soil-warming response developed in the planted plots as the contribution of root/rhizosphere respiration to belowground respiration declined. A negative correlation was observed between the contribution of root/rhizosphere respiration to total belowground respiration and the magnitude of the soil-warming response indicating that bulk soil respiration is more temperature sensitive than root/rhizosphere respiration. The dependence of root/rhizosphere respiration on substrate provision from photosynthesis is the most probable explanation for the observed lower temperature sensitivity of root/rhizosphere respiration. At harvest in late September, final crop biomass did not differ between the two soil temperature treatments in either the maize or wheat plots. Postharvest, flux measurements during the winter months indicated that the response of belowground respiration to the soil-warming treatment increased in magnitude (response equated to a Q(10) value of 5.7 compared with similar to 2.3 during the growing season). However, it appeared that this response was partly caused by a strong indirect effect of soil warming. When measurements were made at a common temperature, belowground respiration remained higher in the warmed subplots suggesting soil warming had maintained a more active microbial community through the winter months. It is proposed that any changes in winter temperatures, resulting from global warming, could alter the sink strength of terrestrial ecosystems considerably.

Original language	English
Pages (from-to)	2654-2667
Number of pages	14
Journal	Global Change Biology
Volume	13
Issue number	12
DOIs	https://doi.org/10.1111/j.1365-2486.2007.01454.x
Publication status	Published - Dec 2007

Keywords

bare soil
CO2
maize
plant growth
Q(10)
root respiration
soil moisture
temperature
wheat
winter
ROOT RESPIRATION
CO2 EFFLUX
TEMPERATURE SENSITIVITY
PHOTOSYNTHESIS CONTROLS
GRASSLAND COMMUNITY
NIGHT TEMPERATURE
TALLGRASS PRAIRIE
RADIATION FLUX
CARBON-CYCLE
FOREST

Access to Document

10.1111/j.1365-2486.2007.01454.x

Cite this

@article{20e6d141cdcf46ce84bb83dc2b2efdef,

title = "The effect of soil warming on bulk soil vs. rhizosphere respiration",

abstract = "There has been considerable debate on whether root/rhizosphere respiration or bulk soil respiration is more sensitive to long-term temperature changes. We investigated the response of belowground respiration to soil warming by 3 degrees C above ambient in bare soil plots and plots planted with wheat and maize. Initially, belowground respiration responded more to the soil warming in bare soil plots than in planted plots. However, as the growing season progressed, a greater soil-warming response developed in the planted plots as the contribution of root/rhizosphere respiration to belowground respiration declined. A negative correlation was observed between the contribution of root/rhizosphere respiration to total belowground respiration and the magnitude of the soil-warming response indicating that bulk soil respiration is more temperature sensitive than root/rhizosphere respiration. The dependence of root/rhizosphere respiration on substrate provision from photosynthesis is the most probable explanation for the observed lower temperature sensitivity of root/rhizosphere respiration. At harvest in late September, final crop biomass did not differ between the two soil temperature treatments in either the maize or wheat plots. Postharvest, flux measurements during the winter months indicated that the response of belowground respiration to the soil-warming treatment increased in magnitude (response equated to a Q(10) value of 5.7 compared with similar to 2.3 during the growing season). However, it appeared that this response was partly caused by a strong indirect effect of soil warming. When measurements were made at a common temperature, belowground respiration remained higher in the warmed subplots suggesting soil warming had maintained a more active microbial community through the winter months. It is proposed that any changes in winter temperatures, resulting from global warming, could alter the sink strength of terrestrial ecosystems considerably.",

keywords = "bare soil, CO2, maize, plant growth, Q(10), root respiration, soil moisture, temperature, wheat, winter, ROOT RESPIRATION, CO2 EFFLUX, TEMPERATURE SENSITIVITY, PHOTOSYNTHESIS CONTROLS, GRASSLAND COMMUNITY, NIGHT TEMPERATURE, TALLGRASS PRAIRIE, RADIATION FLUX, CARBON-CYCLE, FOREST",

author = "Hartley, {Iain P.} and Andreas Heinemeyer and Evans, {Sam P.} and Phil Ineson",

year = "2007",

month = dec,

doi = "10.1111/j.1365-2486.2007.01454.x",

language = "English",

volume = "13",

pages = "2654--2667",

journal = "Global Change Biology",

issn = "1354-1013",

publisher = "Wiley-Blackwell",

number = "12",

}

TY - JOUR

T1 - The effect of soil warming on bulk soil vs. rhizosphere respiration

AU - Hartley, Iain P.

AU - Heinemeyer, Andreas

AU - Evans, Sam P.

AU - Ineson, Phil

PY - 2007/12

Y1 - 2007/12

N2 - There has been considerable debate on whether root/rhizosphere respiration or bulk soil respiration is more sensitive to long-term temperature changes. We investigated the response of belowground respiration to soil warming by 3 degrees C above ambient in bare soil plots and plots planted with wheat and maize. Initially, belowground respiration responded more to the soil warming in bare soil plots than in planted plots. However, as the growing season progressed, a greater soil-warming response developed in the planted plots as the contribution of root/rhizosphere respiration to belowground respiration declined. A negative correlation was observed between the contribution of root/rhizosphere respiration to total belowground respiration and the magnitude of the soil-warming response indicating that bulk soil respiration is more temperature sensitive than root/rhizosphere respiration. The dependence of root/rhizosphere respiration on substrate provision from photosynthesis is the most probable explanation for the observed lower temperature sensitivity of root/rhizosphere respiration. At harvest in late September, final crop biomass did not differ between the two soil temperature treatments in either the maize or wheat plots. Postharvest, flux measurements during the winter months indicated that the response of belowground respiration to the soil-warming treatment increased in magnitude (response equated to a Q(10) value of 5.7 compared with similar to 2.3 during the growing season). However, it appeared that this response was partly caused by a strong indirect effect of soil warming. When measurements were made at a common temperature, belowground respiration remained higher in the warmed subplots suggesting soil warming had maintained a more active microbial community through the winter months. It is proposed that any changes in winter temperatures, resulting from global warming, could alter the sink strength of terrestrial ecosystems considerably.

AB - There has been considerable debate on whether root/rhizosphere respiration or bulk soil respiration is more sensitive to long-term temperature changes. We investigated the response of belowground respiration to soil warming by 3 degrees C above ambient in bare soil plots and plots planted with wheat and maize. Initially, belowground respiration responded more to the soil warming in bare soil plots than in planted plots. However, as the growing season progressed, a greater soil-warming response developed in the planted plots as the contribution of root/rhizosphere respiration to belowground respiration declined. A negative correlation was observed between the contribution of root/rhizosphere respiration to total belowground respiration and the magnitude of the soil-warming response indicating that bulk soil respiration is more temperature sensitive than root/rhizosphere respiration. The dependence of root/rhizosphere respiration on substrate provision from photosynthesis is the most probable explanation for the observed lower temperature sensitivity of root/rhizosphere respiration. At harvest in late September, final crop biomass did not differ between the two soil temperature treatments in either the maize or wheat plots. Postharvest, flux measurements during the winter months indicated that the response of belowground respiration to the soil-warming treatment increased in magnitude (response equated to a Q(10) value of 5.7 compared with similar to 2.3 during the growing season). However, it appeared that this response was partly caused by a strong indirect effect of soil warming. When measurements were made at a common temperature, belowground respiration remained higher in the warmed subplots suggesting soil warming had maintained a more active microbial community through the winter months. It is proposed that any changes in winter temperatures, resulting from global warming, could alter the sink strength of terrestrial ecosystems considerably.

KW - bare soil

KW - CO2

KW - maize

KW - plant growth

KW - Q(10)

KW - root respiration

KW - soil moisture

KW - temperature

KW - wheat

KW - winter

KW - ROOT RESPIRATION

KW - CO2 EFFLUX

KW - TEMPERATURE SENSITIVITY

KW - PHOTOSYNTHESIS CONTROLS

KW - GRASSLAND COMMUNITY

KW - NIGHT TEMPERATURE

KW - TALLGRASS PRAIRIE

KW - RADIATION FLUX

KW - CARBON-CYCLE

KW - FOREST

U2 - 10.1111/j.1365-2486.2007.01454.x

DO - 10.1111/j.1365-2486.2007.01454.x

M3 - Article

SN - 1354-1013

VL - 13

SP - 2654

EP - 2667

JO - Global Change Biology

JF - Global Change Biology

IS - 12

ER -