TY - JOUR
T1 - Sensitivity of soil respiration to soil temperature decreased under deep biochar amended soils in temperate croplands
AU - He, Xinhua
AU - Du, Z.
AU - Wang, Y.
AU - Lu, N.
AU - Zhang, Q.
PY - 2016/12/1
Y1 - 2016/12/1
N2 - © 2016 Elsevier B.V.Long-term effects of biochar application on soil carbon mineralization are important to evaluate the potential of biochar in carbon sequestration. Over a one-year period of time, we monitored soil respiration from a wheat-maize rotation cropping system after five years (once a year) of consecutive biochar application. In doing so four treatments with three replications each in a random design were examined: (1) a control plot without biochar and straw addition (CT), (2) 4.5 Mg biochar ha-1 year-1 (B4.5), (3) 9.0 Mg biochar ha-1 year-1 (B9.0) and (4) straw return (SR, ~15 Mg wheat + maize aboveground biomass ha-1 year-1). An equivalent amount of inorganic fertilizers with biochar was broadcasted on the soil surface and then plowed into ~16 cm soil depth prior to seeding. Both temporal dynamics and cumulative amounts of soil respiration were not significantly changed under the two biochar applications than under CT, but significantly increased under straw return than under CT and two biochar treatments. The annual respiration was 29.42, 29.96, 30.08, and 39.00 Mg CO2 ha-1 year-1 in CT, B4.5, B9.0 and SR treatments, respectively. Meanwhile, soil respiration positively correlated with soil temperature but negatively with soil moisture. Sensitivity of soil respiration to temperature (Q10) was significantly decreased due to biochar addition. These results indicated the potential of applying biochar to enhance soil carbon sequestration.
AB - © 2016 Elsevier B.V.Long-term effects of biochar application on soil carbon mineralization are important to evaluate the potential of biochar in carbon sequestration. Over a one-year period of time, we monitored soil respiration from a wheat-maize rotation cropping system after five years (once a year) of consecutive biochar application. In doing so four treatments with three replications each in a random design were examined: (1) a control plot without biochar and straw addition (CT), (2) 4.5 Mg biochar ha-1 year-1 (B4.5), (3) 9.0 Mg biochar ha-1 year-1 (B9.0) and (4) straw return (SR, ~15 Mg wheat + maize aboveground biomass ha-1 year-1). An equivalent amount of inorganic fertilizers with biochar was broadcasted on the soil surface and then plowed into ~16 cm soil depth prior to seeding. Both temporal dynamics and cumulative amounts of soil respiration were not significantly changed under the two biochar applications than under CT, but significantly increased under straw return than under CT and two biochar treatments. The annual respiration was 29.42, 29.96, 30.08, and 39.00 Mg CO2 ha-1 year-1 in CT, B4.5, B9.0 and SR treatments, respectively. Meanwhile, soil respiration positively correlated with soil temperature but negatively with soil moisture. Sensitivity of soil respiration to temperature (Q10) was significantly decreased due to biochar addition. These results indicated the potential of applying biochar to enhance soil carbon sequestration.
U2 - 10.1016/j.apsoil.2016.08.018
DO - 10.1016/j.apsoil.2016.08.018
M3 - Article
SN - 0929-1393
VL - 108
SP - 204
EP - 210
JO - Applied Soil Ecology
JF - Applied Soil Ecology
ER -