By using packed soil-core incubation experiments,we have studied stimulating effects of addition of external carbon(C)(glucose,6.4 g Cm~(-2))on heterotrophic respiration and microbial biomass C of a mature broadleaf and Korean pine mixed forest(BKPF)and an adjacent white birch forest(WBF)soil under different wetting intensities(55%and 80%WFPS,water-filled pore space)and nitrogen(N)supply(NH_4C1 and KNO_3,4.5 g Nm~(-2))conditions.The results showed that for the control,the cumulative carbon dioxide(CO_2)flux from WBF soil during the 15-day incubation ranged from 5.44 to 5.82 g CO_2-Cm~(-2),which was significantly larger than that from BKPF soil(2.86 to 3.36 g CO_2-Cm~(-2)).With increasing wetting intensity,the cumulative CO_2 flux from the control was decreased for the WBF soil,whereas an increase in the CO_2 flux was observed in the BKPF soil(P<0.05).The addition of NH_4C1 or KNO_3 alone significantly reduced the cumulative CO_2 fluxes by 9.2%-21.6%from the two soils,especially from WBF soil at low wetting intensity.The addition of glucose alone significantly increased soil heterotrophic respiration,microbial biomass C(MBC),and microbial metabolic quotient.The glucose-induced cumulative CO_2 fluxes and soil MBC during the incubation ranged from 8.7 to 11.7 g CO_2-Cm~(-2)and from 7.4 to 23.9 g Cm~(-2),which are larger than the dose of added C.Hence,the addition of external carbon can increase the decomposition of soil native organic C.The glucose-induced average and maximum rates of CO_2 fluxes during the incubation were significantly influenced by wetting intensity(WI)and vegetation type(VT),and by WI×VT,NH_4Cl×VT and WI×VT×NH_4Cl(P<0.05).The addition of NH_4C1,instead of KNO_3 significantly decreased the glucose-induced MBC of WBF soil(P<0.05),whereas adding NH_4C1 and KNO_3 both significantly increased the glucose-induced MBC of BKPF soil at high moisture(P<0.05).According to the differences in soil labile C pools,MBC and CO_2 fluxes in the presence and absence of glucose,it can be concluded that the stimulating effects of glucose on soil heterotrophic respiration and MBC under temperate forests were dependent on vegetation type,soil moisture,and amount and type of the N added. By using packed soil-core incubation experiments, we have studied stimulating effects of addition of external carbon (C) (glucose, 6.4 g Cm -2) on heterotrophic respiration and microbial biomass C of a mature broadleaf and Korean pine mixed forest (BKPF) and an adjacent white birch forest (WBF) soil under different wetting intensities (55% and 80% WFPS, water- filled pore space) and nitrogen (N) supply (NH4C1 and KNO3, 4.5 g Nm ~ ). These results showed that for the control, the cumulative carbon dioxide (CO 2) flux from WBF soil during the 15-day incubation ranged from 5.44 to 5.82 g CO 2 -Cm -2, which was significantly larger than that from With increasing wetting intensity, the cumulative CO_2 flux from the control was decreased for the WBF soil, an increased in the CO_2 flux was observed in the BKPF soil (2.86 to 3.36 g CO_2-Cm -2) P <0.05). The addition of NH_4C1 or KNO_3 significantly significantly reduced the cumulative CO_2 fluxes by 9.2% -21.6% from the two soils, especially from WB F soil at low wetting intensity. The addition of glucose alone significantly increased soil heterotrophic respiration, microbial biomass C (MBC), and microbial metabolic quotient. The glucose-induced cumulative CO 2 fluxes and soil MBC during the incubation ranged from 8.7 to 11.7 g CO 2 -Cm ~ (-2) and from 7.4 to 23.9 g Cm ~ (-2), which are larger than the dose of added C.ence, the addition of external carbon can increase the decomposition of soil native organic C. The glucose- induced average and maximum rates of CO 2 fluxes during the incubation were significantly influenced by wetting intensity (WI) and vegetation type (VT), and by WI × VT, NH 4 Cl × VT and WI × VT × NH 4 Cl (P <0.05) of NH_4C1, instead of KNO_3 significantly decreased the glucose-induced MBC of WBF soil (P <0.05) .According to the addition of NH_4C1 and KNO_3 both significantly increased the glucose-induced MBC of BKPF soil at high moisture (P <0.05) differences in soil labile C pools, MBC and CO_2 fluxes in the presence and absenc e ofglucose, it can be concluded that the stimulating effects of glucose on soil heterotrophic respiration and MBC under temperate forests were dependent on vegetation type, soil moisture, and amount and type of the N added.