Applying biochar into soils has potential to increase carbon sequestration and reduce soil greenhouse gas (GHG) emission. This study was dedicated to investigate the mechanism through which biochar affects soil microorganism and GHG emissions. Biochar used in the experiment was generated from pyrolysis of Cryptomeria japonica (Linn. f.) D. Don. at 700˚C. The field experiment was located in the organic-farming tea garden (OTG) and conventional-farming tea garden (CTG) at Tea Research and Extension Station. Soils in the two gardens were obtained to conduct the soil layering box (SLB) experiment. In the field experiment, biochar was applied in the rates of 0% (control), 1% and 2% (w/w) in the OTG and CTG. Gas and soil were sampled within two months since each fertilizer application, and were subjected to the analysis. An SLB consisted of a biochar layer between soil layers. The soil and biochar were analyzed after incubation and sampling by layer. Results in the SLB experiment showed that there was no difference in microbial population among the (+BC) and (-BC) treatments of the O-SLBs, indicating that biochar had a limited impact on the distribution of microbial population. In the C-SLB, the (+BC) layers had larger microbial population compared with (+BC) upper layers, (-BC) smaller layers and the (-BC) layers in (-BC)-SLBs did, and such impact endured for at least 12 weeks. Pearson’s coefficient correlation revealed that in the O-SLBs, distribution of microbial numbers was related to non-biochar organic matter, while in the C-SLBs it was related to water and nitrate contents. Microbial activity in O-SLBs was smaller in biochar while was not different between biochar and soil in the C-SLBs. Principle component analysis for community-level physiological profiles (CLPP) revealed that in O-SLBs, the shift of microbial community might be present, and the smaller microbial activity in biochar might be due to great biochar nutrient-sorbing force which reduced nutrient availability for microbial utilization. In C-SLBs, microbial activity, CLPP and GHG fluxes were not different between (+BC)- and (-BC)-SLBs. In the field experiment, soil N2O effluxes, microbial population and activity in biochar-amended plots would decrease after the first two fertilizer applications in the OTG. However, after the third fertilizer application, no difference in N2O fluxes and microbial growth was present possibly due to biochar surface oxidation. In the CTG, although biochar increased microbial growth in the soil, it did not affect N2O emissions significantly. Biochar-induced CO2 emissions were likely present in the two gardens, but it did not lead to the change of cumulative CO2 fluxes. Methane fluxes were not affected by biochar in the two gardens.