Crop growth simulation models provide a means to quantify the effects of climate, soil and management on crop growth and biogeochemical processes in soil. The Denitrification and Decomposition (DNDC) model was evaluated for its ability to simulate methane (CH₄), nitrous oxide (N₂O) and carbon dioxide (CO₂) emissions from Indian rice fields with various management practices. The model was calibrated and validated for field experiments in New Delhi, India. The observed yield, N uptake and greenhouse gas (GHG) emissions were in good agreement with the values predicted by the model. The model was then applied for estimation of GHG emissions from rice fields in India using a newly compiled soil/climate/land use database. Continuous flooding of rice fields (42.25 million ha) resulted in annual net emissions of 1.07?1.10, 0.038?0.048 and 21.16?60.96 Tg of CH₄-C, N₂O-N and CO₂-C, respectively, with a cumulated global warming potential (GWP) of 130.93?272.83 Tg CO₂ equivalent. Intermittent flooding of rice fields reduced annual net emissions to 0.12?0.13 Tg CH₄-C and 16.66?48.80 Tg CO₂-C while N₂O emission increased to 0.056?0.060 Tg N₂O-N. The GWP, however, reduced to 91.73?211.80 Tg CO₂ equivalent. The study suggests that the model can be applied for studying the GHG related issues in rice cropping systems of India.