Abstract

Globally, vegetable fields are the primary source of greenhouse gas emissions. A closed-chamber method together with gas chromatography was used to measure the fluxes of nitrous oxide (N2O) emissions in typical vegetable fields planted with four vegetables sequentially over time in the same field: endive, lettuce, cabbage and sweet corn. Results showed that N2O fluxes occurred in pulses with the N2O emission peak varying greatly among the crops. In addition, N2O emissions were linearly associated with the nitrogen (N) application rate (r = 0.8878, n = 16). Excessive fertilizer N application resulted in N loss through nitrous oxide gas emitted from the vegetable fields. Compared with a conventional fertilization (N2) treatment, the cumulative N2O emissions decreased significantly in the growing seasons of four plant species from an nitrogen synergist (a nitrification inhibitor, dicyandiamide and biochar treatments by 34.6% and 40.8%, respectively. However, the effects of biochar on reducing N2O emissions became more obvious than that of dicyandiamide over time. The yield-scaled N2O emissions in consecutive growing seasons for four species increased with an increase in the N fertilizer application rate, and with continuous application of N fertilizer. This was especially true for the high N fertilizer treatment that resulted in a risk of yield-scaled N2O emissions. Generally, the additions of dicyandiamide and biochar significantly decreased yield-scaled N2O-N emissions by an average of 45.9% and 45.7%, respectively, compared with N2 treatment from the consecutive four vegetable seasons. The results demonstrated that the addition of dicyandiamide or biochar in combination with application of a rational amount of N could provide the best strategy for the reduction of greenhouse gas emissions in vegetable field in south China.

Highlights

  • As an important greenhouse gas, nitrous oxide (N2O) plays an important role in global warming, it contributes greatly to ozone depletion

  • The peak value of N2O emissions increased with an increase in the N application rate

  • N2O emissions were linearly associated with the N application rate in vegetable fields

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Summary

Introduction

As an important greenhouse gas, nitrous oxide (N2O) plays an important role in global warming, it contributes greatly to ozone depletion. Because the warming potential of N2O is 298 times that of CO2, N2O emissions have received more attention. Increase levels of atmospheric N2O contribute about 6% of the overall global warming effect, with almost 80% of N2O is emitted from agricultural lands; this N2O originates from N fertilizers, soil disturbance and animal waste [3]. Agricultural N2O emissions are projected to increase by 35%60% by 2030; this increase is projected to be caused by increases in application nitrogen (N) fertilizer and in animal manure production [4]. Effective mitigation measures used to mitigate N2O emission from soil without sacrificing crop yield are urgently needed

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