High nitrous oxide fluxes from rice indicate the need to manage water for both long- and short-term climate impacts.

Global rice cultivation is estimated to account for 2.5% of current anthropogenic warming because of emissions of methane (CH4), a short-lived greenhouse gas. This estimate assumes a widespread prevalence of continuous flooding of most rice fields and hence does not include emissions of nitrous oxide (N2O), a long-lived greenhouse gas. Based on the belief that minimizing CH4 from rice cultivation is always climate beneficial, current mitigation policies promote increased use of intermittent flooding. However, results from five intermittently flooded rice farms across three agroecological regions in India indicate that N2O emissions per hectare can be three times higher (33 kg-N2O⋅ha-1⋅season-1) than the maximum previously reported. Correlations between N2O emissions and management parameters suggest that N2O emissions from rice across the Indian subcontinent might be 30-45 times higher under intensified use of intermittent flooding than under continuous flooding. Our data further indicate that comanagement of water with inorganic nitrogen and/or organic matter inputs can decrease climate impacts caused by greenhouse gas emissions up to 90% and nitrogen management might not be central to N2O reduction. An understanding of climate benefits/drawbacks over time of different flooding regimes because of differences in N2O and CH4 emissions can help select the most climate-friendly water management regimes for a given area. Region-specific studies of rice farming practices that map flooding regimes and measure effects of multiple comanaged variables on N2O and CH4 emissions are necessary to determine and minimize the climate impacts of rice cultivation over both the short term and long term.

Role of an in-house designed crucible in the fabrication of isotopically enriched 28Si target for an in-beam γ-ray spectroscopy experiment.

In the present work, an in-house designed special crucible was developed to fabricate isotopically enriched 28Si targets for a γ-ray spectroscopy experiment. Initially, the crucible was tested with natural Si and then utilized to fabricate isotopically enriched 28Si targets of thickness ∼500 µg/cm2 (∼2.15 µm). The fabricated targets were uniform in thickness and had very little contamination. In addition, one of the fabricated targets was successfully utilized in an in-beam γ-ray spectroscopy experiment. The technique employed in the present work not only facilitates the fabrication of stable and pure targets but also minimizes the wastage of the source material. As a result, these efforts pave the way for future fabrication of low-abundance isotopically enriched nuclear physics targets.