Long-term fertilisation strategies and form affect nutrient budgets and soil test values,soil carbon retention and crop yield resilience

Plant and Soil - The aim of this study was to evaluate the effects of long-term mineral and organic fertilisation on crop performance and soil fertility. The Long-Term Nutrient Depletion Trial...     

Soil greenhouse gas emissions from inorganic fertilizers and recycled oil palm waste products from Indonesian oil palm plantations

A continuous rise in the global demand for palm oil has resulted in the large‐scale expansion of oil palm plantations and generated environmental controversy. Efforts to increase the sustainability of oil palm cultivation include the recycling of oil mill and pruning residues in the field, but this may increase soil methane (CH₄) emissions. This study reports the results of yearlong field‐based measurements of soil nitrous oxide (N₂O) and CH₄ emissions from commercial plantations in North Sumatra, Indonesia. One experiment investigated the effects of soil‐water saturation on N₂O and CH₄ emissions from inorganic fertilizers and organic amendments by simulating 25 mm rainfall per day for 21 days. Three additional experiments focused on emissions from (a) inorganic fertilizer (urea), (b) combination of enriched mulch with urea and (c) organic amendments (empty fruit bunches, enriched mulch and pruned oil palm fronds) applied in different doses and spatial layouts (placed in inter‐row zones, piles, patches or bands) for a full year. The higher dose of urea led to a significantly higher N₂O emissions with the emission factors ranging from 2.4% to 2.7% in the long‐term experiment, which is considerably higher than the IPCC standard of 1%. Organic amendments were a significant source of both N₂O and CH₄ emissions, but N₂O emissions from organic amendments were 66%–86% lower than those from inorganic fertilizers. Organic amendments applied in piles emitted 63% and 71% more N₂O and CH₄, respectively, than when spread out. With twice the dose of organic amendments, cumulative emissions were up to three times greater. The (simulated) rainwater experiment showed that the increase in precipitation led to a significant increase in N₂O emissions significantly, suggesting that the time of fertilization is a critical management option for reducing emissions. The results from this study could therefore help guide residue and nutrient management practices to reduce emissions while ensuring better nutrient recycling for sustainable oil palm production systems.     

The effect of light on growth and sporulation of certain fungi

Summary The response of the fungi investigated to duration of exposure to light varies with the variation in the light intensity employed. Using relatively low intensity light (160 and/or 300 foot candles/inch²), the growth ofMyrothecium verrucaria &Pestalotia gracilis was not affected by the increase in the time of light exposure, while that ofPleurotus ostreatus was checked. Fruiting under the same conditions was hastened on exposure to light. Under higher light intensity (950 foot candles/inch²), growth ofMyrothecium was not affected, while that ofPestalotia andPleurotus decreased as the daily period of exposure to light increased. Pleurotus cultures exposed continuously to light showed practically no growth, and combined addition of malt and yeast extracts had a noticeable growth promoting effect on cultures exposed continuously to light, but not significantly on those kept in the dark. This was explained by assuming the presence in malt and yeast extracts of light sensitive growth promoting substances. The effect of light on growth ofPleurotus was found to be concerned with both cell mechanism and medium: light probably inhibits inside the cell the synthesis of one or more substances essential for growth and at the same time it favors the breakdown in the medium of one or more substances required for growth.