Ammonia

About: Ammonia is a research topic. Over the lifetime, 16217 publications have been published within this topic receiving 271940 citations. The topic is also known as: NH3 & azane.

Volatilização de amônia do solo após a aplicação de ureia convencional ou com inibidor de urease

Abstract: Ammonia volatilization is an important process of N loss which decreases the use efficiency of N by plants when urea is applied on the soil surface. To overcome this problem, some chemical compounds were mixed with urea to inhibit the urease action. The purpose of this study was to compare applications of an alternative fertilizer with urease inhibitor to reduce ammonia volatilization with conventional urea, under certain environmental and soil conditions. Four experiments were carried out in 2007 and 2008, under laboratory conditions, with samples of a Humic Haplumbrept. The treatments varied according to each experiment in terms of soil conditions, such as pH (4.0, 5.5, 6.3 and 6.8), soil water content (5, 10 or 20 % moisture), temperature (18 or 35 oC), aside from the fertilizer physical state (solid or liquid) and application method (over the surface or soil-incorporated). The experimental units consisted of plastic trays into which 12 kg of soil (dry basis) were filled in a 15 cm layer. Ammonia gas traps were installed across the soil surface. Frequent measurements were performed during the first 28 days of soil-fertilizer incubation. The peak of ammonia volatilization from the soil occurred in the first week after the application of traditional urea, and two or three days later for urea with urease inhibitor. Ammonia loss was not always higher from conventional than from treated urea, nor from solid than from liquid fertilizers. Ammonia volatilization increased with increases in soil pH, temperature and N rate and was lower at the lowest (5 %) and highest (20 %) soil moisture content. For surface-applied fertilizers, the maximum daily N loss rate was 14 kg ha-1 and the total cumulative loss ranged from 2 to 50 % of the applied N, depending mainly on the physical state of the fertilizer, temperature and on soil moisture. Soil incorporation of urea fertilizers was the best option to minimize ammonia volatilization in all treatments.

Oleaginous yeast Cryptococcus curvatus for biofuel production: Ammonia's effect

Abstract: Culturing oleaginous yeast with organic residues can provide cheap feedstock for biodiesel production, but the high content of nitrogen in some feedstocks (such as food residues) can lead to inhibition to cell growth and lipid synthesis, and this may be caused by ammonia. Thus, the inhibitory effect of ammonia on the growth of yeast Cryptococcus curvatus and its possible mechanism were evaluated in this study. The biomass production, lipid contents, affected metabolic pathways, and activities of the related pathway enzymes were investigated. The results showed that the yeast biomass production on acetate decreased from 5.9 kg m −3 to 2.0 kg m −3 when the initial ammonia concentration (in nitrogen equivalent terms) increased from 131 g m −3 to 3140 g m −3 . Ammonia significantly inhibited the yeast growth with volatile fatty acids (VFA) as carbon sources, but not in the culture with pyruvate generating substances (PGS) as carbon sources. However, the fatty acid synthesis was suppressed by ammonia in cultures with either VFA or PGS. The study on mechanism of ammonia inhibition suggested it might include an inhibition on the acyl-CoA synthetase activity, since a 61% decrease in the enzyme activity was found when 3140 g m −3 of ammonia (in nitrogen equivalent terms) was added. This study firstly reported the effect of ammonia with high concentrations to oleaginous yeast growth and lipid accumulation, and provided preliminary evidences on its possible mechanism of acyl-CoA synthetase inhibition.

Fixation of Ammonia by Organic Soils

Abstract: Ammonia fixation in organic soils of varying carbon content was found to be linearly correlated with percent carbon. In the presence of oxygen 1 molecule of ammonia was fixed per 29 atoms of carbon, and 1 for every 45 atoms of carbon in the absence of oxygen. Treatment of these organic soils with ammonia usually resulted in decreased capacity to retain barium and cupric ions, but the amount of ammonia fixed bore no quantitative relation to the decrease in cation retention. Blocking hydroxyl groups in soil organic matter by treating with dimethyl sulfate decreased the capacity of the organic matter to fix ammonia, indicating that these groups are involved in the fixation reaction. Aldehyde groupings are apparently not involved. Formation of amides through the action of anhydrous ammonia on carboxylic esters may play a minor role in ammonia fixation. A tracer experiment showed that fixed ammonia is slowly made available to plants.