氨化细菌

Seaweed extract-EClean was applied to treatment for eutrophication water. Quantative detection of nitrogen cycle bacteria showed that seaweed extract could improve the growth of ammonifying bacteria, nitrosobacteria and nitrobacteria in the treated water. There was also an increasing trend in the number of denitrifying bacteria in aerated treatment water, which showed that the seaweed extract could accelerate nitrogen cycle and the release of nitrogen from water.

利用国外引进的海藻提取物EClean制剂对富营养化水体进行处理试验，经过定量测定处理和对照水体中氮循环细菌数量的变化，得出EClean制剂能够促进水体的氨化细菌、亚硝化细菌、硝化细菌的生长，并维持了曝气条件下一定数量的反硝化细菌，通过此处理使得在同一反应器中、同一条件下完成硝化作用和反硝化作用成为可能，加速了水体的氮素循环，使水体总氮下降明显。

The number of bacteria, fungi, ammonifier and nitrobacteria were positively correlated with the biomass of growing roots and absorbing roots, while the number of nitrogen-fixing bacteria was negatively correlated with absorbing root biomass.

细菌、真菌、氨化细菌和硝化细菌数量与生长根和吸收根生物量之间显著正相关；固氮菌则仅与吸收根生物量显著负相关；而纤维素分解菌与根系生物量的相关关系不显著。

The results showed that PSB and organic fertilizer could promote the growth of actinomyces, heterotroph bacteria, azotobbacter, ammonifying bacteria and nitrobacteria significantly, and restrain the growth of denitrifying bacteria in the soils.

结果表明，光合细菌和有机肥显著促进土壤中放线菌、异养细菌、固氮菌、氨化细菌和硝化细菌的生长，而抑制反硝化细菌数量。

There was significant positive correlation between the amount of rhizosphere bacteria, fungis, aminate bacteria and dry weight of absorbing root. There was significant negative correlation between azotobacters and dry weight of absorbing root.

根际细菌、真菌、氨化细菌和硝化细菌数量与生长根和吸收根生物量之间显著正相关，固氮菌则仅与吸收根生物量显著负相关，细菌和纤维素分解菌数量与根系呼吸显著正相关。

This experiment is studying the quantities of Change development about the Microorganism Vicinity Manpower wet land with MPN,Last we work out the the quantities of Nitrification bacterium、Oppose the nitrification bacterium and Aminate a bacterium in water Unit volume with Biostatistics.we analysis gets conclusion that the quantities of Three kinds microorganisms is the most Vicinity Manpower wet land according to the last data.

本试验采用稀释培养计数法对湿地附近水中微生物的数量变化动态进行计数调查，最后用最大可能数法求出单位体积水样中硝化细菌、反硝化细菌和氨化细菌三类微生物的数量。根据最终数据分析得到的结论是：在人工湿地附近的水中氨化细菌、硝化细菌、反硝化细菌的数量是最多的。

The effects of removal of organic nitrogen by different ammonibacterium were compared and the scale to the quantity of organic nitrogen which consumed by ammonibacterium is the quantity of ammoniacal nitrogen which is produced.

结果表明，芽孢杆菌属、假单胞菌属为人工湿地中氨化细菌的优势菌属；氨化细菌-1、氨化细菌-2及氨化细菌-5对有机氮的去除效果相对较好，分别达到46.2%、49.4%和52.6%。

The mount of germ and fungus quantity in soil are remarkably increased for the continuous cropping about 5 years, puts the trichobacteria quantity always change tendency to reduce;The edaphon total quantity, the bacterium quantity change reduces generally above the continuous cropping 5 years and below 5 years (including 5 years) the change are not obvious;In the nitrogen physiology group by ammoniates the bacterium primarily and the quantity changes are not very big;The nitrifying bacteria quantity is lower than the comparison (non- continuous cropping), the quantity of denitrifying bacteria is opposite;The alkalinity phosphatase, the urease, invertin activeness have a closed relations with the continuous cropping when it will increase less than 5 years or decrease in more than 5 years. The relation between catalase activeness and the continuous cropping is not very big. The reduction of the invertin activeness, the alkalinity phosphatase, urease activeness have slightly elevates, catalase activeness have no the regular changes.

表现为连作条件下土壤真菌数量显著增大，放线菌数量总的变化趋势降低；土壤微生物总量、细菌数量变化在连作5年以上普遍降低，5年以下(包括5年)则变化差异不明显；氮素生理群中以氨化细菌为主，但数量变化不大；硝化细菌数量低于对照组，反硝化细菌数量则相反：多酚氧化酶、转化酶活性在5年之前逐渐上升，5年之后逐渐下降，，脲酶活性随着连作年限增加持续上升，过氧化氢酶活性、碱性磷酸酶活性变化无规律。

The distributions of microbes in various physiological groups had bigger difference in the 5 soil types, n which, the proportions of ammonifying, nitrite, and denitrifying, aerobic dinitrogen fixed bacteria were relatively bigger and that of sulfate-reduction and inverse-sulfuration bacteria were relatively less.

土壤各生理类群微生物在5种类型土壤中的分布有较大差异，氨化细菌、亚硝化细菌、反硝化细菌和好氧固氮菌在5种类型土壤中占有的比例相对较大，硫化细菌和反硫化细菌相对较少。

Ammonifying rate, nitrosifying rate,nitrifying rate and denitrifying rate were determined by measurement of conversion efficiency and accumulating rate of nitrogenous matter by ammonifying bacteria, nitrobacteria, nitrifying bacteria and denitrifying bacteria in the surface 0-1.5 cm of pond sediment from the intensive fish culture ponds.

通过对精养鱼池表层淤泥中氨化细菌、亚硝化细菌、硝化细菌和反硝化细菌对含氮物质转化率的测定，定量了解了上述细菌的氨化率、亚硝化率、硝化率和反硝化率。

Drought stress weakened the rhizosphere effect of ammonifying bacteria.Under drought stress,rhizospheric ammonifying bacterium amount of Baidan31 was very significantly different at seedling and jointing,and significantly different at tasseling-anthesis from that of control.Rhizospheric nitrifying bacteria tended to increase under drought stress.

干旱胁迫减弱了玉米氨化细菌的根际效应，与对照根际氨化细菌数量相比，白单31在苗期和拔节期根际氨化细菌数量受干旱胁迫的影响达极显著水平，在抽雄～开花期达显著水平；根际硝化细菌数量在干旱胁迫下有所增加。

ammonification bacteria：氨化细菌

ammonification 氨化酌 | ammonification bacteria 氨化细菌 | ammonifying process 氨化过程

ammonifier：氨化细菌

ammonification 氨化 | ammonifier 氨化细菌 | ammonisation 氨化

exothermic reaction：放热反应

氨化过程是一个释放能量的过程,或者说是一种放热反应(exothermic reaction). 例如,如果蛋白质的基本构成物是甘氨酸,那么1摩尔的这种蛋白质经过氨化就可释放出736×103焦的热能. 这些能量将被细菌用来维持它们的生命过程.

ammonifying process：氨化过程

ammonification bacteria 氨化细菌 | ammonifying process 氨化过程 | ammonium 铵

ammonifying bacteria：氨化细菌

aminopeptidase 氨,氨基多 | ammonifying bacteria 氨化细菌 | ammonite 菊石