要把利用光合微生物的大胆想法变成现实,还有不少问题要解决。
Problems remain, however, in putting the bold idea to practical use.
光合微生物还能在细胞内储存大量的脂肪,这就是用于合成生物燃料的基础原料。
Photosynthetic microbes also store plenty of fat, which forms the basis for fuel.
介绍了目前制氢的主要方法,光合微生物制氢被认为是最具潜力的氢能生产技术之一。
The main methods for hydrogen production currently are introduced. And production mechanism by photosynthetic microbe was described.
论述了光合微生物的产氢机制,讨论了影响光合微生物放氢的主要因素,如光、菌株特性、氢供体等。
And production mechanism by photosynthetic microbe was described. The effects of several major factors, including light sources, strain characteristic, hydrogen donors, are discussed.
论述了光合微生物的产氢机制,讨论了影响光合微生物放氢的主要因素,如光、菌株特性、氢供体等。
The effects of several major factors, including light sources, strain characteristic, hydrogen donors, are discussed. The achievement and the problems confronted are summarized.
虽然大豆的细胞内含有脂肪物质,也可以提取后加工成生物燃料,但是,就一英亩面积而言,光合微生物的产油量要比大豆高将近250倍。
Some plants, such as soybeans, also store fats and can be used as fuel sources, but photosynthetic microbes produce nearly 250 times more fat per acre.
因为那里完全没有阳光,所以不可能有光合作用的生命,但像在地球深处蓬勃生长的微生物之类的生命可能仍然存在。
Photosynthetic life is impossible there because sunlight is completely absent, but life such as the microbes that flourish deep within earth may still be possible.
猜测包括了火星上发现微生物、土卫六上的光合作用、甚至是一颗小行星上发现了细菌。 全都不是——NASA发现了一种能消来砷的细菌以及将它们组成它的DNA。
Suggestions included microbes on the Red Planet, photosynthesis on Titan, or perhaps even bacteria on an asteroid.
科学家目前用来做实验的微生物是有光合作用能力的微生物,如藻类和蓝细菌(有时叫做蓝绿藻或蓝藻)。
Scientists are experimenting with photosynthetic microbes such as algae and cyanobacteria (sometimes referred to as blue-green algae).
已经知道一些光合细菌能够利用红外光,但是和植物和蓝细菌不同,这些微生物光合的时候不能产生氧气。
Some photosynthetic bacteria are known to use infrared light, but—in contrast to plants andcyanobacteria—these microorganisms do not produce oxygen.
这种和光合作用微生物的亲密共存现象曾被发现存在于无脊椎动物中,比如说珊瑚,但是从未在脊椎动物中发现过。
Such a close co-existence with a photosynthetic organism has previously been found in invertebrates, such as corals, but never in a vertebrate.
最终,培养基中只剩下像蓝细菌这类能够利用近红外光进行光合作用的微生物存活下来。
Eventually, only microorganisms like cyanobacteria capable of photosynthesis using near-infrared light survived in the cultures.
在地球上,一方面绿色植物在光合过程中捕获了为生存所需的能量,一方面微生物广泛地担负着对光合产物进行最终的分解。
While the energy for on this planet is captured by green plants in the photosynthetic process, microorganisms are generally responsible for the final decomposition of the photosynthetic products .
据认为,世界上所发生的光合作用中,多达90%是由海洋中的微生物完成的。
It is thought that as much as 90 percent of the photosynthesis which takes place in the world goes on in microscopic water plants in the sea.
采用砂培方法研究了光合细菌对番茄发芽的影响和采用盆栽试验研究了光合细菌对番茄生长过程中光合色素、部分抗氧化酶以及微生物区系的影响。
The affects of Photosynthetic bacteria on burgeon of tomato through sand culture method on pigment, enzyme system of tomato and soil microbe through pot culture experiment were studied.
研究了不换水、添加以光合细菌和芽胞杆菌属为主的复合微生物制剂于水中对西施舌育苗的影响。
A mode of using photosynthetic bacteria and Bacillus for rearing Coelomatra antiquate larvae under no water exchange was studied.
连续两年的试验结果表明,复合微生物肥料在水稻上施用能延长水稻叶片的功能期,促进叶片光合作用,增加分蘖数,有效地提高亩穗数和结实率。
Composting experiment of surplus sludge applying complex microbial community(CMC) was carried out to systematically study the function of CMC in composting system to some extends of surplus sludge.
EM是有益微生物菌群的英文缩写,它主要含有五大菌群:光合菌群、乳酸菌群、酵母菌群、放线菌群、醋酸杆菌。
EM (Effective microbes) consists of 5 colonies: photosynthetic microbes , lactic acid microbes, yeast microbes, ray fungus microbes, acetic acid bacilli.
EM是有益微生物菌群的英文缩写,它主要含有五大菌群:光合菌群、乳酸菌群、酵母菌群、放线菌群、醋酸杆菌。
EM (Effective microbes) consists of 5 colonies: photosynthetic microbes , lactic acid microbes, yeast microbes, ray fungus microbes, acetic acid bacilli.
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