The factors which affect the microalgae absorb CO2 is the hot content.
影响微藻吸收CO2的因素是研究的热点内容。
These biotechnique opened up broad prospects for exploit of microalgae.
这些生物技术为微藻类的利用开辟了广阔的前景。
Microalgae has the ability to degrade and accumulate organic pollutants.
微藻具有富集和降解有机污染物的能力。
The extinction spectra of two species of microalgae suspension were inspected.
研究了两种微藻液消光系数的波长分布特征。
This phenomenon could be used to monitor the synchronous growth of single-cell microalgae.
利用这一特性可以监测单细胞藻的同步生长。
The super-critical fluid method and engineered microalgae method are studied in laboratory now.
超临界流体法和工程微藻法仍处于实验室研究阶段。
The two species of Marine microalgae showed significant differences in fat-ty acids composition.
两种微藻脂肪酸组成显示出明显的种间差异。
Objective: the optimization of the co-immobilization conditions of a bait microalgae and probiotics.
目的:一株饵料微藻与益生菌混合固定化培养条件的优化。
Objective to study the effect of spaceflight and radiation on the photosynthetic system of microalgae.
目的研究空间飞行及辐射对微藻光合系统的影响。
Abstract: Advances in commercial biomass products and bioactive compounds of microalgae were reviewed.
摘要:本文综述了微藻在生物质产品及活性物质开发上的研究进展。
Antifungal activities were stronger than antibacterial activity of protein extracts from the two microalgae.
二种微藻蛋白质提取物抗真菌活性比抗细菌活性大。
Marine Microbiological chemistry: Microalgal bioactive product chemistry and renewable energy from microalgae.
海洋微生物化学:微藻活性产物化学及微藻可再生能源利用。
Antarctic ice microalgae refers to micro algae which lives in the Antarctic sea ice, the sea ice edge or water.
南极冰藻就是指生活在南极海冰、海冰边缘或海水中的一大类微藻。
Growth characteristics of 4 microalgae in bubble condition were studied using experiment combined with production method.
采用实验与生产结合的方法,研究了充气条件下几种饵料单胞藻的生长特性。
The SCF technology actualises the idea of green chemistry in liquefaction of microalgae and epoxidation of propylene reaction.
超临界流体技术在微藻液化和丙烯环氧化反应的应用正是体现绿色化学的思想。
There were significant concentrations and timing differences in the hormesis induced by organophosphorus pesticides in microalgae.
两种农药对两种微藻产生毒物刺激效应的作用浓度存在差异。
Microalgae biomass, as a renewable energy through liquefaction, can be turned into bio-oil, reducing consumption and reliance on fossil fuels.
微藻生物质做为一种可再生能源通过液化可以转化为生物油,减少人类对化石能源的消耗与依赖。
Microalgae are a group of lower plants with the capacity of photosynthesis, widely distributed in marine, freshwater, soil and other environments.
微藻是一类能够进行光合作用的低等植物,广泛分布在海水、淡水、土壤等环境中。
The effect of different concentrations of penicillin on the culture and preservation of three commonly used sea microalgae is studied in this paper.
本文采用青霉素处理三种常用海洋微藻,研究不同青霉素浓度对处理藻类的培养与保存的影响。
The growth rate of microalgae followed a progressive rise with the increase of renewal rate and fall with the extension of renewal period in the culture.
半连续培养间的生长速率随更新率的上升而增大,随更新周期的延长而减小。
The primary biological activities of the compounds were evaluated on the models of cell cytoclasis , brine shrimp and growth inhibition of red tide microalgae.
采用细胞毒、卤虫致死和微藻克生活性筛选模型,对分离得到的单体化合物进行了初步的生物活性评价。
Several kinds of typical methods of maintenance microalgae species are presented, including succeeding preservation, immobilization storage and cryopreservation.
本文介绍了微藻保种的几种常用方法,包括继代保存、固定化保存和超低温保存。
There are many kinds of algae in vast sea area and the inland water in China, such as brown alga, green alga, red alga, blue- green alga and microalgae and so on.
在我国辽阔的海域及内陆水域中生长着多种藻类,如褐藻、绿藻、红藻及蓝藻、微藻等,其中产量较大的有海带、裙带菜和紫菜,在海藻化工上多用于生产碘、胶、醇。
Outcome of the research project can offer theoretical and technical support for predicting of the harmful algal blooms and for culturing of the useful microalgae.
研究结果可为赤潮预测和经济微藻培养提供理论依据和技术支持。
The application of gene engineering in biodiesel production is mainly on improving the lipid content of biodiesel raw materials, such as oil plants and oil microalgae.
基因工程技术在生物柴油中的应用,主要集中在提高生物柴油原料的脂类含量上,如对含油植物和含油微藻的研究。
Light of microalgae is one of the most important factor, different wavelengths of light can affect the metabolism of algae, then affecting the ability of microalgae to absorb CO2.
光是影响微藻生长最重要的因子之一,不同波长的光会影响微藻的新陈代谢,从而影响微藻对CO2的吸收能力。
The usage, status of the development of microalgae and the biotechnology in mass culture and the extraction of bioactive molecules contained in microalgae are reviewed in this paper.
论述海洋微藻的用途,开发利用现状,大 容量培养和生物活性物质提取的生物技术,并指出了开发利用的广阔前景。
Some microalgae can grow mixotrophically and heterotrophically on organic carbon, which can compensate for the light limitation of autotrophication, and also improve the EPA-yielding.
许多微藻具有利用有机碳进行兼养和异养的能力,可以弥补自养培养光限制的不足,并且提高了EPA产量。
Some microalgae can grow mixotrophically and heterotrophically on organic carbon, which can compensate for the light limitation of autotrophication, and also improve the EPA-yielding.
许多微藻具有利用有机碳进行兼养和异养的能力,可以弥补自养培养光限制的不足,并且提高了EPA产量。
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