bacterial biomass

简明释义

1. 细菌生命伐; 2. 细菌生物质;

英英释义

例句

1.Environmental changes can drastically affect the levels of bacterial biomass in aquatic ecosystems.

环境变化可以大幅影响水生生态系统中细菌生物量的水平。

2.The bacterial biomass in the gut plays a vital role in digestion and nutrient absorption.

肠道中的细菌生物量在消化和营养吸收中起着重要作用。

3.Researchers found a significant increase in bacterial biomass after adding organic matter to the compost.

研究人员发现，在堆肥中添加有机物后，细菌生物量显著增加。

4.In aquaculture, monitoring bacterial biomass is crucial for maintaining water quality.

在水产养殖中，监测细菌生物量对于维持水质至关重要。

5.The study measured the bacterial biomass in the soil to assess its fertility.

该研究测量了土壤中的细菌生物量以评估其肥力。

作文

Bacterial biomass, or bacterial biomass, refers to the total mass of bacteria in a given environment. This concept is crucial in various fields such as ecology, microbiology, and environmental science. Understanding bacterial biomass can provide insights into the health of ecosystems, the efficiency of bioremediation processes, and the dynamics of nutrient cycling.In natural environments, bacteria are essential players in nutrient cycling. They break down organic matter and recycle nutrients, making them available for other organisms. The measurement of bacterial biomass helps scientists assess the productivity of an ecosystem. For instance, in aquatic systems, high levels of bacterial biomass often indicate a healthy environment where organic material is being efficiently decomposed.Moreover, in agricultural contexts, bacterial biomass plays a vital role in soil fertility. Bacteria contribute to the decomposition of organic matter, which enhances soil structure and nutrient availability. Farmers and agronomists monitor bacterial biomass to optimize soil health and crop yields. By promoting beneficial bacterial populations, they can improve the sustainability of farming practices.In biotechnology, bacterial biomass is harnessed for various applications, including the production of biofuels, pharmaceuticals, and enzymes. The efficiency of these processes often depends on the growth and metabolic activity of bacteria. Therefore, understanding and optimizing bacterial biomass is key to enhancing production yields and reducing costs.Furthermore, the study of bacterial biomass is also important in the context of environmental remediation. Certain bacteria can degrade pollutants, and their biomass can be used to treat contaminated environments. For example, in wastewater treatment plants, the management of bacterial biomass is critical for effective treatment processes, ensuring that harmful substances are broken down and removed from the water.However, it is essential to note that not all bacteria are beneficial. Some pathogenic bacteria can also contribute to bacterial biomass, posing risks to human health and the environment. Therefore, monitoring the composition of bacterial biomass is equally important to distinguish between harmful and beneficial strains.In conclusion, bacterial biomass is a fundamental concept that encompasses the mass of bacteria in various ecosystems. Its implications stretch across multiple disciplines, including ecology, agriculture, biotechnology, and environmental science. By studying and managing bacterial biomass, we can enhance our understanding of ecological health, improve agricultural practices, and develop innovative solutions for environmental challenges. As we continue to explore the complexities of microbial life, the significance of bacterial biomass will undoubtedly remain a focal point in scientific research and practical applications.

细菌生物量或细菌生物量，指的是在特定环境中细菌的总质量。这个概念在生态学、微生物学和环境科学等多个领域至关重要。理解细菌生物量可以为我们提供生态系统健康、污染修复过程的效率和营养循环动态的深入见解。在自然环境中，细菌是营养循环的重要参与者。它们分解有机物质并回收养分，使其他生物能够利用。细菌生物量的测量帮助科学家评估生态系统的生产力。例如，在水体系统中，高水平的细菌生物量通常表明一个健康的环境，在这里有机物质被有效地分解。此外，在农业背景下，细菌生物量在土壤肥力中发挥着重要作用。细菌有助于有机物质的分解，从而增强土壤结构和养分的可用性。农民和农艺师监测细菌生物量以优化土壤健康和作物产量。通过促进有益细菌种群，他们可以改善农业实践的可持续性。在生物技术领域，细菌生物量被用于各种应用，包括生物燃料、药品和酶的生产。这些过程的效率通常依赖于细菌的生长和代谢活动。因此，理解和优化细菌生物量是提高生产产量和降低成本的关键。此外，研究细菌生物量在环境修复中也很重要。某些细菌可以降解污染物，它们的生物量可以用于处理受污染的环境。例如，在废水处理厂，细菌生物量的管理对于有效的处理过程至关重要，确保有害物质被分解并从水中去除。然而，必须注意到，并非所有细菌都是有益的。一些致病细菌也可以贡献于细菌生物量，对人类健康和环境构成风险。因此，监测细菌生物量的组成同样重要，以区分有害和有益菌株。总之，细菌生物量是一个基本概念，涵盖了各种生态系统中细菌的质量。它的影响跨越多个学科，包括生态学、农业、生物技术和环境科学。通过研究和管理细菌生物量，我们可以增强对生态健康的理解，改善农业实践，并为环境挑战开发创新解决方案。随着我们继续探索微生物生命的复杂性，细菌生物量的重要性无疑将继续成为科学研究和实际应用的焦点。