aerobiosis
简明释义
英[ˌeərəʊbaɪˈəʊsɪs]美[ˌeroʊbaɪˈoʊsɪs]
n. [微] 需氧生活;[微] 好氧生活
复 数 a e r o b i o s e s
英英释义
单词用法
有氧生物过程 | |
有氧生物环境 | |
有氧生物条件 | |
有氧生物代谢 | |
对有氧生物的适应 | |
有氧呼吸 | |
有氧生长 | |
有氧活动 | |
有氧生存 | |
有氧阶段 |
同义词
| 有氧呼吸 | Aerobic respiration is essential for the survival of many organisms. | 有氧呼吸对许多生物的生存至关重要。 | |
| 依赖氧气的新陈代谢 | Oxygen-dependent metabolism plays a crucial role in energy production. | 依赖氧气的新陈代谢在能量生产中起着关键作用。 |
反义词
| 厌氧生物 | 厌氧生物存在于缺氧的环境中。 | ||
| 厌氧的 | Many bacteria thrive in anaerobic conditions, which are essential for certain biochemical processes. | 许多细菌在厌氧条件下繁衍生息,这对某些生化过程至关重要。 |
例句
1.The process index of aerobiosis exposural pool treatment method can be selected by aerobiosis vibration bottle.
可以通过好氧振荡瓶培养法来选择好氧曝气池处理法的工艺参数。
2.The process index of aerobiosis exposural pool treatment method can be selected by aerobiosis vibration bottle.
可以通过好氧振荡瓶培养法来选择好氧曝气池处理法的工艺参数。
3.The fermentation process is an example of a reaction that occurs without aerobiosis 需氧生存.
发酵过程是一个在没有aerobiosis 需氧生存 的情况下发生的反应的例子。
4.In the absence of aerobiosis 需氧生存, anaerobic processes take over in decomposing organic matter.
在缺乏aerobiosis 需氧生存 的情况下,厌氧过程开始主导分解有机物。
5.In aerobic environments, organisms rely on aerobiosis 需氧生存 to generate energy efficiently.
在需氧环境中,生物依赖于aerobiosis 需氧生存 高效地生成能量。
6.The study of aerobiosis 需氧生存 is crucial for understanding how aerobic bacteria thrive in soil.
研究aerobiosis 需氧生存 对于理解好氧细菌如何在土壤中繁衍至关重要。
7.Many fish species require aerobiosis 需氧生存 to survive, as they extract oxygen from water.
许多鱼类需要aerobiosis 需氧生存 来生存,因为它们从水中提取氧气。
作文
In the study of biology, the term aerobiosis refers to a form of life that requires oxygen for survival. This process is fundamental to many organisms, including humans, as it enables them to produce energy through cellular respiration. The significance of aerobiosis cannot be overstated, as it plays a crucial role in maintaining the balance of ecosystems. Without organisms that rely on aerobiosis, the atmosphere would lack the necessary oxygen levels to support life as we know it. To understand aerobiosis, it is essential to compare it with its counterpart, anaerobiosis, which describes life forms that thrive in the absence of oxygen. While anaerobic organisms may seem less common, they are equally important in various ecological niches. However, the prevalence of aerobiosis in the animal kingdom highlights its importance in evolutionary terms. Most animals, including humans, depend on aerobic processes to metabolize food and produce energy efficiently.The process of aerobiosis involves several biochemical pathways, primarily the Krebs cycle and oxidative phosphorylation. These pathways occur in the mitochondria of cells, where oxygen acts as the final electron acceptor in the electron transport chain. This process not only produces adenosine triphosphate (ATP), the energy currency of cells, but also generates carbon dioxide and water as byproducts. This efficient energy production is why aerobic organisms can sustain higher levels of activity compared to their anaerobic counterparts.In addition to its biological implications, aerobiosis has significant environmental consequences. The presence of aerobic organisms contributes to the cycling of nutrients and the decomposition of organic matter. For example, bacteria that engage in aerobiosis play a vital role in breaking down dead plants and animals, returning essential nutrients to the soil and promoting plant growth. This process is crucial for agriculture and maintaining healthy ecosystems.Moreover, the study of aerobiosis extends beyond the realm of biology into areas such as medicine and environmental science. Understanding how aerobic processes work can help develop treatments for diseases related to cellular respiration, such as mitochondrial disorders. Additionally, research into aerobiosis can inform strategies to combat climate change, as these organisms are integral to carbon cycling and oxygen production.In conclusion, aerobiosis is a vital concept in biology that encompasses the relationship between oxygen and life. It highlights the intricate connections within ecosystems and the importance of maintaining a balance between aerobic and anaerobic processes. As we continue to explore the complexities of life on Earth, the role of aerobiosis will remain a key area of focus, shaping our understanding of biology, ecology, and environmental sustainability.
在生物学研究中,术语aerobiosis指的是一种需要氧气才能生存的生命形式。这个过程对许多生物体,包括人类,都是至关重要的,因为它使它们能够通过细胞呼吸产生能量。aerobiosis的重要性不容小觑,因为它在维持生态系统的平衡中发挥着关键作用。如果没有依赖于aerobiosis的生物,地球大气中将缺乏支持我们所知生命所需的氧气水平。要理解aerobiosis,必须将其与其对应的厌氧生存方式进行比较,后者描述的是在缺乏氧气的情况下繁荣的生命形式。虽然厌氧生物似乎不那么常见,但它们在各种生态位中同样重要。然而,动物王国中aerobiosis的普遍存在突显了它在进化方面的重要性。大多数动物,包括人类,都依赖于有氧过程来有效地代谢食物并产生能量。aerobiosis的过程涉及几个生化途径,主要是克雷布斯循环和氧化磷酸化。这些途径发生在细胞的线粒体中,氧气作为电子传递链中的最终电子受体。这个过程不仅产生了细胞的能量货币——三磷酸腺苷(ATP),还生成二氧化碳和水作为副产品。这种高效的能量生产是有氧生物能够维持比厌氧生物更高活动水平的原因。除了生物学意义外,aerobiosis还具有重要的环境影响。有氧生物的存在促进了营养物质的循环和有机物质的分解。例如,从事aerobiosis的细菌在分解死去的植物和动物方面发挥着重要作用,将基本营养物质返回土壤,促进植物生长。这个过程对农业和维持健康生态系统至关重要。此外,aerobiosis的研究超越了生物学的领域,扩展到医学和环境科学等领域。了解有氧过程如何运作可以帮助开发与细胞呼吸相关的疾病的治疗方法,例如线粒体疾病。此外,对aerobiosis的研究可以为应对气候变化提供信息,因为这些生物在碳循环和氧气生产中是不可或缺的。总之,aerobiosis是生物学中的一个重要概念,涵盖了氧气与生命之间的关系。它突显了生态系统内的复杂联系以及维持有氧和厌氧过程之间平衡的重要性。随着我们继续探索地球上生命的复杂性,aerobiosis的角色将始终是一个关键的关注领域,塑造我们对生物学、生态学和环境可持续性的理解。
