biodinetic temperature limit

简明释义

生物活动温度临界;

英英释义

例句

1.In aquaculture, knowing the biodinetic temperature limit 生物动力温度极限 is essential for maintaining fish health.

在水产养殖中，了解生物动力温度极限 biodinetic temperature limit 对于维持鱼类健康至关重要。

2.Understanding the biodinetic temperature limit 生物动力温度极限 helps farmers decide when to plant crops.

了解生物动力温度极限 biodinetic temperature limit 有助于农民决定何时种植作物。

3.The biodinetic temperature limit 生物动力温度极限 can vary significantly between different species of plants.

不同植物物种之间的生物动力温度极限 biodinetic temperature limit 可能会有很大差异。

4.The biodinetic temperature limit 生物动力温度极限 influences how organisms adapt to their environments.

生物体如何适应其环境受到生物动力温度极限 biodinetic temperature limit 的影响。

5.The researchers found that the biodinetic temperature limit 生物动力温度极限 for this species is crucial for its survival in changing climates.

研究人员发现，这种物种的生物动力温度极限 biodinetic temperature limit 对于其在气候变化中的生存至关重要。

作文

Understanding the concept of biodinetic temperature limit is crucial for various fields, including biology, environmental science, and agriculture. The term refers to the maximum and minimum temperatures at which living organisms can effectively carry out their biological processes. This temperature range is vital for maintaining the health and functionality of ecosystems. When temperatures exceed or fall below this limit, organisms may experience stress, leading to a decline in their growth, reproduction, and survival rates.In biology, the biodinetic temperature limit plays a significant role in determining the habitats of different species. For instance, many plants and animals have adapted to thrive in specific temperature ranges. Tropical plants, for example, flourish in warm climates, while polar species have evolved to withstand extreme cold. Understanding these limits helps scientists predict how climate change might impact biodiversity. As global temperatures rise, species that cannot adapt to new conditions may face extinction.Agriculture is another area where the biodinetic temperature limit is critical. Farmers must be aware of the temperature thresholds for the crops they cultivate. Each plant species has its own optimal growing conditions, and exceeding these limits can result in reduced yields. For example, if a heatwave occurs during the flowering stage of a crop, it can lead to poor pollination and, consequently, lower harvests. Therefore, farmers often implement strategies such as irrigation and shade provision to protect their crops from temperature extremes.Moreover, the biodinetic temperature limit also affects the distribution of pests and diseases. Many agricultural pests thrive in warmer conditions, and as global temperatures rise, the range of these pests expands, posing new challenges for farmers. Understanding the temperature limits of both crops and pests allows for better pest management strategies, which are essential for sustainable agriculture.In environmental science, the biodinetic temperature limit is essential for assessing the health of ecosystems. Temperature fluctuations can disrupt the delicate balance of ecosystems, affecting everything from nutrient cycling to predator-prey relationships. For instance, coral reefs, which are highly sensitive to temperature changes, can suffer from bleaching when water temperatures rise beyond their limits. This not only impacts the corals themselves but also the myriad of marine species that rely on these habitats.In conclusion, the biodinetic temperature limit is a fundamental concept that underpins our understanding of biological processes across various disciplines. By recognizing the importance of temperature ranges for living organisms, we can better address the challenges posed by climate change, optimize agricultural practices, and protect our ecosystems. As we move forward, it is imperative that researchers and policymakers consider these limits in their efforts to create sustainable solutions for our planet's future.

理解biodinetic temperature limit这一概念对于生物学、环境科学和农业等多个领域至关重要。该术语指的是生物体能够有效进行生物过程的最高和最低温度。这个温度范围对于维持生态系统的健康和功能至关重要。当温度超过或低于这个极限时，生物体可能会经历压力，从而导致它们的生长、繁殖和生存率下降。在生物学中，biodinetic temperature limit在确定不同物种栖息地方面发挥着重要作用。例如，许多植物和动物已经适应了在特定温度范围内生存。热带植物例如，在温暖的气候中茁壮成长，而极地物种则进化出抵御极端寒冷的能力。理解这些极限有助于科学家预测气候变化可能对生物多样性产生的影响。随着全球气温上升，无法适应新条件的物种可能面临灭绝。农业是另一个biodinetic temperature limit至关重要的领域。农民必须了解他们所种植作物的温度阈值。每种植物都有其最佳生长条件，超过这些极限可能导致产量减少。例如，如果在作物开花阶段发生热浪，可能导致授粉不良，从而降低收成。因此，农民通常会采取灌溉和遮荫等策略，以保护作物免受温度极端的影响。此外，biodinetic temperature limit还影响害虫和疾病的分布。许多农业害虫在温暖的条件下繁衍生息，随着全球气温上升，这些害虫的分布范围扩大，为农民带来了新的挑战。理解作物和害虫的温度极限使得更好的害虫管理策略成为可能，这对于可持续农业至关重要。在环境科学中，biodinetic temperature limit对于评估生态系统的健康至关重要。温度波动可能扰乱生态系统的微妙平衡，影响从营养循环到捕食者-猎物关系的方方面面。例如，珊瑚礁对温度变化极为敏感，当水温超过其极限时可能会遭受白化。这不仅影响珊瑚本身，还影响依赖这些栖息地的众多海洋物种。总之，biodinetic temperature limit是一个根本性的概念，它支撑着我们对各个学科生物过程的理解。通过认识温度范围对生物体的重要性，我们可以更好地应对气候变化带来的挑战，优化农业实践，并保护我们的生态系统。展望未来，研究人员和政策制定者必须在为我们星球的未来创造可持续解决方案的努力中考虑这些极限。