phytotron

简明释义

英[ˈfaɪtəʊˌtrɒn]美[ˈfaɪtoʊˌtrɑːn]

n. 人工气候室（以人工调节温度、湿度等的实验室）

英英释义

单词用法

同义词

反义词

例句

1.More than 400 rice conventional varieties were aged in a small phytotron, and 38 rice varieties were screened for morphological index.

在小型人工气候箱中，对4 0 0余份常规品种进行人工老化处理，并结合随机抽取的38份材料进行了籼粳形态指数分析。

2.More than 400 rice conventional varieties were aged in a small phytotron, and 38 rice varieties were screened for morphological index.

在小型人工气候箱中，对4 0 0余份常规品种进行人工老化处理，并结合随机抽取的38份材料进行了籼粳形态指数分析。

3.The rooting rates of P, davidiana in phytotron reached 85%.

在人工气候室条件下，山杨扦插生根率达85％。

4.In the phytotron, scientists can manipulate light, temperature, and humidity to optimize plant development.

在植物生长室中，科学家可以操控光照、温度和湿度，以优化植物生长。

5.The phytotron allows for year-round cultivation of crops regardless of external weather conditions.

该植物生长室允许作物在全年无论外部天气条件如何都能进行种植。

6.The university invested in a new phytotron to enhance their agricultural research capabilities.

该大学投资建造了一个新的植物生长室以增强其农业研究能力。

7.The researchers used the phytotron to study plant growth under controlled environmental conditions.

研究人员使用植物生长室来研究在控制环境条件下的植物生长。

8.By using the phytotron, we observed how different nutrient levels affect plant health.

通过使用植物生长室，我们观察到不同营养水平如何影响植物健康。

作文

In the field of plant biology and agriculture, the term phytotron refers to a controlled environment facility used for growing plants under regulated conditions. This innovative technology allows researchers and agricultural scientists to study the effects of various environmental factors on plant growth, such as light, temperature, humidity, and nutrient availability. The concept of a phytotron has revolutionized the way we approach plant research, enabling us to conduct experiments that would be impossible in natural settings due to uncontrolled variables.The primary advantage of using a phytotron is the ability to manipulate environmental conditions with precision. For instance, scientists can simulate different climates to observe how specific plant species respond to changes in temperature or rainfall patterns. This is particularly important in the context of climate change, where understanding how plants adapt to shifting conditions can inform agricultural practices and biodiversity conservation efforts.Moreover, a phytotron can facilitate the study of plant genetics and breeding. By controlling the growth environment, researchers can create optimal conditions for cross-pollination and seed production. This leads to the development of new plant varieties that are more resilient to pests, diseases, and environmental stresses. As a result, the use of a phytotron plays a critical role in enhancing food security and ensuring sustainable agricultural practices.In addition to its applications in research and breeding, a phytotron also serves as an educational tool. Universities and research institutions often utilize these facilities to teach students about plant biology and the scientific method. Students can engage in hands-on experiments, observing firsthand how changes in environmental factors influence plant growth. This experiential learning fosters a deeper understanding of the complexities of plant life and the importance of scientific inquiry.However, operating a phytotron comes with its challenges. The initial setup costs can be high, as these facilities require sophisticated technology to monitor and control environmental conditions. Additionally, maintaining consistent conditions over time demands careful management and regular maintenance. Despite these challenges, the benefits of a phytotron far outweigh the drawbacks, making it an invaluable asset in the fields of botany and agriculture.In conclusion, the phytotron represents a significant advancement in our ability to study and understand plant life. Its capacity to provide controlled environments for research and education makes it an essential tool for scientists and educators alike. As we continue to face global challenges related to food production and climate change, the insights gained from phytotron studies will be crucial in developing strategies to enhance agricultural resilience and sustainability. The future of agriculture may very well depend on the knowledge and innovations derived from these remarkable facilities.

在植物生物学和农业领域，术语phytotron指的是用于在受控条件下种植植物的控制环境设施。这项创新技术使研究人员和农业科学家能够研究各种环境因素对植物生长的影响，例如光照、温度、湿度和营养物质的可用性。phytotron的概念彻底改变了我们对植物研究的方式，使我们能够进行在自然环境中由于不可控变量而不可能进行的实验。使用phytotron的主要优势是能够精确操控环境条件。例如，科学家可以模拟不同的气候，以观察特定植物物种如何应对温度或降雨模式的变化。这在气候变化的背景下尤为重要，因为理解植物如何适应变化的条件可以为农业实践和生物多样性保护工作提供信息。此外，phytotron还可以促进植物遗传学和育种的研究。通过控制生长环境，研究人员可以创造最佳条件进行异花授粉和种子生产。这导致了新植物品种的开发，这些品种对害虫、疾病和环境压力更具抵抗力。因此，使用phytotron在增强粮食安全和确保可持续农业实践方面发挥了关键作用。除了在研究和育种中的应用外，phytotron还作为一种教育工具。大学和研究机构通常利用这些设施教授学生植物生物学和科学方法。学生可以参与动手实验，亲眼观察环境因素变化如何影响植物生长。这种体验式学习加深了对植物生命复杂性的理解以及科学探究重要性的认识。然而，运营phytotron也面临挑战。初始设置成本可能很高，因为这些设施需要复杂的技术来监测和控制环境条件。此外，保持一致的条件需要仔细管理和定期维护。尽管存在这些挑战，phytotron的好处远远超过缺点，使其成为植物学和农业领域中一项宝贵的资产。总之，phytotron代表了我们研究和理解植物生命能力的重要进步。它为研究和教育提供受控环境的能力，使其成为科学家和教育工作者必不可少的工具。随着我们继续面临与粮食生产和气候变化相关的全球挑战，从phytotron研究中获得的见解对于制定增强农业韧性和可持续性的战略至关重要。农业的未来可能在很大程度上取决于从这些卓越设施中获得的知识和创新。