artificial atmospher

简明释义

人工气氛

英英释义

例句

1.The greenhouse creates an artificial atmosphere 人工气候 that helps plants grow year-round.

温室创造了一种人工气候 人工气候，帮助植物全年生长。

2.In space missions, astronauts rely on an artificial atmosphere 人工气候 to breathe and survive.

在太空任务中，宇航员依赖于人工气候 人工气候来呼吸和生存。

3.The hotel offers rooms with an artificial atmosphere 人工气候 designed to enhance relaxation.

这家酒店提供的房间具有旨在增强放松感的人工气候 人工气候。

4.Aquariums often maintain an artificial atmosphere 人工气候 to ensure fish thrive in captivity.

水族馆通常维持一种人工气候 人工气候以确保鱼类在圈养环境中繁荣。

5.The simulation room uses an artificial atmosphere 人工气候 to mimic conditions on Mars for research.

模拟室使用人工气候 人工气候来模仿火星上的条件以进行研究。

作文

In recent years, the concept of an artificial atmosphere has gained significant attention in various fields, including environmental science, space exploration, and even architecture. An artificial atmosphere refers to a man-made environment that mimics the characteristics of the natural atmosphere, often created for specific purposes such as supporting life in hostile environments or enhancing certain conditions for scientific research. This essay will explore the significance of artificial atmospheres, their applications, and the challenges associated with creating and maintaining them.One of the most prominent applications of artificial atmospheres is in the field of space exploration. Astronauts traveling to the Moon, Mars, or beyond require a controlled environment to survive the harsh conditions of outer space. The absence of breathable air, extreme temperatures, and high levels of radiation make it essential to create an artificial atmosphere within spacecraft and habitats on other planets. For instance, the International Space Station (ISS) maintains a carefully regulated atmosphere, ensuring that astronauts have access to oxygen while removing carbon dioxide and other harmful gases. This careful balance is crucial for long-term missions and lays the groundwork for future colonization efforts.Another significant area where artificial atmospheres are utilized is in agriculture, particularly in controlled-environment agriculture (CEA). Greenhouses and vertical farms often employ artificial atmospheres to optimize plant growth by regulating temperature, humidity, and carbon dioxide levels. By creating an ideal environment, farmers can increase crop yields and reduce the need for pesticides, ultimately leading to more sustainable agricultural practices. The use of artificial atmospheres in agriculture also allows for year-round production, which is especially important in regions with harsh climates.Moreover, artificial atmospheres play a vital role in scientific research. Laboratories often require specific atmospheric conditions to conduct experiments that would be impossible under natural circumstances. For example, researchers studying the effects of climate change on various ecosystems may create artificial atmospheres to simulate future environmental conditions. These controlled settings allow scientists to observe how different species respond to changes in temperature, humidity, and carbon dioxide levels, providing valuable insights into the potential impacts of global warming.However, creating and maintaining an artificial atmosphere is not without its challenges. One of the primary concerns is the energy required to sustain these environments. For instance, maintaining the necessary temperature and humidity levels in a greenhouse can consume significant amounts of energy, raising questions about sustainability. Additionally, the materials used to construct habitats with artificial atmospheres must be carefully selected to ensure they can withstand the pressures and conditions of their environments.In conclusion, the development of artificial atmospheres has opened up new possibilities in various fields, from space exploration to agriculture and scientific research. By creating controlled environments that mimic natural conditions, we can support life in inhospitable places, enhance agricultural productivity, and conduct important scientific studies. However, the challenges of energy consumption and material selection must be addressed to ensure that these advancements are sustainable. As technology continues to evolve, the potential for artificial atmospheres to transform our understanding of life and our ability to thrive in diverse environments will only grow stronger.

近年来，‘人工气氛’的概念在环境科学、太空探索甚至建筑等多个领域引起了显著关注。‘人工气氛’指的是一种人造环境，模仿自然气氛的特征，通常是为了特定目的而创建，如在恶劣环境中支持生命或增强科学研究的某些条件。本文将探讨‘人工气氛’的重要性、应用及其创建和维护所面临的挑战。‘人工气氛’最显著的应用之一是在太空探索领域。前往月球、火星或更远地方的宇航员需要一个受控环境，以便在外太空严酷条件下生存。缺乏可呼吸空气、极端温度和高辐射水平使得在宇宙飞船和其他星球栖息地内创造‘人工气氛’变得至关重要。例如，国际空间站（ISS）维持着一个经过仔细调节的气氛，确保宇航员能够获得氧气，同时去除二氧化碳和其他有害气体。这种微妙的平衡对于长期任务至关重要，并为未来的殖民努力奠定了基础。另一个‘人工气氛’被广泛利用的重要领域是农业，特别是在受控环境农业（CEA）中。温室和垂直农场通常利用‘人工气氛’来优化植物生长，通过调节温度、湿度和二氧化碳水平。通过创造理想环境，农民可以提高作物产量并减少对农药的需求，从而最终导致更可持续的农业实践。在农业中使用‘人工气氛’还允许全年生产，这在气候恶劣的地区尤为重要。此外，‘人工气氛’在科学研究中也发挥着至关重要的作用。实验室通常需要特定的气氛条件来进行在自然情况下无法进行的实验。例如，研究气候变化对各种生态系统影响的研究人员可能会创造‘人工气氛’以模拟未来的环境条件。这些受控环境允许科学家观察不同物种如何应对温度、湿度和二氧化碳水平的变化，为全球变暖潜在影响提供宝贵的见解。然而，创建和维护‘人工气氛’并非没有挑战。主要的担忧之一是维持这些环境所需的能源。例如，维持温室内必要的温度和湿度水平可能消耗大量能源，这引发了关于可持续性的问题。此外，用于构建具有‘人工气氛’的栖息地的材料必须经过精心选择，以确保它们能够承受其环境的压力和条件。总之，‘人工气氛’的发展在多个领域开启了新的可能性，从太空探索到农业和科学研究。通过创造模仿自然条件的受控环境，我们可以在不适宜居住的地方支持生命，增强农业生产力，并进行重要的科学研究。然而，能源消耗和材料选择的挑战必须得到解决，以确保这些进步是可持续的。随着技术的不断发展，‘人工气氛’改变我们对生命的理解以及我们在多样环境中茁壮成长的能力的潜力将愈加强大。