xerothermic
简明释义
英[ˌzɪərəʊˈθɜːmɪk]美[ˌzɪrəˈθərmɪk]
adj. 干热的;适于干热环境的
英英释义
Relating to or denoting a climate characterized by hot, dry conditions. | 指与炎热、干燥气候相关的或描述这种气候的。 |
单词用法
干热环境 | |
干热植被 | |
干热地区 | |
适应干热栖息地 | |
干热生态系统的特征 | |
在干热地区茁壮成长 |
同义词
| 干旱的 | 沙漠以其干旱的气候为特征。 | ||
| 干燥的 | 该地区的干燥季节持续几个月。 | ||
| 脱水的 | 干燥的土壤使植物难以生长。 | ||
| 灼热的 | The scorched earth left behind after the wildfire was a stark reminder of the disaster. | 野火过后留下的焦土是灾难的明显提醒。 |
反义词
| 湿生的 | 湿生植物在潮湿的环境中生长良好。 | ||
| 中生的 | Mesophytic ecosystems are characterized by moderate moisture levels. | 中生生态系统的特征是适度的湿度水平。 |
例句
1.Currently, mainstream medical dry films mostly include: xerothermic raster display laser imaging films, direct hot imaging films, whole digital sunlight dry films.
主流干式医用胶片主要分为:干热显像激光成像片、热敏干式胶片及全数字化阳光干式胶片。
2.Currently, mainstream medical dry films mostly include: xerothermic raster display laser imaging films, direct hot imaging films, whole digital sunlight dry films.
主流干式医用胶片主要分为:干热显像激光成像片、热敏干式胶片及全数字化阳光干式胶片。
3.It obtained success in estimating the moisture profit and loss, and has significance in analyzing Xerothermic winds and droughts.
利用本计算方法所得结果在评估水分盈亏时取得了明显的成效,在干旱和干热风分析中有重要的实际意义。
4.Many species thrive in xerothermic 干旱热带的 habitats, showcasing unique adaptations.
许多物种在xerothermic 干旱热带的栖息地中蓬勃发展,展示出独特的适应性。
5.The xerothermic 干旱热带的 conditions of the desert challenge many forms of life.
沙漠的xerothermic 干旱热带的条件对许多生命形式构成挑战。
6.The xerothermic 干旱热带的 regions often experience extreme temperature fluctuations.
在xerothermic 干旱热带的地区,温度波动通常非常剧烈。
7.In a xerothermic 干旱热带的 environment, plants have adapted to conserve water.
在xerothermic 干旱热带的环境中,植物已经适应了水分的保存。
8.The Xerothermic 干旱热带的 climate of the region makes it suitable for cacti and succulents.
该地区的Xerothermic 干旱热带的气候使其适合生长仙人掌和多肉植物。
作文
The term xerothermic refers to a climate or environment that is characterized by high temperatures and low moisture levels. This type of climate can be found in various regions around the world, particularly in areas such as deserts and semi-arid zones. Understanding the implications of xerothermic conditions is essential for various fields, including ecology, agriculture, and urban planning. In an ecological context, xerothermic environments support a unique set of flora and fauna that have adapted to survive in harsh conditions. For example, many plants in these regions have developed deep root systems to access underground water, while others may have thick, waxy leaves to reduce water loss through evaporation. Animals, too, exhibit fascinating adaptations; some are nocturnal, avoiding the heat of the day, while others have evolved specialized behaviors to conserve water. These adaptations highlight the resilience of life in xerothermic climates and emphasize the importance of biodiversity in maintaining ecological balance. From an agricultural perspective, farming in xerothermic regions presents significant challenges. Traditional crops may struggle to thrive due to insufficient rainfall and intense sunlight. Consequently, farmers often turn to drought-resistant varieties or implement innovative irrigation techniques to maximize water efficiency. Techniques such as drip irrigation and rainwater harvesting are becoming increasingly popular in xerothermic areas, allowing farmers to sustain their livelihoods despite the challenging conditions. Furthermore, understanding soil health becomes crucial, as xerothermic soils can become degraded without proper management. Urban planning in xerothermic regions also requires careful consideration. Cities situated in these climates must address issues related to heat retention and water scarcity. Urban heat islands, where built-up areas experience significantly higher temperatures than their rural surroundings, can exacerbate the effects of xerothermic conditions. To combat this, planners can incorporate green spaces, which not only provide shade but also help with cooling through evapotranspiration. Additionally, sustainable building practices that prioritize energy efficiency and water conservation are essential in xerothermic locales. Moreover, climate change poses an added threat to xerothermic regions. As global temperatures rise, these areas may experience even more extreme weather patterns, leading to prolonged droughts and increased desertification. This underscores the need for proactive measures to mitigate the impacts of climate change, such as reforestation projects and the promotion of sustainable agricultural practices. In conclusion, the concept of xerothermic environments encompasses a wide range of challenges and opportunities. By studying the unique characteristics of these climates, we can develop strategies to adapt and thrive in them. Whether through ecological research, agricultural innovation, or sustainable urban planning, understanding the implications of xerothermic conditions is crucial for fostering resilience in our ever-changing world. The knowledge gained from these studies not only benefits the regions directly affected but also contributes to our broader understanding of climate adaptation and sustainability.
干热的一词指的是一种特征为高温和低湿度的气候或环境。这种气候可以在世界各地的不同地区找到,尤其是在沙漠和半干旱区。理解干热的条件的影响对于生态学、农业和城市规划等多个领域至关重要。在生态学背景下,干热的环境支持着一套独特的动植物群,这些生物已经适应了恶劣的条件。例如,许多生长在这些地区的植物发展出了深根系统,以便获取地下水,而其他一些植物可能有厚厚的蜡质叶子,以减少通过蒸发造成的水分流失。动物同样表现出迷人的适应性;一些是夜行性的,避免白天的高温,而另一些则进化出特殊的行为来保存水分。这些适应性突显了生命在干热的气候中的韧性,并强调了生物多样性在维持生态平衡中的重要性。从农业的角度来看,在干热的地区进行农业生产面临重大挑战。传统作物可能由于降雨不足和强烈阳光而难以生长。因此,农民通常转向抗旱品种或实施创新的灌溉技术,以最大化水资源利用效率。在干热的地区,滴灌和雨水收集等技术变得越来越普遍,使农民能够在艰难的条件下维持生计。此外,了解土壤健康变得至关重要,因为如果没有适当管理,干热的土壤可能会退化。位于干热的地区的城市规划也需要仔细考虑。位于这些气候下的城市必须解决与热量保持和水资源短缺相关的问题。城市热岛现象,即建筑区域的温度明显高于周边农村地区,可以加剧干热的条件的影响。为了解决这个问题,规划者可以纳入绿地,不仅提供阴凉,还通过蒸散作用帮助降温。此外,优先考虑能源效率和水资源保护的可持续建筑实践在干热的地区至关重要。此外,气候变化对干热的地区构成了额外威胁。随着全球气温上升,这些地区可能会经历更极端的天气模式,导致长期干旱和加剧的沙漠化。这凸显了采取主动措施以减轻气候变化影响的必要性,例如重新造林项目和推广可持续农业实践。总之,干热的环境的概念涵盖了广泛的挑战和机遇。通过研究这些气候的独特特征,我们可以制定适应和繁荣的策略。无论是通过生态研究、农业创新还是可持续城市规划,理解干热的条件的影响对于在我们不断变化的世界中培养韧性至关重要。从这些研究中获得的知识不仅使直接受影响的地区受益,同时也有助于我们更广泛地理解气候适应和可持续性。
