geomorphology
简明释义
英[dʒiːəʊmɔːˈfɒlədʒi]美[ˌdʒiəmɔrˈfɑlədʒi]
n. 地形学,地貌学
英英释义
Geomorphology is the scientific study of landforms and the processes that shape them, including erosion, sedimentation, and tectonic activity. | 地貌学是对地形及其形成过程的科学研究,包括侵蚀、沉积和构造活动。 |
单词用法
地貌特征 | |
地貌过程 | |
地貌学与景观演变 | |
地貌学的应用 |
同义词
反义词
| 人类活动过程 | The impact of anthropogenic processes on the landscape is significant. | 人类活动过程对地貌的影响是显著的。 | |
| 城市化 | 城市化导致了自然地貌的变化。 |
例句
1.Soil is an important component in agriculture resources which relates with parent rock, topography-geomorphology, climate, vegetation and artificial factor.
土壤是农业资源中的重要组成部分,土壤的发育受到地势地貌、母岩母质、气候、植被及人为因素的影响。
2.According to many researchers achievement, the response of fluvial geomorphology to tectonic movement is discussed.
以前人的研究工作为例,讨论了河流地貌对构造活动的响应。
3.Geomorphology is one of the most factors of physical geographical environment.
地貌是自然地理环境要素的重要组成部分。
4.The difference in time corresponded to the difference in climate, so there is difference in type and shape of Guangxi tropical karst geomorphology.
这种时间上的差异,不仅造成了发育时气候上的差异,还造成了广西各地区热带岩溶地貌类型、形态上的不同。
5.Scale is a platitude problem of geomorphology.
尺度是一个老生常谈的地学问题。
6.Fluvial erosion is among the core components in tectonic geomorphology.
河流地貌和侵蚀是构造地貌研究的核心内容。
7.Geomorphology deals with the origin of landscapes and changes in them.
地貌学研究地形的成因及其变化。
8.Researchers in geomorphology often analyze soil and rock formations to predict erosion patterns.
从事地貌学的研究人员常常分析土壤和岩石形成,以预测侵蚀模式。
9.Understanding geomorphology is crucial for managing natural resources effectively.
理解地貌学对于有效管理自然资源至关重要。
10.In our geography class, we learned about the various processes that shape geomorphology.
在我们的地理课上,我们学习了塑造地貌学的各种过程。
11.The study of geomorphology helps us understand how landscapes are formed over time.
对地貌学的研究帮助我们理解景观是如何随着时间形成的。
12.The principles of geomorphology can be applied to urban planning to mitigate flood risks.
可以将地貌学的原理应用于城市规划,以减轻洪水风险。
作文
The study of the Earth's surface and its various forms is known as geomorphology. This scientific discipline focuses on understanding the processes that shape the landforms we see around us, from majestic mountains to intricate river valleys. By examining the physical features of the Earth, geomorphology helps us comprehend not only the history of our planet but also the dynamic forces that continue to modify it today.In essence, geomorphology investigates how natural elements such as water, ice, wind, and tectonic activity contribute to the sculpting of landscapes. For instance, rivers erode land as they flow, carving out canyons and creating deltas where they meet larger bodies of water. Similarly, glaciers can reshape entire regions by grinding down rock and depositing sediment as they advance and retreat. Understanding these processes is crucial for predicting future changes in the environment, especially in the context of climate change.Moreover, geomorphology plays a vital role in various practical applications. Urban planners, for example, rely on geomorphic assessments to determine suitable locations for infrastructure development. Knowledge of the local topography can influence decisions related to building roads, bridges, and even entire cities. Additionally, geomorphology is essential in the field of environmental management, where understanding landforms can help mitigate natural hazards such as landslides and flooding.The significance of geomorphology extends beyond just scientific inquiry; it also intersects with cultural and historical studies. Many ancient civilizations thrived in areas where the geomorphological features provided fertile land for agriculture or natural defenses against invaders. By studying the landforms of these regions, researchers can gain insights into the lifestyles and survival strategies of past societies.Furthermore, modern techniques in geomorphology, such as remote sensing and geographic information systems (GIS), have revolutionized the way scientists analyze landscapes. These technologies allow for detailed mapping and modeling of landforms, enabling researchers to visualize changes over time and predict future developments. As a result, geomorphology has become an interdisciplinary field that incorporates aspects of geology, geography, ecology, and even archaeology.In conclusion, geomorphology is a critical field of study that enhances our understanding of the Earth's physical features and the processes that create them. Its applications are vast, impacting urban planning, environmental conservation, and historical research. As we face global challenges such as climate change and urbanization, the insights gained from geomorphology will be invaluable in shaping sustainable solutions for the future. By continuing to explore and understand the intricate relationships between landforms and the forces that shape them, we can better navigate the complexities of our ever-changing world.
地球表面及其各种形态的研究被称为地貌学。这个科学学科专注于理解塑造我们周围地貌的过程,从雄伟的山脉到复杂的河谷。通过检查地球的物理特征,地貌学帮助我们理解不仅是我们星球的历史,还有继续影响它的动态力量。本质上,地貌学研究自然元素如水、冰、风和构造活动如何共同作用来雕刻景观。例如,河流在流动时侵蚀土地,雕刻出峡谷,并在与较大水体相遇时形成三角洲。同样,冰川可以通过磨平岩石和沉积物的堆积来重新塑造整个地区。理解这些过程对于预测未来环境变化至关重要,特别是在气候变化的背景下。此外,地貌学在各种实际应用中发挥着重要作用。例如,城市规划者依赖地貌评估来确定基础设施开发的合适位置。对当地地形的了解可以影响与建造道路、桥梁甚至整个城市相关的决策。此外,地貌学在环境管理领域也是必不可少的,了解地貌特征可以帮助减轻自然灾害,如山体滑坡和洪水。地貌学的重要性不仅限于科学探究;它还与文化和历史研究交叉。许多古代文明在地貌特征提供的肥沃土地或自然防御的地区繁荣发展。通过研究这些地区的地貌特征,研究人员可以深入了解过去社会的生活方式和生存策略。此外,现代的地貌学技术,如遥感和地理信息系统(GIS),已经彻底改变了科学家分析景观的方式。这些技术允许对地貌进行详细的制图和建模,使研究人员能够可视化随时间变化的变化并预测未来的发展。因此,地貌学已成为一个跨学科的领域,结合了地质学、地理学、生态学甚至考古学的各个方面。总之,地貌学是一个关键的研究领域,增强了我们对地球物理特征及其形成过程的理解。它的应用广泛,影响着城市规划、环境保护和历史研究。随着我们面临气候变化和城市化等全球挑战,从地貌学中获得的见解将在塑造可持续解决方案方面发挥重要作用。通过继续探索和理解地貌与塑造它们的力量之间的复杂关系,我们可以更好地应对我们不断变化的世界的复杂性。
