bathymetric contour

简明释义

等深线

英英释义

例句

1.In coastal engineering, understanding the bathymetric contour 水深等高线 is crucial for designing breakwaters.

在沿海工程中，理解水深等高线 bathymetric contour 对于设计防波堤至关重要。

2.The researchers created a 3D model based on the bathymetric contour 水深等高线 data collected during the survey.

研究人员根据调查中收集的水深等高线 bathymetric contour 数据创建了一个三维模型。

3.The marine biologist studied the bathymetric contour 水深等高线 to understand the underwater habitat of various species.

这位海洋生物学家研究了水深等高线 bathymetric contour，以了解各种物种的水下栖息地。

4.Using a sonar device, the team mapped the bathymetric contour 水深等高线 of the lake to identify potential fishing spots.

团队使用声纳设备绘制了湖泊的水深等高线 bathymetric contour，以识别潜在的钓鱼地点。

5.The bathymetric contour 水深等高线 lines on the map indicate where the ocean floor drops sharply.

地图上的水深等高线 bathymetric contour 线显示出海底急剧下降的位置。

作文

The study of oceanography is crucial for understanding the complex dynamics of our planet's waters. One important aspect of this field is the analysis of underwater topography, which can be represented through various methods, including maps and digital models. A significant term in this context is bathymetric contour, which refers to the lines on a map that connect points of equal depth in a body of water. These contours provide essential information about the underwater landscape, such as the location of underwater mountains, valleys, and plains. By examining bathymetric contours, scientists can gain insights into marine ecosystems, sediment transport, and even the potential for underwater resources.Understanding bathymetric contours is vital not only for academic research but also for practical applications in navigation and environmental management. For instance, sailors rely on these contours to avoid shallow areas that could pose risks to their vessels. Additionally, fishermen use this information to locate productive fishing grounds, as certain depths are more conducive to supporting diverse marine life.Moreover, bathymetric contours are essential in the study of climate change. As sea levels rise, the changes in underwater topography can affect ocean currents and, consequently, global weather patterns. Scientists use bathymetric data to model these changes and predict future scenarios, enabling better preparation for potential impacts on coastal communities.The technology used to create bathymetric contours has advanced significantly over the years. Traditional methods involved manual soundings taken from ships, which were labor-intensive and limited in scope. Today, modern sonar systems and satellite imagery allow for high-resolution mapping of the ocean floor. These advancements have greatly enhanced our understanding of underwater landscapes and their significance.In addition to their scientific importance, bathymetric contours also play a role in environmental conservation efforts. Understanding the underwater terrain helps in the identification of critical habitats, such as coral reefs and seagrass beds, which are essential for biodiversity. Conservationists can use this information to implement measures that protect these vulnerable ecosystems from threats like pollution and climate change.Furthermore, bathymetric contours aid in the planning and development of offshore infrastructure, such as wind farms and oil drilling sites. By analyzing the contours, engineers can determine the most suitable locations for construction while minimizing environmental impact. This careful planning is crucial as we transition to renewable energy sources and seek sustainable ways to harness ocean resources.In conclusion, bathymetric contours are a fundamental component of oceanographic studies, providing valuable insights into underwater topography and its implications for navigation, marine ecology, climate change, and resource management. As technology continues to evolve, our ability to accurately map and understand these underwater landscapes will undoubtedly improve, leading to better stewardship of our oceans. The significance of bathymetric contours cannot be overstated, as they serve as a key to unlocking the mysteries of the deep sea and ensuring a sustainable future for our planet's waterways.

海洋学的研究对于理解我们星球水域的复杂动态至关重要。这个领域的一个重要方面是对水下地形的分析，这可以通过各种方法进行表示，包括地图和数字模型。在这种情况下，一个重要的术语是水深等高线，它指的是在水体中连接相同深度点的线。这些等高线提供了有关水下景观的重要信息，例如水下山脉、山谷和平原的位置。通过检查水深等高线，科学家可以深入了解海洋生态系统、沉积物运输，甚至潜在的水下资源。理解水深等高线不仅对学术研究至关重要，而且对航行和环境管理的实际应用也至关重要。例如，水手依靠这些等高线来避免可能对船只构成风险的浅水区。此外，渔民利用这些信息来定位富饶的渔场，因为某些深度更有利于支持多样的海洋生物。此外，水深等高线在气候变化研究中也是必不可少的。随着海平面上升，水下地形的变化可能会影响海洋洋流，从而影响全球天气模式。科学家使用水深数据来建模这些变化并预测未来情景，从而更好地为潜在影响沿海社区做好准备。用于创建水深等高线的技术近年来显著进步。传统方法涉及从船只进行手动测量，这既费力又有限制。今天，现代声纳系统和卫星图像允许对海底进行高分辨率映射。这些进步极大增强了我们对水下景观及其重要性的理解。除了科学重要性之外，水深等高线在环境保护工作中也发挥着作用。理解水下地形有助于识别关键栖息地，例如珊瑚礁和海草床，这些栖息地对生物多样性至关重要。保护主义者可以利用这些信息实施保护措施，以保护这些脆弱的生态系统免受污染和气候变化等威胁。此外，水深等高线有助于离岸基础设施的规划和开发，例如风电场和石油钻探场地。通过分析等高线，工程师可以确定最适合施工的位置，同时尽量减少对环境的影响。这种细致的规划至关重要，因为我们正在向可再生能源转型，并寻求可持续的方式来利用海洋资源。总之，水深等高线是海洋研究的基本组成部分，为水下地形及其对航行、海洋生态、气候变化和资源管理的影响提供了宝贵的见解。随着技术的不断进步，我们准确绘制和理解这些水下景观的能力无疑将得到改善，从而更好地保护我们的海洋。水深等高线的重要性不容小觑，因为它们是揭开深海奥秘的钥匙，并确保我们星球水域可持续未来的保障。