integrated geophysical system

简明释义

1. 综合地球物理系统; 2. 综合物探系统;

英英释义

例句

1.Using an integrated geophysical system can significantly enhance the accuracy of subsurface mapping.

使用综合地球物理系统可以显著提高地下映射的准确性。

2.The integrated geophysical system helped identify potential mineral deposits in the area.

这个综合地球物理系统帮助识别了该地区潜在的矿藏。

3.An integrated geophysical system combines data from various sources for better geological assessments.

一个综合地球物理系统结合来自不同来源的数据，以便更好地进行地质评估。

4.The research team developed an integrated geophysical system to monitor seismic activities in the region.

研究团队开发了一个综合地球物理系统来监测该地区的地震活动。

5.The oil company invested in an integrated geophysical system to optimize their exploration efforts.

这家石油公司投资于一个综合地球物理系统以优化他们的勘探工作。

作文

In recent years, the field of geophysics has made significant advancements, particularly with the development of an integrated geophysical system. This system combines various geophysical methods and technologies to provide a comprehensive understanding of the Earth's subsurface. The need for such a system arises from the complexity of geological formations and the necessity for accurate data in fields such as oil and gas exploration, mineral resource assessment, and environmental studies. An integrated geophysical system integrates data from seismic, magnetic, gravitational, and electrical methods, allowing scientists and engineers to create a more complete picture of the subsurface environment.The primary advantage of using an integrated geophysical system is its ability to enhance the resolution and reliability of geological interpretations. For instance, while seismic surveys can provide information about the structure and stratigraphy of the Earth, they may not effectively identify certain types of minerals or fluids. By incorporating magnetic and gravitational data, which respond to different physical properties of the subsurface materials, researchers can fill in the gaps left by seismic data alone. This holistic approach not only improves the accuracy of geological models but also reduces the risk associated with exploration activities.Moreover, an integrated geophysical system can significantly reduce costs and time associated with data collection and analysis. Traditional methods often require multiple surveys and separate analyses for each technique, leading to increased expenses and extended project timelines. In contrast, an integrated geophysical system allows for simultaneous data acquisition and processing, streamlining workflows and making projects more efficient. This efficiency is particularly crucial in industries where time is money, such as in oil drilling or construction projects.In addition to economic benefits, the implementation of an integrated geophysical system also promotes environmental sustainability. By providing more accurate assessments of subsurface conditions, these systems can help minimize the environmental impact of exploration and extraction activities. For example, better understanding of groundwater resources can lead to more responsible management practices, reducing the risk of contamination and depletion.Furthermore, the integration of various geophysical techniques enhances our ability to monitor geological hazards. Natural disasters such as earthquakes, landslides, and volcanic eruptions pose significant risks to communities worldwide. An integrated geophysical system can be employed to monitor seismic activity, ground deformation, and other indicators of potential hazards, enabling timely warnings and preventive measures to be put in place.In conclusion, the advent of the integrated geophysical system represents a major leap forward in geophysical research and applications. By combining multiple geophysical methods, this system provides a more detailed and accurate understanding of the Earth's subsurface, leading to improved decision-making in resource exploration, environmental protection, and hazard monitoring. As technology continues to advance, we can expect even greater innovations in the field of geophysics, making the integrated geophysical system an essential tool for scientists and industry professionals alike.

近年来，地球物理学领域取得了显著进展，尤其是随着综合地球物理系统的发展。该系统结合了各种地球物理方法和技术，以提供对地球地下的全面理解。之所以需要这样的系统，是因为地质构造的复杂性以及在石油和天然气勘探、矿产资源评估和环境研究等领域对准确数据的必要性。综合地球物理系统整合了来自地震、磁力、重力和电法的数据，使科学家和工程师能够创建更完整的地下环境图像。使用综合地球物理系统的主要优势在于其能够增强地质解释的分辨率和可靠性。例如，虽然地震勘测可以提供有关地球结构和地层的信息，但可能无法有效识别某些类型的矿物或流体。通过结合磁力和重力数据，这些数据对地下材料的不同物理特性作出反应，研究人员可以填补仅凭地震数据留下的空白。这种整体方法不仅提高了地质模型的准确性，还降低了与勘探活动相关的风险。此外，综合地球物理系统可以显著降低数据收集和分析的成本和时间。传统方法通常需要多次勘测和对每种技术的单独分析，导致费用增加和项目时间延长。相比之下，综合地球物理系统允许同时进行数据采集和处理，从而简化工作流程，使项目更加高效。这种效率在石油钻探或建筑项目等以时间为金钱的行业中尤为重要。除了经济利益，实施综合地球物理系统还促进了环境可持续性。通过提供对地下条件的更准确评估，这些系统可以帮助最小化勘探和开采活动对环境的影响。例如，更好地了解地下水资源可以导致更负责任的管理实践，减少污染和枯竭的风险。此外，各种地球物理技术的整合增强了我们监测地质灾害的能力。地震、滑坡和火山喷发等自然灾害对全球社区构成重大风险。综合地球物理系统可以用于监测地震活动、地面变形和其他潜在危险的指标，从而使及时警报和预防措施得以实施。总之，综合地球物理系统的出现代表了地球物理研究和应用的重大飞跃。通过结合多种地球物理方法，该系统提供了对地球地下的更详细和准确的理解，从而改善了在资源勘探、环境保护和灾害监测中的决策。随着技术的不断进步，我们可以期待地球物理领域的更大创新，使综合地球物理系统成为科学家和行业专业人士的重要工具。