magnetometric
简明释义
英[/ˌmæɡ.nəˈtɒ.mə.trɪk/]美[/ˌmæɡ.nəˈtɛm.ə.trɪk/]
adj. 磁力的;测磁的
英英释义
Relating to the measurement of magnetic fields or magnetic properties. | 与磁场或磁性特性的测量相关的。 |
单词用法
磁测量 | |
磁测勘测 | |
磁测数据 | |
磁测技术 | |
磁测仪器 | |
磁异常 |
同义词
反义词
| 非磁性的 | Materials that are non-magnetic do not respond to magnetic fields. | 非磁性材料不对磁场产生反应。 | |
| 抗磁性的 | 抗磁性物质会被磁场排斥。 |
例句
1.Finally, the paper give some Suggestions Magnetometric electric method for your reference.
论文的最后给出了磁电法的一些建议供大家参考。
2.Remark: Magnetometric sucking disc or working plateform is required for special work.
备注:特殊工作另配磁力吸盘或工作平台。
3.Finally, the paper give some Suggestions Magnetometric electric method for your reference.
论文的最后给出了磁电法的一些建议供大家参考。
4.The magnetometric approach was crucial in locating the hidden archaeological site.
这种磁测方法对于定位隐藏的考古遗址至关重要。
5.In geology, magnetometric surveys can reveal information about subsurface structures.
在地质学中,磁测调查可以揭示地下结构的信息。
6.The researchers used magnetometric techniques to measure the Earth's magnetic field variations.
研究人员使用磁测技术来测量地球磁场的变化。
7.Engineers rely on magnetometric measurements for designing more efficient magnetic sensors.
工程师依赖磁测测量来设计更高效的磁传感器。
8.The magnetometric data collected from the site helped identify mineral deposits.
从现场收集的磁测数据帮助识别矿藏。
作文
In recent years, the field of geophysics has seen significant advancements, particularly in the area of magnetic surveys. One of the most intriguing aspects of this discipline is the use of magnetometric (磁测的) techniques to explore and analyze the Earth's magnetic field. These methods have proven invaluable for various applications, ranging from mineral exploration to archaeological investigations. Understanding how magnetometric (磁测的) data is collected and interpreted can provide insights into the underlying geological processes that shape our planet.Magnetic surveys typically involve measuring the strength and direction of the Earth's magnetic field at different locations. This process is carried out using specialized instruments known as magnetometers. These devices can detect even the slightest variations in the magnetic field, which can be indicative of underlying geological structures. The magnetometric (磁测的) data collected can reveal a wealth of information about the composition and distribution of minerals, making it an essential tool for geologists and resource explorers.One of the most common applications of magnetometric (磁测的) techniques is in the search for valuable mineral deposits. For instance, certain minerals, such as iron ore, exhibit distinct magnetic properties that can be detected through magnetic surveys. By analyzing the magnetometric (磁测的) data, geologists can identify areas with high concentrations of these minerals, guiding exploration efforts and reducing costs associated with drilling and excavation.In addition to mineral exploration, magnetometric (磁测的) methods are also used in environmental studies. For example, scientists can monitor changes in the magnetic field caused by human activities, such as mining or construction. This information can help assess the environmental impact of these activities and inform more sustainable practices. Furthermore, magnetometric (磁测的) surveys can assist in locating buried waste sites or other contaminants, contributing to efforts in environmental remediation.Another fascinating application of magnetometric (磁测的) techniques is in archaeology. By conducting magnetic surveys at historical sites, archaeologists can uncover hidden structures and artifacts without the need for intrusive excavation. The magnetic signatures of ancient buildings, walls, and even roads can be detected, providing a non-invasive means of exploring our past. This innovative approach not only preserves the integrity of archaeological sites but also enhances our understanding of historical civilizations.As technology continues to advance, the capabilities of magnetometric (磁测的) techniques will only improve. Modern magnetometers are becoming increasingly sensitive and portable, allowing for more extensive and detailed surveys. Additionally, the integration of magnetometric (磁测的) data with other geophysical methods, such as seismic and electrical resistivity surveys, can yield a more comprehensive understanding of subsurface conditions.In conclusion, the role of magnetometric (磁测的) techniques in geophysics is multifaceted and essential for various fields, including mineral exploration, environmental monitoring, and archaeology. As we continue to refine these methods and develop new technologies, the potential applications of magnetometric (磁测的) surveys will undoubtedly expand, providing us with deeper insights into the Earth’s magnetic properties and their implications for our world. Understanding and harnessing the power of magnetometric (磁测的) data will be crucial for addressing future challenges in resource management and environmental conservation.
近年来,地球物理学领域取得了显著进展,尤其是在磁性勘测方面。这个学科中最引人入胜的方面之一是使用magnetometric(磁测的)技术来探索和分析地球的磁场。这些方法在矿产勘探到考古调查等各种应用中证明了其无价之宝。理解如何收集和解释magnetometric(磁测的)数据可以为我们提供有关塑造我们星球的基础地质过程的见解。磁性勘测通常涉及在不同位置测量地球磁场的强度和方向。这个过程是通过使用称为磁力仪的专业仪器进行的。这些设备可以检测到磁场中即使是最微小的变化,这可能表明潜在的地质结构。收集的magnetometric(磁测的)数据可以揭示大量关于矿物组成和分布的信息,使其成为地质学家和资源勘探者的重要工具。magnetometric(磁测的)技术的一个常见应用是在寻找有价值的矿藏方面。例如,某些矿物,如铁矿石,表现出明显的磁性特性,可以通过磁性勘测检测到。通过分析magnetometric(磁测的)数据,地质学家可以识别出这些矿物高浓度的区域,从而指导勘探工作并降低钻探和挖掘的成本。除了矿物勘探外,magnetometric(磁测的)方法还用于环境研究。例如,科学家可以监测由人类活动(如采矿或建设)引起的磁场变化。这些信息可以帮助评估这些活动对环境的影响,并为更可持续的实践提供建议。此外,magnetometric(磁测的)勘测还可以帮助定位埋藏的废弃物场所或其他污染物,为环境修复工作做出贡献。magnetometric(磁测的)技术的另一个迷人应用是在考古学中。通过在历史遗址进行磁性勘测,考古学家可以在不进行侵入性挖掘的情况下揭示隐藏的结构和文物。古代建筑、墙壁甚至道路的磁性特征可以被检测到,提供了一种非侵入性探索我们过去的手段。这种创新方法不仅保护了考古遗址的完整性,还增强了我们对历史文明的理解。随着技术的不断进步,magnetometric(磁测的)技术的能力只会提高。现代磁力仪变得越来越灵敏和便携,允许进行更广泛和详细的勘测。此外,magnetometric(磁测的)数据与其他地球物理方法(如地震和电阻率勘测)的整合,可以提供对地下条件的更全面理解。总之,magnetometric(磁测的)技术在地球物理学中的角色是多方面的,对矿物勘探、环境监测和考古学等各个领域都是至关重要的。随着我们继续完善这些方法并开发新技术,magnetometric(磁测的)勘测的潜在应用无疑将扩展,为我们提供更深入的关于地球磁性特性及其对我们世界的影响的洞察。理解和利用magnetometric(磁测的)数据的力量对于应对未来资源管理和环境保护的挑战至关重要。
