PhD in Astrophysical and Geophysical Fluid Dynamics - Magnetohydrodynamic Experiments
  • 学历文凭

    Ph.D.

  • 专业院系

    物理与天文学

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  • 课程时长

  • 课程学费

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国际学生入学条件

Applicants to research degree programmes should normally have at least a first class or an upper second class bachelors honours degree in an appropriate discipline
IELTS (International English Language Testing System) Academic at 6.0 overall with no less than 5.5 in each component skill
TOEFL iBT (Test of English as a Foreign Language Internet-Based Test) at 87 overall with no less than 20 in listening, 20 in reading, 22 in speaking and 21 in writing
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雅思考试总分

6.0

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  • 雅思总分:6
  • 托福网考总分:87
  • 托福笔试总分:160
  • 其他语言考试:PTE (Pearson Test of English) Academic at 60 overall with no less than 59 in any component
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课程简介

Most research in astrophysical and geophysical fluids is either observational or theoretical. There are a number of groups though, in America, France, Germany, Russia, and other countries, that have taken on the challenge of trying to reproduce some of the relevant physics in laboratory experiments. Working with liquid sodium or gallium obviously involves considerable technical difficulties, not only in handling them safely, but also in measuring the resulting fluid flows. It is the only way though to study magnetohydrodynamic (MHD) phenomena in the lab. In the astrophysical and geophysical fluids group at Leeds we do not do experiments ourselves (we are mathematicians, after all, not physicists). Instead, we use theoretical/computational modelling to try to understand some of the existing results, and also suggest new experimental possibilities. We are in close contact with several of the experimental groups. The basic principle whereby a fluid flow may generate a magnetic field is well known, if the advective timescale L/U is shorter than the diffusive timescale L2/η, the flow has a chance anyway of being a dynamo. More formally, the magnetic Reynolds number RmUL/η must be at least O(10) or so. In stellar and planetary interiors, this condition is easily met, since the typical length scales L are so large, even quite modest flow scales U suffice. In the lab though, this condition is not so easily satisfied, due to the large magnetic diffusivity η of typical liquid metals (1 m2/s). If L1 m (already a rather large device), U must then be at least 10 m/s. To have any chance of achieving dynamo action, large volumes of liquid metal must therefore be churned around at high speeds. Furthermore, in order to be a dynamo, a flow must be not only sufficiently vigorous, but also sufficiently complex in its spatial structure. The two successful laboratory dynamos to date, in Riga (Latvia) and Karlruhe (Germany), achieved this complexity by means of pipes and baffles within the fluid, thereby severely constraining the motion. However, much of the interest in achieving a fluid dynamical dynamo is precisely in the freedom that the fluid flow and the magnetic field have in adjusting to one another (unlike a bicycle dynamo, say, in which the motion is very precisely constrained, consisting simply of a rotating coil of wire). Current work in this area is therefore focussed on trying to achieve dynamo action in less constrained flows. The basic physics behind the MRI is again well known, it is a mechanism whereby a differential rotation profile such as that found in Keplerian accretion disks may be hydrodynamically stable, but nevertheless magnetohydrodynamically unstable. A number of groups are currently trying to achieve this instability in the lab, by confining the fluid between differentially rotating cylinders. One important difference between these MRI experiments and the dynamo experiments discussed above is that in the MRI experiments there is also an externally imposed magnetic field. This was originally taken to be along the axis of the cylinders, but one of our contributions (Hollerbach & Rudiger 2005) was to show that adding an azimuthal field as well dramatically reduces the speeds at which one must rotate the inner and outer cylinders. A number of groups are now working on implementing this new experimental design.
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利兹大学在《2025 完整大学指南》中名列英国大学前25名,在2025 QS世界大学排名中名列世界前100名。它也是罗素大学集团大学之一,这是英国著名的顶尖研究密集型大学名单。该大学的学生满意度很高,在英国排名第三(2018年《泰晤士报高等教育学生体验调查》)。作为同一项调查的一部分,该大学的校园设施在英国排名第二,这是对学生发挥潜力的绝佳校园的认可。近年来,两栋新建筑投资超过1.2亿英镑。体育设施也被认为是世界级的。The Edge是一个为学生提供的令人难以置信的健身中心,包括一个25米的室内游泳池、攀岩墙和为不同体育活动设置的各种大厅。这是一所热情友好的大学,拥有充满活力、多样化的学生群体。事实上,来自世界130多个不同国家的13800多名国际学生在利兹大学学习。学生会是这个国家最活跃、最活跃的工会之一。学生可以加入300多个俱乐部和社团,利兹大学联盟(LUU)是英国第一个被全国学生联合会评为''优秀''的俱乐部和社团。

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