Experiments to Investigate Non-Linear Microwave Interactions in Plasma

研究等离子体中非线性微波相互作用的实验

• 批准号: 2124050
• 金额: --
• 依托单位: University of Strathclyde
• 依托单位国家: 英国
• 项目类别: Studentship
• 财政年份: 2018
• 资助国家: 英国
• 起止时间: 2018 至 无数据
• 项目状态: 已结题
• 来源: https://gtr.ukri.org/projects?ref=studentship-2124050
• 关键词: Experiments; Investigate; Non; Linear; Microwave

Plasma is a state of matter that exists when the energy level or temperature becomes sufficiently high that electrons are no longer bound to atoms. This produces at least two species (negative electrons and positive ions) with opposite charge and very different masses (electron mass << ion mass). The charge of both types of particle make them each respond to electromagnetic fields (such as light, microwave and radio waves), but in opposite directions, and at very different rates. They particularly respond to waves at frequencies close those of natural plasma oscillations, determined by complicated combinations of the magnitude and direction of any static magnetic field, the number density and mass of the particles. They can absorb wave energy at frequencies called 'resonances', and reflect wave energy at frequencies called 'cut-offs'. These effects are often used to heat or measure plasmas in important laboratory experiments and applications, such as new techniques for energy production through fusion reactions (magnetically confined) and industrial processing as well as natural plasmas in the Earth's magnetosphere and ionosphere. Both natural ionospheric and magnetospheric plasmas are important to modern communication and navigation systems. In industrial processing, plasma physics underpins semiconductor processing and hence modern digital technology. In fusion energy research the impact potential is to enable an almost unlimited supply of energy, addressing serious environmental concerns surrounding the use of fossil fuel, with no long term radioactive byproducts.Parametric coupling refers to a multi-wave interaction where two or more waves exchange energy when their frequencies are related by a natural plasma oscillation frequency. Such processes have recently been found to cause difficulties in laser-plasma interactions for inertial confinement fusion, whilst at the same time offering exciting potential for new and more flexible ways of delivering energy into both inertially and magnetically confined fusion plasmas. Indications exist that suggest such new techniques will be increasingly important as such research moves from fundamental experiments to application scale equipment. We therefore propose to undertake fundamental research investigating these interactions in the microwave frequency range. The microwave range is particularly appealing for such research since powerful sources and amplifiers, developed for a range of applications, are readily available, can be very precisely controlled, enhancing the ability to investigate the plasma physics dynamics, whilst groundbreaking research points towards microwave generators achieving very high levels of normalised intensity (a measure of the effective intensity of the wave, affected by the wavelength, meaning that microwave intensities are effectively 'uplifted' compared to optical intensities). This indicates potential in the microwave frequency range to explore the dynamics of extreme ranges of wave-plasma interaction in the near future. A further motivation for investigating the effect of wave coupling using microwaves is its direct application relevance to industrial processing and magnetic confinement fusion plasma physics.The coupling of two precisely controlled microwave beams (~10cm to 3cm wavelength) in a (weakly to strongly) magnetised helicon plasma by plasma (acoustic-like) oscillations in the electrons and ions, cyclotron oscillation of the electrons and ions and hybrid oscillations including both quasi-acoustic and cyclotron motion will be investigated, as will the effects of stochastic heating where 'quasi-random' motion of particles in high amplitude waves gives very rapid increase in effective temperature.

等离子体是一种物质状态，当能量水平或温度变得足够高时，电子不再与原子结合。这会产生至少两种具有相反电荷和非常不同质量（电子质量<<离子质量）的物质（负电子和正离子）。这两种粒子的电荷使它们各自对电磁场（如光、微波和无线电波）作出反应，但方向相反，速度也大不相同。它们对频率接近自然等离子体振荡频率的波特别敏感，而自然等离子体振荡是由静磁场的大小和方向、粒子的数量密度和质量的复杂组合决定的。它们可以在称为“共振”的频率下吸收波能，并在称为“截止”的频率下反射波能。在重要的实验室实验和应用中，例如通过聚变反应（磁约束）和工业加工产生能量的新技术以及地球磁层和电离层中的天然等离子体，这些效应通常用于加热或测量等离子体。自然电离层和磁层等离子体对现代通信和导航系统都很重要。在工业加工中，等离子体物理学是半导体加工的基础，因此也是现代数字技术的基础。在核聚变能源研究中，核聚变的潜在影响是实现几乎无限的能源供应，解决化石燃料使用带来的严重环境问题，同时不会产生长期的放射性副产品。参数耦合是指多波相互作用，当两个或多个波的频率与自然等离子体振荡频率相关时，它们交换能量。这种过程最近被发现在激光等离子体相互作用的惯性约束聚变造成的困难，而在同一时间提供了令人兴奋的潜力，新的和更灵活的方式提供能量到惯性和磁约束聚变等离子体。有迹象表明，随着这些研究从基础实验转向应用规模设备，这些新技术将变得越来越重要。因此，我们建议进行基础研究，调查微波频率范围内的这些相互作用。微波范围对此类研究特别有吸引力，因为为一系列应用开发的强大源和放大器随时可用，可以非常精确地控制，增强了研究等离子体物理动力学的能力，同时开创性的研究指向微波发生器实现非常高的归一化强度水平。（受波长影响的波的有效强度的量度，意味着微波强度与光学强度相比被有效地“提升”）。这表明在不久的将来，在微波频率范围内探索波-等离子体相互作用的极端范围的动力学的潜力。研究使用微波的波耦合效应的另一动机是其与工业处理和磁约束聚变等离子体物理学的直接应用相关性。（~ 10 cm至3 cm波长），（弱到强）磁化螺旋等离子体将研究电子和离子中的（类声）振荡、电子和离子的回旋振荡以及包括准声和回旋运动的混合振荡，随机加热的效果也是如此，其中粒子在高振幅波中的“准随机”运动使有效温度非常迅速地增加。