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Discover the latest progress and results from the H-1NF Scanning Interferometer, revealing insights into plasma behavior with high spatial and temporal resolutions. The system employs a unique time-multiplexed approach, allowing detailed observations of plasma dynamics. Gain valuable information on plasma decay, particle transport, and fully ionized plasma physics. Enhancements like expanded diagonal views promise enhanced coverage for in-depth plasma tomography. Benefit from combined instrument data to explore ne, Te, Ti, and ion velocity. Upgrade your understanding of flexible Heliac plasma behavior with this sophisticated tool.
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Progress and New Results from the H-1NF Scanning Interferometer Scott Collis, George Warr, John Howard
A Time Multiplexed Interferometer • The System is basically described as two Michelson Interferometers with a time varying viewing path viewing • The phase shift induced by the plasma is given by • The signal is time multiplexed, which means we only need one detector per probe beam
Beams are swept by a grating wheel • Wheel speed can be varied from 0-6000rpm • At 6000 rpm with a 6 partitioned wheel one scan of the plasma takes 1.8ms • The wheel also Doppler shifts the beam:
Continuous Grating allows viewing of small structures • The grating constant changes linearly across a sector • Possibility of seeing small structures, of order 1cm (beam size) such as islands and transport barriers • Data can aliased when frequency of plasma oscillations approaches the scan frequency of the interferometer
Calibration • We need a transform from temporal position in scan • to spatial position in the H-1NF tank
A 2.5cm absorber was placed at three positions on the bottom mirror
Top Diagonal Results Beam width: 1.3cm
Bottom Diagonal Results Beam width: 3.2cm
High Density ICRH Shot • Fundamental ICRH resonance of Hydrogen • B=0.5T • Peaked density profile • Highest B2ne product observed in H-1NF
Possibilities • With the wheel running at high speed it is possible to get temporally and spatially resolved information on the plasma decay • From this it will be possible to solve the two dimensional diffusion equation • With the new ICRH mode it is possible to study the physics of fully ionized plasmas in H-1NF
But first…. • To tomographically reconstruct density maps of the H-1NF plasma we need a greater coverage of the plasma • We will be expanding the fan of the diagonal views and installing a central view
Using the interferometer to understand particle transport • Using a gas puffer it is possible to modulate the source term in the continuity equation • By modulating the gas flow and using the high temporal and spatial resolution of the interferometer it is possible to gain an insight into how particle transport occurs in H-1NF • Information can be combined with other instruments to gain not only ne but Te Ti and ion velocity
Conclusion • The H-1NF Scanning interferometer can make spatially and temporally resolved measurements of the plasma with resolutions of up to 1cm and 1.8ms • As the system is upgraded the data it produces will provide physical insight into the behavior of flexible Heliac plasmas
