Update on the Scientific Status of the Plasma Focus

Auluck, S. K. H.; Kubeš, P.; Paduch, M.; Sadowski, M.; Krauz, V. I.; Lee, Paul; Soto, Leopoldo; Scholz, M.; Miklaszewski, R.; Schmidt, H.; Blagoev, A.; Samuelli, M.; Seng, Yeow Sing; Springham, S. V.; Talebitaher, A.; Pavez, Cristian; Akel, M.; Yap, S. L.; Verma, Rishi; Koláček, K.; Keat, Paul Lee Choon; Rawat, Rajdeep Singh; Abdou, A.; Zhang, Guixin; Laas, T.

doi:10.3390/plasma4030033

Cited by 39 publications

(53 citation statements)

References 359 publications

(875 reference statements)

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“…In a multi-step combustion mechanism with known operating conditions (such as H 2 , O 2 , HO 2 , H + , OH − , HO 2 , O 2+ , and δ is the third body in our simulation), the concentration of oxygen is found from the rate equations of other species involved in the system 78 61 ). 4, Plasma discharges in pure neon (adapted from 68 ). 5, Effect of liners in PF discharge (adapted from 68 ).…”

Section: Plasma For Oxygen Sensingmentioning

confidence: 99%

“…8, Electric circuit of nitrogen-plasma jet device (adapted from 61 ). 9, Real-time plasma from an RIE setup (adapted from 70 10, Electron density profiles at 3 different distances from the anode plane (adapted from 68 ). 11, FEM simulated electron density vs position of candle flame.…”

Section: Plasma For Oxygen Sensingmentioning

confidence: 99%

“…(adapted from61 ). 4, Plasma discharges in pure neon (adapted from68 ). 5, Effect of liners in PF discharge (adapted from68 ).…”

mentioning

confidence: 99%

“…4, Plasma discharges in pure neon (adapted from68 ). 5, Effect of liners in PF discharge (adapted from68 ). 6, An air plasma generation setup (adapted from64 ).…”

mentioning

confidence: 99%

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Towards real-time oxygen sensing: From nanomaterials to plasma

Vinitha¹,

Chinmaya²,

CV³

et al. 2021

Preprint

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A significantly large scope is available for the scientific and engineering developments of high-throughput ultra-high sensitive oxygen sensors. We give a perspective of oxygen sensing for two physical states of matters -solid-state nanomaterials and plasma. From single-molecule experiments to material selection, we reviewed various aspects of sensing, such as capacitance, photophysics, electron mobility, response time, and a yearly progress. Towards miniaturisation, we have highlighted the benefit of lab-on-chip-based devices and showed exemplary measurements of fast real-time oxygen sensing. From the physicalchemistry perspective, plasma holds a strong potential in the application of oxygen sensing. We investigated the current state-of-the-art of electron density, temperature, and design issues of plasma systems. We also show a numerical aspects of low-cost approach towards developing plasma-based oxygen sensor from household candle flame. In this perspective, we give an opinion about a diverse range of scientific insight together, identifies the short comings, and opens the path for new physical-chemistry device developments of oxygen sensor along with providing a guideline for innovators in oxygen sensing.

show abstract

Section: Plasma For Oxygen Sensingmentioning

confidence: 99%

Section: Plasma For Oxygen Sensingmentioning

confidence: 99%

See 2 more Smart Citations

Towards real-time oxygen sensing: From nanomaterials to plasma

Vinitha¹,

Chinmaya²,

CV³

et al. 2021

Preprint

View full text Add to dashboard Cite

show abstract

“…The present paradigm of plasma focus research can be succinctly summarized in terms of a Standard Narrative [3]. Its chief defining characteristic feature is a travelling distribution of current (that can be initiated by a variety of mechanisms [3], but is most commonly initiated by a sliding discharge on an insulator) accelerated by its own magnetic field that drives an ionizing shock wave into the neutral fill gas, mainly deuterium, and its subsequent convergence into a dense and hot plasma column. Physical separation of the current distribution (measured using magnetic probes) and the dense shockwave plasma (that is seen in most emissivity and refractivity-based diagnostics) is a well-established fact.…”

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confidence: 99%

On filamentation in the dense plasma focus

Auluck

2022

Physics of Plasmas

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Striking pictures showing filamentary structures in the plasma focus have intrigued researchers from the early days of plasma focus research. A definitive understanding of their occurrence, origin, structure, and role in plasma focus physics is still not in sight as summarized in a recent comprehensive review. This is because they are often not observed in a “standard mode” of plasma focus operation with pure deuterium, particularly in large installations, but are found in smaller experiments or those with gaseous admixtures. This has led to the suspicion that filaments are not a native feature of the plasma focus phenomenon. Recent success in observation of filaments in PF-1000 in pure deuterium operation by novel modification of the interferometer system that allows simultaneous interferometry and schlieren photography changes this situation. This Letter looks at the implications of this development in the larger context of plasma focus physics. Conceptualization of filamentation as a native feature of the traveling current distribution behind an ionizing strong shock wave is shown to be a feasible paradigm that can be formulated as a computable model for filamentation in the plasma focus.

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On the “quantum theory of paraxial ray optics according to Dietrich Marcuse” and its connection with a new class of interferometers

Auluck

2024

J Opt

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Update on the Scientific Status of the Plasma Focus

Cited by 39 publications

References 359 publications

Towards real-time oxygen sensing: From nanomaterials to plasma

Towards real-time oxygen sensing: From nanomaterials to plasma

On filamentation in the dense plasma focus

On the “quantum theory of paraxial ray optics according to Dietrich Marcuse” and its connection with a new class of interferometers

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