Megagauss Physics

Fowler, C.M.

doi:10.1126/science.180.4083.261

Cited by 39 publications

(3 citation statements)

References 26 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In agreement with previous results [12,13] it was found that the rotation angle was almost linear as a function of the magnetic field, as demonstrated in figure 5. Nonlinearities of the effect have been reported in the literature [14], but these phenomena occur in a field range far beyond our experimental possibilities and preferably at shorter wavelengths [15]. The theoretical field dependence of the rotation angle deduced from the generally accepted value of the Verdet constant, V = 7.2 • (mm −1 T −1 ), coincides very well with our experimental results, thus confirming the high precision of our field measurements.…”

Section: The Faraday Rotationsupporting

confidence: 91%

Solid state applications of a transportable low-cost megagauss generator

Puhlmann¹,

Portugall²,

ller³

et al. 1997

J. Phys. D: Appl. Phys.

View full text Add to dashboard Cite

A table-top megagauss generator, employing the single-turn coil technique has successfully been applied in solid state physics. Magnetic fields up to 113 T are generated within a useful volume of about . A detailed description of techniques for high-quality field measurements under the conditions of a short time duration and the presence of strong transient electric disturbances during the field generation is given. Faraday rotation in CdS as well as cyclotron resonance experiments in n-type PbSe are presented as examples of the efficiency of the generator as a scientific instrument.

show abstract

Section: The Faraday Rotationsupporting

confidence: 91%

Solid state applications of a transportable low-cost megagauss generator

Puhlmann¹,

Portugall²,

ller³

et al. 1997

J. Phys. D: Appl. Phys.

View full text Add to dashboard Cite

show abstract

“…Ultrahigh magnetic fields have been generated by imploding a conducting shell (liner) around a magnetic flux, for example, using high explosives [11] or high current [12].…”

mentioning

confidence: 99%

Threshold for Thermal Ionization of an Aluminum Surface by Pulsed Megagauss Magnetic Field

et al. 2010

View full text Add to dashboard Cite

The first measurement of the threshold for thermal ionization of the surface of thick metal by pulsed magnetic field (B) is reported. Thick aluminum-with depth greater than the magnetic skin layer-was pulsed with partial differential B/ partial differential t from 30-80 MG/micros. Novel loads avoided nonthermal plasma (from electron avalanche, or energetic particles or photons from arcs). Thermal plasma forms from 6061-alloy aluminum when the surface magnetic field reaches 2.2 MG, in qualitative agreement with numerical simulation results by Garanin et al. [J. Appl. Mech. Tech. Phys. 46, 153 (2005)].

show abstract

“…The very first experiments, on the Faraday and Zeeman effects, were mainly demonstrations that experiments could actually be done, and precise verifications of the field measurement [96]. Further experiments at Los Alamos were mainly done with 'strip' compression generators, both optical and magneto-resistance experiments at temperatures down to the liquid helium range [45,47,49,55]. At Livermore, the isentropic compression of hydrogen was extensively studied with fields of order 10 MG [63].…”

Section: Merits For Experimental Applicationsmentioning

confidence: 99%

Pulsed magnets

Herlach¹

1999

Rep. Prog. Phys.

105

View full text Add to dashboard Cite

Pulsed magnets are divided into two categories: below 100 T with pulse duration in the range 1 ms-1 s, and above 100 T with pulse duration of order microsecond due to self-destruction of the coil. For both categories, simple scaling laws for the performance are given. For nondestructive magnets, these depend in the first place on the mechanical strength and electrical conductivity of the materials used in coil design; another important parameter is the size of the bore. Together with the energy and power available from the pulsed power supply, this determines peak field and pulse duration. Different types of power supply are discussed, capacitor banks as well as controlled rectification of ac power. For destructive magnets, there is a simple relation between the peak field and the velocity at which the coil structure is expanded by the magnetic force; this can be estimated from shock wave properties of the conductor. The expansion can be neutralized by imploding the coil in a flux compression experiment. High explosives as well as electromagnetic forces have been used for this purpose to obtain fields up to 2800 T. A simple and efficient method is the exploding single-turn coil; this is best suited for experiments up to 300 T.The design and performance of the different magnets is discussed in detail. A few examples for application of these magnets in experiments are given. Prospects for generating higher fields by different methods are discussed, in particular miniaturization on all levels-coils ('micro-magnets') as well as experiments.

show abstract

Megagauss Physics

Cited by 39 publications

References 26 publications

Solid state applications of a transportable low-cost megagauss generator

Solid state applications of a transportable low-cost megagauss generator

Threshold for Thermal Ionization of an Aluminum Surface by Pulsed Megagauss Magnetic Field

Pulsed magnets

Contact Info

Product

Resources

About