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| 003 | MiAaHDL | ||
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| 019 | ⊔ | ⊔ | ‡a62529755 |
| 035 | ⊔ | ⊔ | ‡a(MiU)990180508170106381 |
| 035 | ⊔ | ⊔ | ‡asdr-miu.990180508170106381 |
| 035 | ⊔ | ⊔ | ‡z(MiU)MIU01000000000000018050817-goog |
| 035 | ⊔ | ⊔ | ‡a(OCoLC)317554478 |
| 035 | ⊔ | ⊔ | ‡z(MiU)Aleph018050817 |
| 040 | ⊔ | ⊔ | ‡aLHL ‡beng ‡cLHL ‡dHLS ‡dOCLCF ‡dOCLCO ‡dOCLCQ ‡dCOD ‡dTRAAL |
| 049 | ⊔ | ⊔ | ‡aMAIN |
| 050 | ⊔ | 4 | ‡aQC718.5.C65 ‡bG35 1968 |
| 086 | 0 | ⊔ | ‡aD 301.45/40:353 |
| 088 | ⊔ | ⊔ | ‡aAD 669063 |
| 088 | ⊔ | ⊔ | ‡aAFCRL 68-140 |
| 100 | 1 | ⊔ | ‡aGallagher, Charles C., ‡d1937- ‡eauthor. |
| 245 | 1 | 0 | ‡aPlasma containment in a minimum-B geometry / ‡cCharles C. Gallagher, Lewis S. Combes, Morton A. Levine. |
| 264 | ⊔ | 1 | ‡aL. G. Hansom Field, Bedford, Massachusetts : ‡bAir Force Cambridge Research Laboratories, Office of Aerospace Research, United States Air Force, ‡c1968. |
| 300 | ⊔ | ⊔ | ‡avi, 26 pages : ‡billustrations ; ‡c28 cm. |
| 336 | ⊔ | ⊔ | ‡atext ‡btxt ‡2rdacontent |
| 337 | ⊔ | ⊔ | ‡aunmediated ‡bn ‡2rdamedia |
| 338 | ⊔ | ⊔ | ‡avolume ‡bnc ‡2rdacarrier |
| 490 | 0 | ⊔ | ‡aAFCRL ; ‡v68-0140 |
| 490 | 0 | ⊔ | ‡aPhysical Sciences Research Papers ; ‡vNo. 353 |
| 500 | ⊔ | ⊔ | ‡a"Space Physics Laboratory Project 8608." |
| 500 | ⊔ | ⊔ | ‡a"AD0669063 (from http://www.dtic.mil)." |
| 500 | ⊔ | ⊔ | ‡a"March 1968." |
| 504 | ⊔ | ⊔ | ‡aIncludes bibliographical references (pages 25-26). |
| 520 | ⊔ | ⊔ | ‡aThe advantages of a toroidal plasma containment device are illustrated. Low loss rates are predicted. A toroidal magnetic field is crossed with a multi-cusp magnetic field in configurations predicted by electrolytic tank analog experiments. Three such configurations are described. The first, a relatively simple device with slowly varying fields, showed the inability of the toroidal field to penetrate a plasma and strong cusp field. The second toroid, with moderately fast fields and application of rotational transform principles, produced plasma-field separation, as evidenced by a hot, relatively dense plasma contained in a central region of reduced cusp field strength. The third toroid, featuring the fastest rising fields, produced similar though more pronounced results, including a three fold compression of a plasma heated to over 15 eV, with containment times on the order of 20 microsec. (Author). |
| 538 | ⊔ | ⊔ | ‡aMode of access: Internet. |
| 650 | ⊔ | 0 | ‡aPinch effect (Physics) |
| 650 | ⊔ | 0 | ‡aMagnetic fields. |
| 650 | ⊔ | 0 | ‡aPlasma confinement devices. |
| 650 | ⊔ | 0 | ‡aPlasma confinement. |
| 700 | 1 | ⊔ | ‡aLevine, Morton A., ‡eauthor. |
| 700 | 1 | ⊔ | ‡aCombes, Lewis S., ‡eauthor. |
| 710 | 2 | ⊔ | ‡aAir Force Cambridge Research Laboratories (U.S.) |
| 730 | 0 | ⊔ | ‡aTechnical Report Archive & Image Library (TRAIL) |
| 899 | ⊔ | ⊔ | ‡a39015095294909 |
| CID | ⊔ | ⊔ | ‡a102766424 |
| DAT | 0 | ⊔ | ‡b20230928000000.0 |
| DAT | 1 | ⊔ | ‡a20230928062550.0 ‡b2023-12-31T18:41:09Z |
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