Superprizolatorsko stanje je po prvi put eksperimentalno uoceno pre svega
nekoliko godina. Za elektrotehnicke primene, najznacajnija osobina superizolatora je
beskonacna elektricna otpornost. Superizolatorsko stanje moguce je shvatiti kao dualno
superprovodnom, pri cemu oba opstaju samo do odredenih kriticnih vrednosti ista tri
parametra: temperature, primenjenog napona i jacine magnetnog polja. Moguce primene
superizolatora su za izolaciju kablova (pogotovo superprovodnih kablova, cija
konstrukcija podrazumeva hladenje do niskih temperatura na kojima se održavaju i
superprovodno i superizolatorsko stanje), galvanskih elemenata (cime bi gubici usled
struja curenja mogli da se svedu na zanemarljiv nivo) i komponenti u tehnologiji
integrisanih kola (što bi omogucilo izradu znatno tanjih dielektricnih slojeva).
Nakon razmatranja opštih karakteristika izolatorskih materijala i osobina
superprovodnog stanja, u radu je dat opis mikroskopskih i makroskopskih karakteristika
superizolatorske fa...ze. Detaljno su razmotreni efekti zracenja na materijale, u zavisnosti
od vrste zracenja i osobina materijalne sredine kroz koju ono prolazi. Posebna pažnja
posvecena je interakciji zracenja sa izolatorskim materijalima, sa naglaskom na
radijaciona oštecenja u cvrstim izolatorima.
Izloženi su principi Monte Carlo metoda simulacije prolaska zracenja kroz
materijal, koje se zasnivaju na numerickoj simulaciji slucajnih velicina na osnovu
poznatih raspodela.
Prikazani su rezultati numerickih simulacija dejstva zracenja na analizirane
superizolatorske filmove, kojim su obuhvaceni gubici energije upadnog zracenja putem
jonizacije, fononskog pobudivanja rešetke i izmeštanja atoma materijala. Numericka
simulacija sporvedena u radu dovedena je u vezu sa teorijskim modelom
superizolatorske faze, uzimajuci u obzir sve specificnosti ovog stanja. Uoceno je da
svaki od tri vida deponovanja energije zracenja u superizolatorima dovodi do
specificnih promena njegovih fizickih osobina, koje mogu da budu prolazne ili trajne.
Efekti zracenja razmatrani su sa stanovišta strukturnih promena unutar ispitivanih
filmova, kao i promena elektricnih osobina, kao što su specificna elektricna otpornost i
strujno-naponska karakteristika. Radijacione promene su uporedene za razne tipove
zracenja i debljine filmova superizolatorskih materijala...
Superinsulating state was experimentally observed for the first time only a couple
of years ago. The most important property of superinsulators, for their use in electrical
engineering, is the infinite electrical resistance. The superinsulating state can be viewed
as being dual to the superconducting one, with both states subsisting only below certain
critical values of the same three parameters: temperature, applied voltage, and magnetic
field strength. Possible applications of superinsulators are for cable insulation
(especially of superconducting cables that have to be cooled to low temperatures, at
which both the superconducting and the superinsulating state can exist), insulation of
galvanic elements (for reducing leakage current losses to a negligible level), and
insulation of components in integrated circuit technology (which could make dielectric
layers even thinner).
After surveying general characteristics of insulating materials and the properties of
the superconducting state..., the dissertation provides a description of microscopic and
macroscopic characteristics of the superinsulating phase. A detailed review of radiation
effects in materials is included, depending on the type of radiation and the properties of
the medium it traverses. Special attention is given to the interaction of radiation with
insulating materials, emphasizing radiation damage in solid state insulators.
The principles of using Monte Carlo methods for simulating the passage of
radiation through matter are represented.
Results of numerical simulations of radiation effects in the analyzed
superinsulating films are presented. Simulated radiation transport included incident
radiation energy losses through ionization, phonon excitation, and atom displacement.
The conducted numerical simulation was linked to the theoretical model of the
superinsulating phase, taking account of all the specific traits of this state. It was noted
that all three modes of radiation energy deposition in superinsulators bring about either
transient or permanent changes of their properties. Radiation effects were considered
with respect to structural changes within the investigated films, as well as the changes
of electrical properties, such as the specific electrical resistance and the current-voltage
characteristic. Radiation-induced changes were compared for various types of radiation
and different superinsulating film thicknesses...
Факултет:
Универзитет у Београду, Електротехнички факултет
Датум одбране:
11-06-2012
Кључне речи:
superizolatori / superinsulators / superprovodnici / zracenje / radijacioni efekti / jonski snop / Monte Carlo metoda / numericka simulacija / superconductors / radiation / radiation effects / ion beam / Monte Carlo method / simulation
