2001
DOI: 10.1038/35078016
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An unusual phase transition to a second liquid vortex phase in the superconductor YBa2Cu3O7

Abstract: A magnetic field penetrates a superconductor through an array of 'vortices', each of which carries one quantum of flux that is surrounded by a circulating supercurrent. In this vortex state, the resistivity is determined by the dynamical properties of the vortex 'matter'. For the high-temperature copper oxide superconductors (see ref.1 for a theoretical review), the vortex phase can be a 'solid', in which the vortices are pinned, but the solid can 'melt' into a 'liquid' phase, in which their mobility gives ris… Show more

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Cited by 109 publications
(148 citation statements)
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“…The vicinity of such a critical point to T g could provide another explanation for the extreme heat capacity of the vortex glass former. Indeed, interesting features have been observed recently in the vortex matter phase diagram of hightemperature superconductors, such as inverse melting below a Kauzmann point 24,28 and evidence for a liquid-liquid transition in its vicinity 14 . These might be related to the features observed in structural glasses.…”
Section: Discussionmentioning
confidence: 99%
See 1 more Smart Citation
“…The vicinity of such a critical point to T g could provide another explanation for the extreme heat capacity of the vortex glass former. Indeed, interesting features have been observed recently in the vortex matter phase diagram of hightemperature superconductors, such as inverse melting below a Kauzmann point 24,28 and evidence for a liquid-liquid transition in its vicinity 14 . These might be related to the features observed in structural glasses.…”
Section: Discussionmentioning
confidence: 99%
“…1 and the above discussion about T K in the vortex matter in HTSCs. With the introduction of random vortex pinning defects, however, the first-order melting transition vanishes and is replaced by a more continuous transition 4,[11][12][13][14] , commonly referred to as the 'vortex-glass' transition. There is evidence for different glassy phases (Bose glass, Bragg Glass and vortex glass) 4 , the detailed nature of which however remains controversial.…”
mentioning
confidence: 99%
“…Experimental results suggest that an increase in temperature above a certain critical value T m determines the transition to a liquid phase, [5][6][7] while the effects of disorder associated with high magnetic fields are responsible for the insurgence of a glassy phase. [8][9][10] A deep theoretical understanding of such transition phenomena, accounting for their microscopic origin, has not been achieved yet.…”
Section: Grain-boundary-induced Meltingmentioning
confidence: 99%
“…As in conventional matter strong enough fluctuations destroy longrange order: when temperature is raised the vortex lattice melts into a vortex liquid. [5][6][7] Fluctuations are also provided by quenched disorder that is intrinsically present in these materials, leading to complex glassy phases. [8][9][10][11][12][13] While several experimental methods have been used to investigate vortex matter, a direct image of the geometrical and topological properties of the vortices can be obtained by the Bitter decoration technique.…”
Section: Introductionmentioning
confidence: 99%
“…In particular, much experimental and theoretical effort has been devoted to characterizing the phase diagram of type II superconductors [4]. Depending on the value of the magnetic field H, temperature T , and sample preparation, vortices can either form a crystal [5], which at higher temperatures melts into a liquid [6,7,8,9], or, due to quenched disorder, they can be found in more complex phases, such as the vortex glass [10], the Bose glass [11] or the Bragg glass [12,13]. Of special importance is the non-equilibrium response of vortex matter to the flow of an external current [14,15], because the dissipative motion of the vortices induces an undesirable macroscopic resistance.…”
mentioning
confidence: 99%