Critical exponents and scaling invariance in the absence of a critical point
The paramagnetic-to-ferromagnetic phase transition is believed to proceed through a critical point, at which power laws and scaling invariance, associated with the existence of one diverging characteristic length scale -- the so called correlation length -- appear. We indeed observe power laws and s...
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Zusammenfassung: | The paramagnetic-to-ferromagnetic phase transition is believed to proceed
through a critical point, at which power laws and scaling invariance,
associated with the existence of one diverging characteristic length scale --
the so called correlation length -- appear. We indeed observe power laws and
scaling behavior over extraordinarily many decades of the suitable scaling
variables at the paramagnetic-to-ferromagnetic phase transition in ultrathin Fe
films. However, we find that, when the putative critical point is approached,
the singular behavior of thermodynamic quantities transforms into an analytic
one: the critical point does not exist, it is replaced by a more complex phase
involving domains of opposite magnetization, below as well as $above$ the
putative critical temperature. All essential experimental results are
reproduced by Monte-Carlo simulations in which, alongside the familiar exchange
coupling, the competing dipole-dipole interaction is taken into account. Our
results imply that a scaling behavior of macroscopic thermodynamic quantities
is not necessarily a signature for an underlying second-order phase transition
and that the paramagnetic-to-ferromagnetic phase transition proceeds, very
likely, in the presence of at least two long spatial scales: the correlation
length and the size of magnetic domains. |
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DOI: | 10.48550/arxiv.1410.7686 |