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      <dc:title>Phase transitions and diversification in complex systems: The role of heterogeneites, adaptation a other essencial aspects of real systems</dc:title>
      <dc:creator>Villa Martín, Paula</dc:creator>
      <dc:contributor>Muñoz Martínez, Miguel Ángel</dc:contributor>
      <dc:contributor>Universidad de Granada. Departamento de Electromagnetismo y Física de la Materia</dc:contributor>
      <dc:subject>Física estadística</dc:subject>
      <dc:subject>Transformaciones de fase (Física estadística)</dc:subject>
      <dc:subject>Probabilidades</dc:subject>
      <dc:subject>Conjuntos difusos</dc:subject>
      <dc:subject>Análisis de sistemas</dc:subject>
      <dc:subject>Dinámica de sistemas</dc:subject>
      <dc:subject>Termodinámica</dc:subject>
      <dc:subject>Mecánica estadística</dc:subject>
      <dc:subject>Procesos estocásticos</dc:subject>
      <dc:subject>Heterogeneidad ecológica</dc:subject>
      <dc:description>Let us summarize the main issues treated in the different chapters of this thesis.&#xd;
In chapter 1 basic concepts needed in this thesis are summarized. Firstly, main&#xd;
features of continuous and discontinuous phase transitions are presented in order to a&#xd;
correct distinction between them (section 1.1). Then, prototypical models presenting&#xd;
these types of transition are described and analyzed in section 1.2.&#xd;
In chapter 2, we study the importance of demographic stochasticity and diffusion&#xd;
in a generic system subjected to a discontinuous transition in the mean-field approach. We investigate how the order of the transition would surprisingly depend&#xd;
on such mechanisms. Beside this, we also study the the unavoidable presence of&#xd;
spatial heterogeneity in real systems. In this case, a rounding phenomenon for low dimensional&#xd;
systems appears. The ideas presented here can help to further understand&#xd;
discontinuous transitions, and contribute to the discussion about the possibility of&#xd;
preventing these shifts in order to minimize their disruptive ecological, economic, and&#xd;
societal consequences.&#xd;
For a deeper understanding of some of the previous results, in chapter 3 we&#xd;
present a more technical and detailed study of the effect of spatial heterogeneity on&#xd;
a prototypical model exhibiting a discontinuous transition. Here we try to explain&#xd;
how, in analogy with what happens in problems of thermodynamic equilibrium, the&#xd;
existence of some form of spatial disorder implies that potentially discontinuous transitions&#xd;
are rounded-off, thus making the system critical (at low dimensions).&#xd;
In this context, in chapter 4 we wonder whether a structurally (and so spatially)&#xd;
disordered system would also present the same smoothing effect. An extensive&#xd;
analysis of all possible systems presenting this structural heterogeneity may constitute&#xd;
a thesis itself. As a consequence, we focus on the brain cortex, a system that is&#xd;
well described by models exhibiting discontinuous transitions at mean-field and which&#xd;
presents a complex and known network structure. Interestingly, criticality appears for&#xd;
small topological dimensions and so, a compatibility of integrative models of neural&#xd;
activity (exhibiting discontinuous transitions in mean-field), and the critical features&#xd;
experimentally measured in the cortex, is accomplished.&#xd;
The above chapters do not consider any type of mutation or variation of its individuals&#xd;
due to the fact that, in those cases, evolution usually takes place in longer&#xd;
times than the considered ones. However, apart from the previous inherent properties,&#xd;
adaptation is an essential feature of real systems. What would it happen if&#xd;
individuals rapidly evolve affecting community dynamics? In chapter 5 we propose a relatively simple computational eco-evolutionary model&#xd;
specifically devised to describe rapid phenotypic diversification in a particular experiment&#xd;
of species-rich communities [236]. Despite this, the model is easily generalizable&#xd;
to analyze different eco-evolutionary problems within a relatively simple and unified&#xd;
computational framework. We show that it captures the main phenomenology observed&#xd;
experimentally, and it also makes non-trivial predictions. Although, unlike it&#xd;
was awaited, no phase transition from poor to rich communities appear, in future we&#xd;
will investigate the needed mechanisms for which this phase transition occurs.&#xd;
Finally, thesis conclusions are presented in chapter chapter 6.</dc:description>
      <dc:date>2017-03-27T11:16:05Z</dc:date>
      <dc:date>2017-03-27T11:16:05Z</dc:date>
      <dc:date>2017</dc:date>
      <dc:date>2017-02-24</dc:date>
      <dc:type>info:eu-repo/semantics/doctoralThesis</dc:type>
      <dc:identifier>Villa Martín, P. Phase transitions and diversification in complex systems: Tthe role of heterogeneites, adaptation a other essencial aspects of real systems. Granada: Universidad de Granada, 2017. [http://hdl.handle.net/10481/45496]</dc:identifier>
      <dc:identifier>9788491631576</dc:identifier>
      <dc:identifier>http://hdl.handle.net/10481/45496</dc:identifier>
      <dc:language>eng</dc:language>
      <dc:rights>http://creativecommons.org/licenses/by-nc-nd/3.0/</dc:rights>
      <dc:rights>info:eu-repo/semantics/openAccess</dc:rights>
      <dc:rights>Creative Commons Attribution-NonCommercial-NoDerivs 3.0 License</dc:rights>
      <dc:publisher>Universidad de Granada</dc:publisher>
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