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Line 7: However, their model does not account for the [[chiral]] coupling between the [[fermions]] and the SU(2) [[gauge bosons]] in the [[standard model]]. For strings labeled by the positive integers, string-nets are the [[spin network]]s studied in [[loop quantum gravity]]. This has led to the proposal by Levin and Wen,<ref>{{cite journal \|title=Photons and electrons as emergent phenomena \|first1=Michael \|last1=Levin \|first2=Xiao-Gang \|last2=Wen \|journal=Rev. Mod. Phys. \|volume=77 \|pages=871–879 [878] \|date=2005 \|quote=loop quantum gravity appears to be a string net condensation … \|doi=10.1103/RevModPhys.77.871 \|arxiv=cond-mat/0407140 \|s2cid=117563047 }}</ref> and Smolin, Markopoulou and Konopka<ref>{{cite arXiv \|eprint=hep-th/0611197 \|quote=We argue (but do not prove) that under certain conditions the spins in the system can arrange themselves in regular, lattice-like patterns at low temperatures. \|first1=Tomasz \|last1=Konopka \|first2=Fotini \|last2=Markopoulou \|first3=Lee \|last3=Smolin \|title=Quantum Graphity \|date=2006}}</ref> that loop quantum gravity's spin networks can give rise to the [[standard model]] of [[particle physics]] through this mechanism, along with [[fermi statistics]] and [[gauge bosons\|gauge interactions]]. To date, a rigorous derivation from LQG's spin networks to Levin and Wen's spin lattice has yet to be done, but the project to do so is called [[~~Event symmetry#Quantum_graphity_and_other_random_graph_models\|~~quantum graphity]], and in a more recent paper, Tomasz Konopka, [[Fotini Markopoulou]], [[Simone Severini]] argued that there are some similarities to spin networks (but not necessarily an exact equivalence) that gives rise to U(1) gauge charge and electrons in the string net mechanism.<ref>{{cite journal \|title=Quantum graphity: A model of emergent locality \|first1=Tomasz \|last1=Konopka \|first2=Fotini \|last2=Markopoulou \|first3=Simone \|last3=Severini \|journal=Phys. Rev. D \|volume=77 \|issue=10 \|page=19 \|date=May 2008 \|doi=10.1103/PhysRevD.77.104029 \|arxiv=0801.0861 \|bibcode=2008PhRvD..77j4029K \|s2cid=6959359 \|quote=The characterization of the string-condensed ground state is diﬃcult but its excitations are expected to be that of a U(1) gauge theory, … The two main diﬀerences between this model and the original string-net condensation model proposed by Levin and Wen are that in the present case the background lattice is dynamical and has hexagonal rather than square plaquettes.}}</ref> [[Herbertsmithite]] may be an example of string-net matter.<ref name=eureka>{{cite web\|last=Bowles\|first=Claire\|title=Have researchers found a new state of matter?\|url=http://www.eurekalert.org/pub_releases/2007-03/ns-hrf031407.php\|publisher=Eureka Alert\|accessdate=29 January 2012}}</ref><ref name=newscientist>{{cite journal\|last=Merali\|first=Zeeya\|title=The universe is a string-net liquid\|journal=New Scientist\|date=2007-03-17\|volume=193\|issue=2595\|pages=8–9\|url=https://www.newscientist.com/article/mg19325954.200\|accessdate=29 January 2012\|doi=10.1016/s0262-4079(07)60640-x}}</ref>

String-net liquid: Difference between revisions