pith. sign in

Reduce dimensional quantum criticality for Non-Fermi liquids

1 Pith paper cite this work. Polarity classification is still indexing.

1 Pith paper citing it
abstract

We present a reduced dimension theoretical framework for studying quantum field theories at finite density, providing a tractable model for investigating non-Fermi liquid (NFL) behavior near quantum phase transitions. Our approach departs from the standard paradigm by placing bosons and fermions in different spatial dimensions: bosonic fields reside in a $(d+1)$-dimensional bulk, while fermionic fields are confined on a $d$-dimensional boundary. This dimensional separation significantly simplifies the renormalization group (RG) analysis of gapless boson-fermion coupling. We demonstrate that the tree-level boson exchange contributions, which typically exhibit logarithmic divergences, become finite in our reduced-dimension scheme. Furthermore, the $\log^2$ and $\log^3$ divergences that characterize 1-loop four-fermion interactions in conventional treatments are reduced to logarithmic divergences within this framework, substantially improving the convergence properties of the perturbative expansion and allowing controlled theoretical analysis of NFL physics.

years

2026 1

verdicts

UNVERDICTED 1

clear filters

representative citing papers

Reduce dimensional quantum criticality for Non-Fermi liquids

cond-mat.str-el · 2026-06-01 · unverdicted · novelty 6.0

A reduced-dimension model places bosons in (d+1) dimensions and fermions in d dimensions to make perturbative RG analysis of NFL physics more tractable by taming logarithmic and higher divergences.

citing papers explorer

Showing 1 of 1 citing paper after filters.

  • Reduce dimensional quantum criticality for Non-Fermi liquids cond-mat.str-el · 2026-06-01 · unverdicted · none · ref 1 · internal anchor

    A reduced-dimension model places bosons in (d+1) dimensions and fermions in d dimensions to make perturbative RG analysis of NFL physics more tractable by taming logarithmic and higher divergences.