%0 Journal Article %1 PhysRevB.102.054408 %A Schäfer, Robin %A Hagymási, Imre %A Moessner, Roderich %A Luitz, David J. %D 2020 %I American Physical Society %J Phys. Rev. B %K b %N 5 %P 054408 %R 10.1103/PhysRevB.102.054408 %T Pyrochlore S=$\dfrac12$ Heisenberg antiferromagnet at finite temperature %U https://link.aps.org/doi/10.1103/PhysRevB.102.054408 %V 102 %X We use a combination of three computational methods to investigate the notoriously difficult frustrated three-dimensional pyrochlore S = 1/2 aquantum antiferromagnet, at finite temperature T : canonical typicality for a finite cluster of 2 x 2 x 2 unit cells (i.e., 32 sites), a finite-T matrix product state method on a larger cluster with 48 sites, and the numerical linked cluster expansion (NLCE) using clusters up to 25 lattice sites, including nontrivial hexagonal and octagonal loops. We calculate thermodynamic properties (energy, specific heat capacity, entropy, susceptibility, magnetization) and the static structure factor. We find a pronounced maximum in the specific heat at T = 0.57J, which is stable across finite size clusters and converged in the series expansion. At T approximate to 0.25J (the limit of convergence of our method), the residual entropy per spin is 0.47k(B) In 2, which is relatively large compared to other frustrated models at this temperature. We also observe a nonmonotonic dependence on T of the magnetization at low magnetic fields, reflecting the dominantly nonmagnetic character of the low-energy states. A detailed comparison of our results to measurements for the S = 1 material $NaCaNi_2F_7$ yields a rough agreement of the functional form of the specific heat maximum, which in turn differs from the sharper maximum of the heat capacity of the spin ice material $Dy_2Ti_2O_7$.

@article{PhysRevB.102.054408, abstract = {We use a combination of three computational methods to investigate the notoriously difficult frustrated three-dimensional pyrochlore S = 1/2 aquantum antiferromagnet, at finite temperature T : canonical typicality for a finite cluster of 2 x 2 x 2 unit cells (i.e., 32 sites), a finite-T matrix product state method on a larger cluster with 48 sites, and the numerical linked cluster expansion (NLCE) using clusters up to 25 lattice sites, including nontrivial hexagonal and octagonal loops. We calculate thermodynamic properties (energy, specific heat capacity, entropy, susceptibility, magnetization) and the static structure factor. We find a pronounced maximum in the specific heat at T = 0.57J, which is stable across finite size clusters and converged in the series expansion. At T approximate to 0.25J (the limit of convergence of our method), the residual entropy per spin is 0.47k(B) In 2, which is relatively large compared to other frustrated models at this temperature. We also observe a nonmonotonic dependence on T of the magnetization at low magnetic fields, reflecting the dominantly nonmagnetic character of the low-energy states. A detailed comparison of our results to measurements for the S = 1 material $NaCaNi_2F_7$ yields a rough agreement of the functional form of the specific heat maximum, which in turn differs from the sharper maximum of the heat capacity of the spin ice material $Dy_2Ti_2O_7$.}, added-at = {2020-08-19T11:51:01.000+0200}, author = {Schäfer, Robin and Hagymási, Imre and Moessner, Roderich and Luitz, David J.}, biburl = {https://www.bibsonomy.org/bibtex/25c2bb3301fbde3a9489ccf7456463461/ctqmat}, day = 4, description = {Phys. Rev. B 102, 054408 (2020) - Pyrochlore $S=\frac{1}{2}$ Heisenberg antiferromagnet at finite temperature}, doi = {10.1103/PhysRevB.102.054408}, interhash = {16d98068a55ecfc1c9c38009ed67089c}, intrahash = {5c2bb3301fbde3a9489ccf7456463461}, journal = {Phys. Rev. B}, keywords = {b}, month = {8}, note = {http://arxiv.org/abs/2003.04898}, number = 5, numpages = {20}, pages = 054408, publisher = {American Physical Society}, timestamp = {2023-10-19T13:23:55.000+0200}, title = {Pyrochlore S=$\mathbf{\dfrac{1}{2}}$ Heisenberg antiferromagnet at finite temperature}, url = {https://link.aps.org/doi/10.1103/PhysRevB.102.054408}, volume = 102, year = 2020 }