doi: 10.1038/s41598-017-13118-4.
Charge and Lattice Fluctuations in Molecule-Based Spin Liquids
Affiliations
- PMID: 29018228
- PMCID: PMC5635065
- DOI: 10.1038/s41598-017-13118-4
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Charge and Lattice Fluctuations in Molecule-Based Spin Liquids
Sci Rep.
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Abstract
Spin liquid (SL) systems have been the subject of much attention recently, as they have been theoretically predicted to not freeze, even at 0 K. Despite extensive searches being made for such a system, only a few candidates have been found. All of these candidates share geometrical frustrations that are based on triangular lattices. We applied vibrational spectroscopy to one of the candidates of a molecule-based SL system, and we compared its results against three antiferromagnetic compounds and four charge-ordered compounds. All of their structural motifs belong to triangular lattices. The C=C stretching modes in the SL state indicated that there were charge and lattice fluctuations. These fluctuations were suppressed but non-negligible in the AF compounds. This finding is potentially significant, as it indicates that a hidden lattice and charge fluctuation are the driving force of a geometrical frustration, which eventually leads to a SL state.
Conflict of interest statement
The authors declare that they have no competing interests.
Figures
Molecular structure, crystal structure and schematic views of two-dimensional layers of β′–EtMe3Sb[Pd(dmit)2]2 (Sb-salt 2). (a) Monomer of Pd(dmit)2. (b) Crystal structure as viewed along the b-axis. (c) Two equivalent conducting layers with different orientations; layer 1 and layer 2. t
d, t
s and t
t denote the transfer integrals between neighboring dimers in the diagonal, stacking and transverse directions, respectively. (d) Schematic views of the two-dimensional layers.
Correlation diagram of C=C stretching modes in monomers, dimers, tetramers and octamers that have centre of inversion symmetries. The tetramers and octamers are composed of two and four dimers, respectively. The C=C stretching modes of the monomers and dimers are shown by the arrows. AD–DD: C=C stretching modes of a dimer, AT1–DT2: C=C stretching modes of a tetramer, and AO1–DO4: C=C stretching modes of an octamer. The positive and negative signs for each vibrational mode denote in-phase and out-of-phase vibrations, respectively. These C=C stretching modes are classified into Groups A–D. AR-DIR in the right column correspond to peaks in Fig. 3. CO4 denoted by the blue area is independent of any C=C stretching modes of tetramer and dimer. AIR and DIR, denoted by green area, consist of C=C stretching modes of tetramer and octamer, but these are independent of any C=C stretching modes of dimer. AIR consists of the AT2 and AO3 modes, and DIR consists of the DT2 and DO3 modes. AR, CIR, BIR and DR, denoted by orange area, consist of C=C stretching modes of dimer, tetramer and octamer. AR consists of the AD, AT1 and AO1 modes, CIR consists of the CD, CT1 and CO1 modes, BIR consists of the BD, BT1, BO1 and BO4 modes, and DR consists of the DD, DT1, DO1 and DO4 modes.
IR and Raman spectra. (a) a-polarized IR spectra for Sb-salt 2. (b) b-polarized IR spectra for Sb-salt 2. (c) c*-polarized IR spectra of P-salt 1, Sb-salt 1 and Sb-salt 2. The a-polarized IR spectra of P-salt 2 is also shown in (c). (d) Raman spectra observed at 5 K. Aside from Sb-salt 2, all of the salts here have antiferromagnetic ground states. All of the IR spectra were obtained as conductivity spectra from the Kramers–Kronig transformation of the corresponding reflectance spectra.
HOMO–LUMO inversion, and charge distributions and bond alternations in a 2D layer of X[Pd(dmit)2]2. (a) Energy diagram of the monomers, normal dimer, and tight dimer. “L” and “H” represent the LUMO and HOMO of a monomer, respectively. The sum (+) and subtraction (−) between them designate bonding and antibonding interactions, respectively. (b) and (c): Two of three different CO states revealed by our previous works. (d): Layer consisting of regularly arranged [dimers]−. (e): Legend of electron densities of monomers in (b–d). The black, grey and white sections in the monomers of (b–d) denote the electron densities in the HOMO of (b) [tetramer]2−, (c) [octamer]4− and (d) [dimer]−. Different patterns of the inter-dimer bond alternations; the bold, thin and dotted lines between the dimers denote the strong, intermediate and weak inter-dimer interactions, respectively, between the HOMOs in (b) [tetramer]2− and (c) [octamer]4−. The interacting monomers that form tetramers or octamers in (b) and (c) are highlighted by the orange rectangles. Inter-dimer VBOs in (b) are formed along two of three directions in the triangular lattice. Intra-dimer charge separation in (b) is accompanied by inter-dimer VBOs. The intra-dimer interaction in a charge-rich dimer of (c) is weaker than that in a charge-poor dimer, which manifests itself as the intra-dimer VBO. Inter-dimer VBOs are also formed in (c). Intra- and inter-dimer charge separations of (c) are accompanied by inter- and intra-dimer VBOs, respectively. The combination between intra- and inter-dimer VBOs is formed along one of the three directions. There is no VBO in (d).
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