Neutron low-temperature (4 and 20 K) and X-ray high-pressure (6.5 x 10² and 9.8 x 10² MPa) structures of the organic superconductor di(2,3,6,7-tetramethyl-1,4,5,8-tetraselenafulvalenium) hexafluorophosphate, (TMTSF)₂PF₆

Abstract: The Bechgaard salts (TMTSF)2X (with X a small centro-or non-centrosymmetric anion) show several kinds of ground states, in particular a superconducting one at low temperatures (T

“…It shows that the PF 6 -D12 lattice parameters are larger than those for PF 6 -H12. The 4 K lattice parameters of PF 6 -D12 are comparable to those of PF 6 -H12 at 120 K. 23 Using the low-temperature compressibility of PF 6 -H12, 37 one deduces that the increase of volume of PF 6 -D12 corresponds to the application of a negative pressure of 500 MPa to PF 6 -H12 at 4 K. This is a much larger effect than the one revealed for κ-(BEDT-TTF) 2 Cu[N(CN) 2 ]Br where deuteration corresponds to the application of a negative pressure of about 40 MPa to the hydrogenated salt. 3 As for the PF 6 -H12 salt, the structural refinement of PF 6 -D12 shows that both CD 3 methyl groups and the PF 6 anions are ordered at 4 K. The thermal parameters [U(eq) in Table III] of the P, F, Se, and C atoms (nuclei) of the PF 6 -D12 salt are comparable to those previously determined in PF 6 -H12.…”

“…3 As for the PF 6 -H12 salt, the structural refinement of PF 6 -D12 shows that both CD 3 methyl groups and the PF 6 anions are ordered at 4 K. The thermal parameters [U(eq) in Table III] of the P, F, Se, and C atoms (nuclei) of the PF 6 -D12 salt are comparable to those previously determined in PF 6 -H12. 23 U(eq) of D is however 50% larger than U(eq) of H, which means that D undergoes larger quantum fluctuations than H. This result is surprising because D has a mass twice larger than that of H. It is tempting to assign this effect to the presence of smaller potential barriers for quantum tunneling in PF 6 -D12 than in PF 6 -H12. In addition, as for PF 6 -H12 and despite the fact that the PF 6 anion is well localized in the 4 K structure, Table III shows that U(eq) for F is three times larger than the U(eq) for the central P atom of the anion.…”

“…Both anion and methyl-group disorders are progressively removed upon cooling. In particular, the refinement of the 20 K and 4 K neutron-scattering structural data of hydrogenated (TMTSF) 2 PF 6 (named PF 6 -H12 below) 23 show that each anion locks its orientation by establishing two short F-Se contact distances and four F. . .H-CH 2 bonds with four neighboring TMTSF molecules located in a plane nearly perpendicular to a.…”

Low-temperature structural effects in the (TMTSF)2PF6and AsF6Bechgaard salts

“…It shows that the PF 6 -D12 lattice parameters are larger than those for PF 6 -H12. The 4 K lattice parameters of PF 6 -D12 are comparable to those of PF 6 -H12 at 120 K. 23 Using the low-temperature compressibility of PF 6 -H12, 37 one deduces that the increase of volume of PF 6 -D12 corresponds to the application of a negative pressure of 500 MPa to PF 6 -H12 at 4 K. This is a much larger effect than the one revealed for κ-(BEDT-TTF) 2 Cu[N(CN) 2 ]Br where deuteration corresponds to the application of a negative pressure of about 40 MPa to the hydrogenated salt. 3 As for the PF 6 -H12 salt, the structural refinement of PF 6 -D12 shows that both CD 3 methyl groups and the PF 6 anions are ordered at 4 K. The thermal parameters [U(eq) in Table III] of the P, F, Se, and C atoms (nuclei) of the PF 6 -D12 salt are comparable to those previously determined in PF 6 -H12.…”

“…3 As for the PF 6 -H12 salt, the structural refinement of PF 6 -D12 shows that both CD 3 methyl groups and the PF 6 anions are ordered at 4 K. The thermal parameters [U(eq) in Table III] of the P, F, Se, and C atoms (nuclei) of the PF 6 -D12 salt are comparable to those previously determined in PF 6 -H12. 23 U(eq) of D is however 50% larger than U(eq) of H, which means that D undergoes larger quantum fluctuations than H. This result is surprising because D has a mass twice larger than that of H. It is tempting to assign this effect to the presence of smaller potential barriers for quantum tunneling in PF 6 -D12 than in PF 6 -H12. In addition, as for PF 6 -H12 and despite the fact that the PF 6 anion is well localized in the 4 K structure, Table III shows that U(eq) for F is three times larger than the U(eq) for the central P atom of the anion.…”

“…Both anion and methyl-group disorders are progressively removed upon cooling. In particular, the refinement of the 20 K and 4 K neutron-scattering structural data of hydrogenated (TMTSF) 2 PF 6 (named PF 6 -H12 below) 23 show that each anion locks its orientation by establishing two short F-Se contact distances and four F. . .H-CH 2 bonds with four neighboring TMTSF molecules located in a plane nearly perpendicular to a.…”

Low-temperature structural effects in the (TMTSF)2PF6and AsF6Bechgaard salts

“…The first one comes from X-ray and neutron measurements which have provided accurate values for the structural parameters of these compounds [4]. Using them as inputs, quantum chemistry calculations [5] have provided values for various hopping integrals, in particular for the hopping integrals along the stacks tl and t2, for a few compounds (see table 1).…”

One-dimensional electronic properties of the Bechgaard salts

“…Some examples of such studies are known. For example, high-pressure and low-temperature compressions were shown to have similar effects on the structure of an organic superconductor di (2,3,6,7-tetramethyl-1,4,5,8-tetraselenafulvalenium) hexafluorophosphate (Gallois, Gaultier, Hauw, Lamcharfi & Filhol, 1986). However, in general, comparative studies of anisotropic strain induced in the same structure by different actions are still rare.…”

Distortion of Crystal Structures of Some Co^III Ammine Complexes. I. Distortion of Crystal Structure of [Co(NH₃)₅NO₂]Cl(NO₃) on Cooling