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Crystal structure, T-P phase diagram and magnetotransport properties of new organic metal Crystal structure, T-P phase diagram and magnetotransport properties.

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Presentation on theme: "Crystal structure, T-P phase diagram and magnetotransport properties of new organic metal Crystal structure, T-P phase diagram and magnetotransport properties."— Presentation transcript:

1 Crystal structure, T-P phase diagram and magnetotransport properties of new organic metal Crystal structure, T-P phase diagram and magnetotransport properties of new organic metal  -(BETS) 2 Mn[N(CN) 2 ] 3 Vladimir Zverev 1, Nataliya Kushch 2, Eduard Yagubskii 2, Lev Buravov 2, Salavat Khasanov 1, Rimma Shibaeva 1, Mark Kartsovnik 3, and Werner Biberacher 3 1 Institute of Solid State Physics, Chernogolovka 2 Institute of Problems of Chemical Physics, Chernogolovka 3 Walther-Meissner-Institut, Bayerishe Akademie der Wissenschaften, Garching, Germany

2 Crystal structure, T-P phase diagram and magnetotransport properties of new organic metal Crystal structure, T-P phase diagram and magnetotransport properties of new organic metal  -(BETS) 2 Mn[N(CN) 2 ] 3 Electrical conductivity is provided by an organic radical cation subsystem We deal with hybrid multifunctional molecular material combining conducting and magnetic properties in the same crystal lattice. Magnetism is provided by an anionic subsystem, containing magnetic transition metal (Mn).

3 a b Crystal structure of  -(BETS) 2 Mn[N(CN) 2 ] 3 projected on the ac- plane (a); Projection of the anion layer on the bc-plane (b) The structure is characterized by the alternation of  -type cation layers with polymeric anion layers along the a axis. In the anion layer, each Mn 2+ ion has an octahedral coordination and is linked with six neighboring Mn 2+ ions via N(CN) 2 - bridges.

4 Y Y +q+q -q-q (0 1 -3) (0 -1 -3) q = 0.42 b*  -(BETS) 2 Mn[N(CN) 2 ] 3 T = 90K Diffraction pattern in the (a*,b*) plane. The arrows indicate on the satellite reflections. 1-D section of the diffraction pattern along the line Y = kb* - 3c* There is a phase transition near 102 K resulting in the formation of incommensurate superstructure: below 102K X-ray diffraction patterns show weak satellite reflections which can be described by the incommensurate wave vector q = 0.42b*. This superstructure survives down to 15 K!

5 Y  -(BETS) 2 Mn[N(CN) 2 ] 3 T = 90K Diffraction pattern in the (a*,b*) plane. The arrows indicate on the satellite reflections. There is a phase transition near 102 K resulting in the formation of incommensurate superstructure: below 102K X-ray diffraction patterns show weak satellite reflections which can be described by the incommensurate wave vector q = 0.42b*. This superstructure survives down to 15 K!

6 Temperature dependence of the interplane resistance of  -(BETS) 2 Mn[N(CN) 2 ] 3 crystal at ambient pressure

7 Temperature dependence of the interplane resistance of  -(BETS) 2 Mn[N(CN) 2 ] 3 crystal at ambient pressure The M-I transition takes place in electron subsystem because at T=T M-I there are no changes in the X-ray crystal structure!

8 Susceptibility  in  -(BETS) 2 [Mn(N(CN) 2 ) 3 ]

9 There is no peculiarity on  (T) dependence at T M-I

10 Susceptibility  in  -(BETS) 2 [Mn(N(CN) 2 ) 3 ] There is no peculiarity on  (T) dependence at T M-I But in 1 H NMR and torque experiments there are some peculiarities indicating to the formation of a short-range order of Mn spins at T M-I ! See Oleg Vyaselev’s Poster!

11 Pressure induced metal-insulator and superconductor-insulator transitions in  -(BETS) 2 Mn[N(CN) 2 ] 3

12 T – P phase diagram Superconducting and insulating phases coexist at (0.4 < P < 0.5) kbar.

13 Shubnikov – de Haas oscillations

14

15 SdH oscillations in 1/B scale

16 Temperature dependence of SdH oscillation amplitude

17 Pressure dependences of SdH oscillation frequency and the cyclotron mass

18 Energy spectrum and the Fermi- surface (extended Hückel method) The SdH oscillation frequency corresponds to about 1.5% of the BZ cross section.

19 Y Y +q+q -q-q (0 1 -3) (0 -1 -3) q = 0.42 b*  -(BETS) 2 Mn[N(CN) 2 ] 3 T = 90K Diffraction pattern in the (a*,b*) plane. The arrows indicate on the satellite reflections. 1-D section of the diffraction pattern along the line Y = kb* - 3c* There is a phase transition near 102 K resulting in the formation of incommensurate superstructure: below 102K X-ray diffraction patterns show weak satellite reflections which can be described by the incommensurate wave vector q = 0.42b*. This superstructure survives down to 15 K!

20 Energy spectrum and the Fermi- surface (extended Hückel method) The SdH oscillation frequency corresponds to about 1.5% of the BZ cross section. The small pocket may arise due to the existence of the superstructure! q=0.42b*

21 Conclusions Crystal structure and magnetotransport properties of new organic metal  -(BETS) 2 Mn[N(CN) 2 ] 3 were studied. A phase transition near 102 K resulting in the formation of incommensurate superstructure below 102K was found. At T  27K a structureless phase transition in electron system was observed at ambient pressure. A moderate pressure P  0.5 kbar suppresses the metal-insulator transition and the compound becomes metallic down to low temperatures and superconducting with T c = 5.8 K. T-P phase diagram was plotted in the pressure range 0-2.5 kbar. In the metallic state Shubnikov-de Haas oscillations which could be related to the small pockets of the FS were observed.

22 Temperature dependence of the interplane resistance of  -(BETS) 2 Mn[N(CN) 2 ] 3 crystal at ambient pressure


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