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Some Igor Schegolev and Chernokolovka Recollections: Igor visited Gor’kov at the NHMFL in the early 90’s: Learned about “Igor” software. -(BEDT-TTF) 2 TlHg(SCN) 4 first material measured at the NHMFL. 20 T at 50 mK*. Some major Chernokolovka physics advances: –FS reconstruction in -(ET) 2 MHg(SCN) 4 –AMRO and its interpretation Due to: Kartsovnik, Kovalev, Shibaeva, Rozenberg, Schegolev, Kushch, Laukhin, Pesotskii, Yakovenko, et al. *Brooks,…Kartsovnick M V, Schegolev A I, et al. 1996 Physica B 216 380
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Selected Paradigm Materials (TMTSF) 2 ClO 4 -(BEDT-TSeF) 2 FeCl 4 S = 5/2 Per 2 [Au(mnt) 2 ] CDW + Pressure: AMRO & SC Per 2 [Pt(mnt) 2 ] (S = ½) Spin Peierls + CDW + Field Phase diagram: NMR & Transport FISDW phase diagram: NMR vs. Transport Mysterious MI-AF transition: Mössbauer studies -(BETS) 2 Fe x Ga 1-x Cl 4-y Br y “alloy studies”
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(Osada et al. - first high field phase diagram, B th, B 1, B 2 ) I.
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Chung 2000 McKernan 1995 Uji 1997 77 Se NMR? Lumata 2008 Is High field T-B phase diagram of (TMTSF) 2 ClO 4 time dependent? Yu 1990 T(K) H(T) Naughton1988 H(T) T(K)
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L. Lumata – simultaneous 77 Se NMR and magnetotransport in (TMTSF) 2 ClO4. Two modes: 1) Fixed angle, change frequency/field 2) Rotation ( ) in b-c plane, fix frequency, change B perp = Bcos( ) a c b B Measure: Spectrum, 1/T 1, and enhancement factor “Metallic pulse”: 12 W @ 1 ns pulse width “SDW pulse”: 12 W @ 500 to 50 ns pulse width V. Mitrovic, Takigawa et al. * 0.21 mm dia. NMR coil
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T = 1.5 K: peak in 1/T 1 occurs at B 1. B1B1 B th B//c, field (frequency) dependent data. Metallic pulses
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“Simultaneous” Resistance and 1/T 1 measurements. Sub-phase boundary clearly shows a change in the nesting condition.
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“Simultaneous” Resistance,1/T 1, and enhancement factor vs. rotation at 14 T. Takahashi et al. B th B1B1 B1B1 B1B1 Works because FISDW is primarily orbital.
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Rotation data at 30 T. B th B1B1 B* B RE
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Main results: 1/T 1 does not peak at the resistive Metal-FISDW transition, but inside the FISDW phase. (Hebel- Slichter like? Theory needed.) “Primitive model”, McKernan et al. SSC 145, 385(2008) appears relevant at “B re ”. Sub-phases clearly seen in NMR. Improved nesting model for all phase transitions needed. Q1Q1 L. L. Lumata: Phys. Rev. B 78, 020407(R)(2008). J. Physics: Conf. Series 132, 012014(2008).
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57 Fe Mossbauer in -BETS 2 FeCl 4 Ga: no magnetic order, superconductivity Fe: AF magnetic order, M-I transition Conventional wisdom: d-electron (Fe 3+, S = 5/2) states drive the AF-MI transition II.
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Interplay of and d electron spins is a complex problem. M: Akutsu et al. Kobayashi et al. Uji Global Phase Diagram: Tuning internal field H J from 0 to 32 T with X: -(BETS) 2 Fe x Ga x-1 Cl 4 B sf via Sasaki et al. Tokumoto et al. Some -d phenomena in -(BETS) 2 FeCl 4 EPR – Rutel, Oshima, et al. H//c Also, magnetoresistance, etc. T MI-AF = 8.3 K
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H -d ~ 4 T. S=5/2 spectrum produces a Schottky C P below T N. “ ’’
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Strategy: look at the Fe 3+ sites directly using Mössbauer spectroscopy Lisbon: 99% 57 Fe enriched TEAFeCl 4 –S. Rabaça Tokyo: Electrochemical crystallization of -(BETS) 2 FeCl 4 –B. Zhou Lisbon: constant-acceleration spectrometer and a 25 mCi 57 Co source in a Rh matrix –J. C. Waerenborgh
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~ 0 57 Fe Mossbauer in -BETS 2 FeCl 4 0 1 & 2 1 & 2 Single Below T MI, we find two sextets corresponding to M s = 5/2 with slightly different B hf values. The sextets merge below 3 K.
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Assume the Fe 3+ spin is in the presence of finite H p-d and that the relaxation is relatively fast. The hyperfine field is: Assume spin wave theory (with linear dispersion for AF order) describes the T-dependence of H -d :
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Experimental and computed hyperfine field B hf and derived H -d field. Waerenborgh et al. arXiv:0909.1096 (PRB-submitted)
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Main results of Mössbauer measurements: 1.Paramagnetic state above T MI 2.Abrupt onset of B hf below T MI. 3.Also paramagnetic below T MI, but now H -d is finite. 4.B hf is temperature dependent, predicts that H -d is also temperature dependent, and reasonably described by AF spin-wave theory. 5.Two Fe sites with different B hf values, with intensity ratio 2:1. Merge below 3 K. Q vector change? Mössbauer and C P appear to agree that Fe 3+ spins do not have long range AF order below T MI, even though the -spin system does. A probe of the spin dynamics, field-dependent C p, and Mössbauer studies would be useful. Also: Theory.
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A brief look at -(BETS) 2 Fe x Ga 1-x Cl 4-y Br y Results from SdH: Disorder for x 0,1 and/or y 0,4 (T D ) Effective mass (F ) correlated with M-X bond length? Radical change in FS for -(BETS) 2 FeCl 2 Br 2 T D ~ 0.5 KT D ~ 3.5 K III.
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-(BETS) 2 GaBr 4 -(BETS) 2 FeCl 2 Br 2 F = 948 T; T D = 0.55 K F = 4616 T F = 80 to 120 T F = 260 T; T D = 3.5 K Different FS No negative MR. E. Steven et al., ISCOM Physica B, to be published.
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Recent Progress in the Per 2 [M(mnt) 2 ] compounds “Lebed’ resonance” and orbital signatures in AMRO studies Per 2 [Au(mnt) 2 ] Pressure induced CDW-to-SC transition in Per 2 [Au(mnt) 2 ] 195 Pt NMR study of SP and CDW behavior in Per 2 [Pt(mnt) 2 ] in high fields. (work still in progress!) IV.
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EPL 85 No 2 (January 2009) 27009 Slow cooling rate under pressure is very important! CDW-SC Proximity: ???????????????????? J. Merino and R. H. McKenzie, Superconductivity Mediated by Charge Fluctuations in Layered Molecular Crystals, PRL 87, 237002(2001). SDW-SC: T. Vuletic et al., Coexistence of superconductivity and spin density wave orderings in the organic superconductor (TMTSF) 2 PF 6, Eur. Phys. J. B 25, 319 (2002). IVa.
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CDW? High Field (> 18 T) & High Pressure (~ 5 bar) reveal FS topology Orbital: QI type oscillations. Geometrical: a-c plane commensurate effects. Per 2 [Au(mnt) 2 ] IVb.
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Orbital effects: Magnetic field dependent Two families due to two extremal area planes in the Fermi Surface Geometrical effects: Magnetic field independent Related to crystallographic directions where the transfer integral paths are strongest. Next step: Lebed magic angle effects? Metal, NFL, Nernst, etc. Main Results:
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Interaction of Peierls and Spin Peierls transitions in Per 2 [Pt(mnt) 2 ] T CDW /T CDW (0) ~ - ( B B/k B T CDW (0)) 2 T SP /T SP (0) ~ -0 44( B B/k B T SP (0)) 2 - 0 2( B B/k B T SP (0)) 4 How and when does magnetic field break the Peierls (1/4 filled) and Spin Peierls (1/2 filled) ground states in the parallel chain system? IVc.
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Graf et al., PRL. A.G. Lebed and Si Wu, PRL 99, 026402 (2007) T(K) Pt Breaking the Peierls and Spin Peierls states in Per 2 [Pt(mnt) 2 ] with high magnetic field. Strategy: follow the 195 Pt NMR signal with field and temperature, and compare it with the transport data. But, could the Pt chains be involved?
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T(K) Pt Main Result So Far: The NMR signal vanishes when the CDW-Metal Phase Boundary Is Approached. Possible that SP is not broken until the CDW phase boundary is reached.
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Cпасибо!
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