Exploring the Role of Bi-Polarons in High Temperature Superconductivity Research

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This research delves into the concept of bi-polarons and their potential involvement in high-temperature superconductivity mechanisms. Collaborators from various institutions are investigating the properties and interactions of bi-polarons, considering factors like effective mass and density. The study compares standard polarons with density-displacement coupling and introduces models for bond polarons or PSSH polarons with displacement-modulated hopping. The discussion also touches on the challenges posed by the weight of Holstein bi-polarons and their implications in tight-binding Hamiltonians. Overall, the research aims to advance knowledge in basic science and mathematics related to polarons and their impact on superconductivity.


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  1. Bond polarons Nikolay Prokof ev (UMass, Amherst) Simons Foundation Paris, September 10, 2021 Advancing Research in Basic Science and Mathematics

  2. Collaborators: Chao Zhang (UMass and Boris Svistunov (UMass Amherst) East China Normal University, Shanghai) arXiv:2108.06725 PRB 21 M. Berciu, D. Marchand, P.C.E. Stamp (UBC, Vancouver) G. De Filippis, V. Cataudella (Universit di Napoli) N. Nagaosa, A.S. Mishchenko (Uniuversity of Tokyo, RIKEN-Saitama) PRL 2010 J. Sous, A, Millis, D. Reichman (Columbia) In progress

  3. Polaron: One impurity in the environment Bi-Polaron: Two impurities in the same environment forming a bound state What is next? Main question: Can bi-polarons provide the high-TC mechanism? 1 ~ T C 2 m R * Bi-polaron radius Bi-polaron effective mass

  4. Recall BCS-BEC crossover 1 ~ T Why ? C 2 m R * Bi-polaron effective mass Bi-polaron radius Similar, but in absolute terms T C 2/d n : T C m Push the bi-polaron density to the limit d nR : 1 1 BEC BCS 1/ F k R

  5. 2/d n : T estimate is very robust against repulsive interactions between bi-polarons! C m 1.84 n m 2/ d n T = 2D: 3.31 T 3D: C 1 0.3lnln(1/ + 2 ) na C m Barely any dependence on interactions. (even in He-4 the ideal gas formulais only 30% wrong) Double-logarithmically weak dependence! NP, O. Ruebenacker, B. Svistunov, PRL 01 Hard spheres Soft spheres Hard disks P. Gruter, D. Ceperley, F. Laloe, PRL 97 ; K. Nho and D.P. Landau, PRA 04 ; S. Pilati, S Giorgini, NP, PRL 08

  6. = + + int H H H H Standard polarons with density-displacement coupling: particle phonons = H g n X int ij i j ij = i n a a electron density i i = + j X b b oscillator displacement j j e e Holstein model (on-site coupling): = H g n X int i i i

  7. Bond polarons or PSSH (Peierls-Su-Schrieffer-Heeger) polarons with displacement modulated hopping: = + j i ( ) H g a a a a X ij ij = + j i ( )( ) H g a a a a X X int i j ij int i j i j ij ij e e Model B Model A

  8. Can bi-polarons be responsible for the high-TC mechanism? No, because Holstein bi-polarons are exponentially heavy when they form [Chakraverty, Ranninger, Feinberg, PRL 98] = + j i = H t a a a a 4 ? W dt Take tight-binding Hamiltonain with bandwidth (cubic lattice) phonon frequency p E particle i j ph ij E p k k W 2 g 4 dt 2 p ph 2 2 2 2 W g W W g g W g Band perturbation theory: Localized electron: exp # E * E p p 2 ph 2 2 2 ph ph overlap integral between phonon clouds W W W W ph = exp g Light-to-heavy crossover at with 1 2 2 * ph

  9. Sharp crossover from light to heavy polarons E 2 W light polaron branch 2 Heavy polaron branch 1

  10. Can bi-polarons be responsible for the high-TC mechanism? No, because the are exponentially heavy when they form. W 22 E W Two band polarons: p W g ph = g 1 2 Crossover to bi-polaron at 2 2 2 g 4 E Localized bi-polaron: p ph 2 p ( ) t g W 2 2 2 ph g t d t d W 2 = = 2 exp 2 exp t with as heavy effective mass bi /2 2 ph For in d=2 we get ph /2 t = /2 2 / W dt = 3 10 4 e e ph ph Realistically even is hard to get ph /4 t =

  11. Berciu, Marchand, Stamp, Filippis, Cataudella, Nagaosa, Mishchenko, NP, PRL 10 Sous, Chakraborty, Krems, Berciu, PRL 18 One-dimensional Model A e ij ij = + )( j i ( ) H g a a a a X X int i j i j ij leads to sign-alternating diagrammatic expansion both in real and momentum space M M ' ' kk pp // // // ' p p ' k k g i g = 2 [sin( ') sin( ) ig p ] M p // ' pp 1 2 In momentum space sign-problem is not as severe. But in 1D one can also afford other methods, e.g. controlled truncation of Hilbert space for diagonalization.

  12. One-dimensional Model A e = 2 cos( ) t Ground state shifts to non-zero momentum 'cos(2 ) K p t p eff 2 / 0 t g 2 ph = ph/ 0.5 t Effective mass is NOT exponentially suppressed at strong coupling in 1D = ph/ 3 t

  13. Zang, Svistunov, NP arXiv:2104.14044 2D Model A 2D Model B k q 1/2 = + k ( , ) k q H.c. H V M c c b k k k int ' , ' e , , = ) sin( e ' ( , ') k k 2 [sin( ig )] (mod el A ) M k k = + ' ( , ') k k 2 cos[( g )/ 2] (model ) B M k k Standard Diagrammatic Monte Carlo for Green s function diagrams. Always convergent for finite but sign-problem kicks in for large expansion orders. Look similarly in momentum representation but have rather different properties

  14. 2D Model A Ground state shifts to non-zero momentum along the diagonal in BZ = ph/ 3 t = ph/ 0.5 t Effective mass is NOT exponentially suppressed as yet for this coupling range Effective mass is slightly anisotropic after the transition

  15. 2D Model B Ground state is always at k=0 Effective mass is NOT exponentially suppressed here (at least not yet ) 1 ~ T What about bi-polarons and prospects for high BEC temperature? C 2 m R *

  16. = + ( + ) j i ij D Model B ( ) H g a a a a b b int i j ij ij Has sign-positive diagrammatic expansion in real space e j // // g g i 1 2 is easy to generalize to dispersive phonons and account for inter-particle interactions (for bi-polarons) // g g U U // g g

  17. D Model B Math. to simulate: 1r g N 2 /2 U Kinks g t ph ( ) Kinks ( , ) exp ( ) s ds td D r r U 0 ph ' ' pot j j j j 2 Kinks N phonons 0 ph phonon propagator j g Potential energy of interparticle interactions 2r ( , , ) r r G 2 1 2 ' 1. Change imaginary time: 1 Kinks Kinks 2. Increase/decrease the number of kinks: MC updates: 1 N N 3. Add/remove phonon lines between kinks: ph ph 4. Add more (if necessary for better decorrelation )

  18. Results for bi-polarons in 2D Model B e Very robust against Hubbard U But are far more heavy than single polarons!

  19. Radial profile of the bound state = = ; 0.5 g t t ph = = ; 0.5 g t t ph The bi-polaron radius goes up with U but remains relatively small Large repulsive U helps s-wave superconductivity!

  20. Relatively shallow states to begin with have much lighter effective masses and the radius effect dominates: TC is suppressed with U

  21. In between two extremes: TC maximum at U=8t from compromise between the bi-polaron mass and size

  22. Main question: Can bi-polarons be responsible for the high-TC mechanism? 1 ~ T C 2 m R * = = Take: / 0.5 and / 8: t U t ph g t = / 0.707 g t = / 1 / ~ 5 m m * 2 0 / ~ 65 m R m g t = / 0.8 * 2 0 ~ T 3 R 1 / ~ 10 m m ~ 0.2 5 * 2 0 C ph ~ 0. 12 T ~ 1. 2 R C ph ~ 0.3 3 T C ph Yes, this is very high Tc estimate!

  23. McMillans [Phys Rev 167, 331 (1968) ] expression utilizing Eliashberg theory [Sov. Phys. JETP 11 696 (1960) ] + e ph 1.04(1 ) 1 = exp T T C D e ph (1 0.62 + * 1.45 ) e ph * 0.12 with 1 There is no Eliashberg theory for because a localized bi-polaron state has much better energy

  24. Just a curious fact: for (particles are slower than phonons) 3 t = ph/ bi-polarons are lighter than twice the polaron mass

  25. Conclusions and questions: Bond polarons and bi-polarons appear to be much lighter than Holstein polarons Bond bi-polarons are robust against local repulsive interactions High TC is not automatic because compact bi-polarons are heavy and light bi- polarons have large size. Best estimates of bi-polaron Tc are significantly higher than the best predictions based on Eliashberg (Fermi-liquid) formula bi m Will phonon dispersion help to reduce ? t bi Is the large problem more severe for ? (likely yes) m ph How all results change in 3D when finite coupling is required for bound states to exist?

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