Gauge-field interaction and superconductivity in the t1−J model

Gauge-field interaction and superconductivity in the t1−J model

T ~ J C 1~$- 189 (1991) 14"/9-14~0 North-Holland GAUGE-FIELD INTERACTION AND SUPERGONDUGTIVII"Y tN I"tt~ # - d M O D E L B.Normand and P.A.Ime...

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T ~

J

C 1~$- 189 (1991) 14"/9-14~0 North-Holland

GAUGE-FIELD

INTERACTION

AND

SUPERGONDUGTIVII"Y

tN I"tt~ # - d M O D E L

B.Normand and P.A.Ime, Dept. of Ph~nties, M.I.T., Cambridge, MA 02139, U.S.A., ~ d N . N ~ Applied Physics, University of Tokyo, 7-3-1 Hongo, Bunkyo.ku, Tokyo 113' Japan.

Dept. o¢

In a theory of dilute fermionic holes in a 2-dimenfional a n t i f e ~ m a g n e t in the d i ~ e r ~ ante, the interparti¢~ interactions can be c u t in terms of a gauge field. We have calculated the g a u ~ f l e l d prop~ator D a ( q , , } at zero temperature, taking into account both fermloni¢ and bosoni¢ degrees of freedom. Numerical ~ t a t ~ of the interaction spectral function show it to be dominated by the fermion ~ t r i b u t i o n , and to have an unconventional power-law dependence a~F(~) .~ ~ - ~ , wlth x dose to ~. S u p e ~ n d u e t i ~ i t y in the rrax~!d i.~ expressed in the formalism of Eiiaahber$ theory, with the unus,a! cJF{~). In the t' - J model of an antiferromagneti¢ sys-

must be included.

Dt,,,(q ) = ll~,~{q) aeparat~ into

tem with short-range order in 2-dimensions, the holes

scalar and vector parts according to the v ~ e x co~apfing~

may hop only on A or B sublattices separately so

in (1), yielding an effective coupling g i ~

that the number difference na - nB is conserved) A

e~

X-~

2flV p~p,,

Schwinger boson/slave fermion decomposition gives a

by B,,,t =

! (P+ ~q)~. ~ ,(P, - 1~q)~ Do(q) - ~ v , ~ t q l . . . . . .AI

bosons (represented by staggered spinor field z), with

t t , fA.V + fa,~,_¢fB,r+¢fB.pfa~p°] [/A,p+q/s.,-/s~ ~ (2}

interactions mediated by a gauge field ~ at, , whose U(1 )

in Matsubara and momentum spa,:e (q = (q, i~,,n }), with

gauge symmetry is a consequence of the conservation

propagators Do(q) = (AoAo) =-- 7l II~'~l{q) and D,~z =

law. The Hamiltonian

(A~A~) ~

system of spinless fermions ( f . 4 , f B ) and spin-carrying

×

Summing ~he polarization bubbles yields the zero>

H=ff dr f d~z~l(O.-iea.)zl 2

~emperature boson part R~.(q) and, separately, the thermal fermion parts I]ge(q) and It~a(q ).

-

2M

(a,

-

-

I . 2M

alytic continuation and taking the T ~ +

(~)

By an-

0 limit of

the latter functions, one obtains Mgebraic expresmons

b,n

~, R

is that of the C P a model, which is taken to be in the

for

disordered phase, with a gap m for spin excitation; M is

y.R ( q , w ) ( 6 ~ - q~q'a), each of which has several forms II,,,¢

the fermion mass in a small energy expansion. The low-

in different regions of (q,w) space. By coding t he_~e expressions in all re~mes of (q, ~ }.

previously i, while in this paper the analysis is extended

one has the exact zero-~empera~ure gauge boson prop-

to include frequencies up to an energy scale of order d.

agator Da(q,,v) for the lowest order interaction. The

To find the lowest order effective interaction be-

interaction spectral function is given by a complete q

tween f a and fB particles required for superconductiv-

integration as

ity, both fermion and boson polarization contributions to the effective gauge propagator Do. = (a~,(q)a,,(-q))

c~2F("v) -

0921-4534/91/'$03.50 © 1991 - Elsevier Science Publishers B.V. All fights r'e~erve&

1 [ d2q 1 e : p } l ~ D a ( q , ¢ t , (2i 2~r J (2~} 2 vFq 2312 ......

R Nonnand et at / Superconductivity in the t'-J model

1480

t# 2

which is valid at all frequencies w < J (the spin-spin interaction setting the upper validity limit of the original decomposition). The function has a power-law dependence at low frequencies aaF(w) ~ ¢0-" (Fig.1.), with 0.25 < z < 0.4 for all reasonable ranges of the external parameters t', J , m and doping $ (which sets pF). In the limit of low frequency and when Iq[ is small relative to m, it can be shown 1'3 that II~'~ << II~-e~ and IIt,R ec "., x d q ~ - -

.ta z~q-~ -, where Xd is a diamagnetic suscep-

tibility. In the approximation that this form is valid for all q < 2pF, one may evaluate the spectral function as 4=(Mxa)]

,

i.e. z = ~. This implies

that the low-q form of II~e¢ dominates the exact integral also, but the effects of averaging over all q <_ 2pg cause deviations from z = ~. The change in form at w > 1pF (Fig.l) is the result of denominator terms in D

of 0 ( q-r), outside the above approximation, becoming significant.. This result, that the fermion part is dominant and the boson mass m plays an insignificant role at zero temperature, is in contrast to the assumption made previously I that m is the upper limit of validity, and marks a crossover in behavior of the effective interaction. The order parameter for pairing in the superconducting phase is (.fA,pf~,-p/, which suggests a N a m b u formulation 4 with two-component field operators ~pT _ (f1,: ' f/L-p) and ~p. The important difference from the spin problem is that the B vertex has "gauge charge" - e (1), which alters the sign of the B fermion contribution to the density p(q) = ~"]~p~ + q l q p j(q) = X-~p~ ( p + ½ q ) ~ + q l " , ~ p .

and current

Taking the vector part

to be dominant, the effective interaction (2)then has the same vertex structure (~'3.r3) as the Eliashberg phonon problem.

10

¸

The coupled Eliashberg equations 4 are expressed 8

in terms of the gap function A(w) and the quasipar-

6

tide renormalization Z(w) using the spectra.! function

4

a2F(w). At zero temperature with a simple power-law

2

form of c~2 F(w), the equations are analytically tractable

0

to lowest order by scaling arguments if one assumes also

!

0

100

50 w (in units of F.E./100)

l0 t

e power-law variation of A(~o) = A 1 ~"

. At low fre-

quencies w < A0 it is found that the only consistent solution is y = 0, i.e. A(w) = A0 is a real constant. Nu-

I

merical solutions currently being refined confirm the existence of a conventional order parameter with ~ ,

_'2 5

if the same divergent spectral function is assumed valid at finite temperature.

At high frequencies w >> A0,

A(w) = A0 remains the only solution in this approxi10

I0 o

Fig.l:

I

,

,

,

I

, It

I

t

I

10 ~ w (in units of F.E./100)

I

I

I

I

I

10 ~-

The interactio- spectral function a 2F'(w), which diverges as w -+ 0. The logarithmic plot has gradient -~c for 0 < w < ½¢F, illustrating persistence of the power law for the entire range.

mation. 1 P.A.Lee, Phys. Rev. Lett. 03, (1989) 680. 2 See for example X.G.Wen, Phys. Rev. B 30, (1989) 7223. 3 N.Nagaosaand P.A.Lee, Phys. Rev. LetL 04, (1989) 2450. 4 D.J.Scalapino, in Superconductivity, ed. R.D. Parks (Marcel Dekker, New York, 1969) pp. 449-560.