The multiple reentrant quantum phase transitions in the $S=1/2$
antiferromagnetic Heisenberg chains with random bond alternation in the
magnetic field are investigated by the density matrix renormalization group
method combined with the interchain mean field approximation. It is assumed
that the odd-th bond is antiferromagnetic with strength $J$ and even-th bond
can take the values ${\JS}$ and ${\JW}$ $ ({\JS} > J > {\JW} > 0)$ randomly
with probability $p$ and $1-p$, respectively. The pure version ($p=0$ and
$p=1$) of this model has a spin gap but exhibits a field induced
antiferromagnetism in the presence of interchain coupling if Zeeman energy due
to the magnetic field exceeds the spin gap. For $0 < p < 1$, the
antiferromagnetism is induced by randomness at small field region where the
ground state is disordered due to the spin gap in the pure case. At the same
time, this model exhibits randomness induced plateaus at several values of
magnetization. The antiferromagnetism is destroyed on the plateaus. As a
consequence, we find a series of reentrant quantum phase transitions between
the transverse antiferromagnetic phases and disordered plateau phases with the
increase of the magnetic field for moderate strength of interchain coupling.
Above the main plateaus, the magnetization curve consists of a series of small
plateaus and the jumps between them, It is also found that the
antiferromagnetism is induced by infinitesimal interchain coupling at the jumps
between the small plateaus. We conclude that this antiferromagnetism is
supported by the mixing of low lying excited states by the staggered interchain
mean field even though the spin correlation function is short ranged in the
ground state of each chain.Comment: 5 pages, 8 figure

Cabra D. C.

Hase M.

Hida K.

Honda Z.

Manaka H.

Matsumoto M.

Mikeska H.-J.

Nikuni T.

Nohadani O.

Scalapino D. J.

Tanaka H.

Uchinokura K.

Villar V.

Yasuda C.

English

arXiv

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Field-Induced Multiple Reentrant Quantum Phase Transitions in Randomly Dimerized Antiferromagnetic S

The multiple reentrant quantum phase transitions in the S = 1/2 antiferromagnetic Heisenberg　chains with random bond alternation in the magnetic field are investigated by the density　matrix renormalization group method combined with interchain mean field approximation. It is　assumed that odd numbered bonds are antiferromagnetic with strength J and even numbered　bonds can take the values JS and JW (JS > J > JW > 0) randomly with the probabilities p and　1−p, respectively. The pure version (p = 0 and p = 1) of this model has a spin gap but exhibits　a field-induced antiferromagnetism in the presence of interchain coupling if Zeeman energy due　to the magnetic field exceeds the spin gap. For 0 < p < 1, antiferromagnetism is induced by　randomness at the small field region where the ground state is disordered due to the spin gap　in the pure version. At the same time, this model exhibits randomness-induced plateaus at　several values of magnetization. The antiferromagnetism is destroyed on the plateaus. As a　consequence, we find a series of reentrant quantum phase transitions between transverse antiferromagnetic　phases and disordered plateau phases with the increase of magnetic field for a　moderate strength of interchain coupling. Above the main plateaus, the magnetization curve　consists of a series of small plateaus and jumps between them. It is also found that antiferromagnetism　is induced by infinitesimal interchain coupling at the jumps between the small　plateaus. We conclude that this antiferromagnetism is supported by the mixing of low-lying　excited states by the staggered interchain mean field even though the spin correlation function　is short ranged in the ground state of each chain.Copyright(c)2006 The Physical Society of Japa

飛田 和男

Saitama University Cyber Repository of Academic Resources

Typeset with jpsj2.cls <ver.1.2> Full PaperField-Induced Multiple Reentrant Quantum Phase Transitions in RandomlyDimerized Antiferromagnetic S = 1=2 Heisenberg ChainsKazuo Hida¤Department of Physics, Faculty of Science,Saitama University, Saitama, Saitama 338-8570(Received February 1, 2006)The multiple reentrant quantum phase transitions in the S = 1=2 antiferromagnetic Heisen-berg chains with random bond alternation in the magnetic ¯eld are investigated by the densitymatrix renormalization group method combined with interchain mean ¯eld approximation. It isassumed that odd numbered bonds are antiferromagnetic with strength J and even numberedbonds can take the values JS and JW (JS > J > JW > 0) randomly with the probabilities p and1¡p, respectively. The pure version (p = 0 and p = 1) of this model has a spin gap but exhibitsa ¯eld-induced antiferromagnetism in the presence of interchain coupling if Zeeman energy dueto the magnetic ¯eld exceeds the spin gap. For 0 < p < 1, antiferromagnetism is induced byrandomness at the small ¯eld region where the ground state is disordered due to the spin gapin the pure version. At the same time, this model exhibits randomness-induced plateaus atseveral values of magnetization. The antiferromagnetism is destroyed on the plateaus. As aconsequence, we ¯nd a series of reentrant quantum phase transitions between transverse anti-ferromagnetic phases and disordered plateau phases with the increase of magnetic ¯eld for amoderate strength of interchain coupling. Above the main plateaus, the magnetization curveconsists of a series of small plateaus and jumps between them. It is also found that antifer-romagnetism is induced by in¯nitesimal interchain coupling at the jumps between the smallplateaus. We conclude that this antiferromagnetism is supported by the mixing of low-lyingexcited states by the staggered interchain mean ¯eld even though the spin correlation functionis short ranged in the ground state of each chain.KEYWORDS: random quantum spin chain, DMRG, disorder-induced order, ¯eld-induced order,randomness-induced plateau, reentrant phase transition1. IntroductionIn recent studies of one-dimensional quantum spin sys-tems, exotic quantum phases induced by a strong mag-netic ¯eld have been attracting broad interest. Amongthem, ¯eld-induced transverse antiferomagnetism hasbeen widely investigated in many experimental and the-oretical studies.1{4) If a magnetic ¯eld larger than thespin gap is applied to a spin-gapped system, the single-chain ground state becomes the Tomonaga-Luttinger liq-uid and the transverse antiferromagnetic order developsas soon as a weak interchain coupling is switched on.Disorder is another origin of order in spin-gapped lowdimensional quantum magnets.5{11) In the presence ofdisorder, spins in the nonmagnetic ground state reviveand induce so-called 'disorder-induced order' even in theabsence of magnetic ¯eld.On the other hand, the possibility of a disorder-induced magnetization plateau is also predicted in acertain class of one-dimensional random quantum mag-nets.11{16) This corresponds to the spin gap state inducedby disorder and magnetic ¯eld.Therefore, the e®ect of disorder on quantum magnetsin a magnetic ¯eld is twofold. Namely, disorder enhancesmagnetic order by reviving spins, while it suppressesmagnetic order by forming plateaus. In the present work,we investigate the competition between these two contra-dictory aspects of randomness in quasi-one-dimensional¤E-mail address : hida@phy.saitama-u.ac.jpquantum spin systems and the resulting multiple reen-trant phase transitions between transverse antiferromag-netic phases and disordered plateau phases. Similar prob-lem has been discussed by Mikeska eat al.14) for the di-luted dimer network system and by Nohadani et al.15,16)for the coupled random dimer network.This paper is organized as follows. In the next section,the model Hamiltonian is presented. The single-chainmagnetization curve is calculated in x3. Within the inter-chain mean ¯eld approximation, we predict the multiplereentrant behavior with the increase in magnetic ¯eld inx4. The calculation of the spin-spin correlation functionis presented in x5. Even in the non-plateau state, wherein¯nitesimal interchain coupling induces transverse or-dering, the correlation function of a single chain turnedout to be short ranged. On the basis of these observa-tions, the mechanism of antiferromagnetism away fromthe plateau region is explained in x5. The ¯nal section isdevoted to summary and discussion.2. Model HamiltonianAs a candidate model in which reentrant antiferro-magnetism is expected, we investigate the quasi-one-dimensional random dimerized S = 1=2 Heisenberg chainwhose Hamiltonian is given byH =Xj8<:N=2Xi=1JS2i¡1;jS2i;j +N=2Xi=1JijS2i;jS2i+1;j9=;12 J. Phys. Soc. Jpn. Full Paper Kazuo Hida0 1 2 300.20.40123MHp=1.0p=0Fig. 1. Magnetization curves of pure single chains with p=0 and1.0. The chain length is N = 240.0 1 2 300.20.4MIIIIIIHp=0.2p=0.4p=0.6p=0.8Fig. 2. Magnetization curve of single chains for p=0.2, 0.4, 0.6and 0.8. The chain length is N = 120. Magnetization is measuredfor the middle 60 sites to reduce the boundary e®ect. The averageis taken over 64 samples. Error bars are shown only for selectedpoints because otherwise the symbols are extremely dense.+NXi=1X<j;j0>JintSi;jSi;j0 ; (1)where Jij = JS with the probability p and Jij = JW withthe probability 1¡p. The interchain exchange coupling isdenoted by Jint. The spin operator Si;j denotes the spinon the i-th site of the j-th chain. The summationP<j;j0>is taken over all nearest neighbour pairs of chains. In thepresent work, we assume JS > J > JW > 0. A similarmodel with ferromagnetic JW has been discussed11) inrelation to experimental materials.5)3. Single-Chain Magnetization CurveThe ground state magnetization curve of a single chainwith Jint = 0 in (1) is calculated using the density matrixrenormalization group (DMRG) method. The magneti-zation per site M is de¯ned byM ´ 1NNXi=1hSzi i ; (2)where the summation is taken over all spins in a singlechain and the chain index j is suppressed. Regular mod-els with p = 0 or p = 1 have magnetization plateaus atM = 0, which corresponds to the spin gap and at thesaturation magnetizationM =Ms ´ 1=2. However, theyhave no plateaus with intermediate values of magnetiza-tion as shown in Fig. 1.On the other hand, the magnetization curves for p 6=0; 1 consist of a sequence of plateaus. Between them,magnetization increases almost continuously. A typicalexample is shown in Fig. 2 for JS = 2; JW = 0:1 andJ = 1 for various values of p.The main features of the magnetization curves can beunderstood using the cluster picture similar to that de-scribed in ref. 11. With the increase in magnetic ¯eld,we observe three large plateaus that are numbered I,II and III in Fig. 2. Let us consider a cluster consist-ing of q successive JS-bonds and q ¡ 1 J-bonds in be-tween. This is called the 'q-cluster' as in ref. 11. The 2qspins in a cluster form a strongly coupled singlet clus-ter. The two spins connected to both ends of this clusterby J-bonds are almost free but weakly coupled mediatedby the quantum °uctuation within the strongly coupledcluster. Other spins form singlet dimers on the J-bondsif JW << J .On plateau I with magnetizationM = (1¡p)Ms, spinsthat do not belong to the q-clusters are all polarized. Onplateau II, end spins separated by 1-clusters with a singleJS-bond remain unpolarized. Similarly, on plateau III,end spins separated by 2-clusters also remain unpolarizedand so on. These interpretations are con¯rmed by com-paring them with the magnetization process of a clusterconsisting of a q-cluster and two additional end spins con-nected by J-bonds on both ends of the q-cluster. Lowerplateaus due to spins separated by longer q-clusters arenot clearly identi¯ed within the present scale. The low¯eld part of the magnetization curve re°ects the singu-larity of the low energy excitation spectrum as describedin ref. 11.Above plateau I, magnetization increases with the se-ries of plateaus and narrow continuous parts up to thesaturation ¯eld. As p increases, the width of the plateausdecreases and magnetization curve becomes almost con-tinuous.4. E®ect of Interchain Exchange InteractionWe treat interchain coupling by mean ¯eld approxima-tion17) assuming the transverse antiferromagnetic orderas ­Sxi;j®=½(¡1)im Jint < 0(¡1)iPjm Jint > 0: (3)J. Phys. Soc. Jpn. Full Paper Kazuo Hida 3For Jint > 0, we assume that the two dimensional lat-tice of the chains is bipartite. The value of Pj is +1 ifthe site j belongs to one of the sublattices and ¡1 if itbelongs to the other. We thus have the interchain mean¯eld Hamiltonian HIMF for each chain asHIMF =N=2Xi=1JS2i¡1S2i +N=2Xi=1JiS2iS2i+1¡ HstNXi=1(¡1)iSxi ; (4)with Hst = zjJintjm. If we denote the staggered magneti-zation m calculated using given value of Hst by m(Hst),the self-consistent equation readsHst = ¸m(Hst); (¸ ´ zjJintj): (5)Therefore, the minimum interchain coupling thatstabilizes transverse ordering is given by ¸c =limHst!0Hst=m(Hst), which is equal to the inverse of thesingle-chain staggered susceptibility Âst. If Âst diverges,the transverse ordering is stabilized for the in¯nitesi-mal interchain coupling within the interchain mean ¯eldapproximation. Practically, we estimate m(Hst) numer-ically with a tiny Hst and estimate ¸c from the ratioHst=m(Hst).Figure 3 shows the magnetic ¯eld dependence of¸c(Hst) estimated with Hst = 0:0005 for p = 0:2 andp = 0:8 as representatives of small p and large p cases.The magnetization curves in the absence of staggered¯eld are also presented. The H-¸c(Hst) curve has mul-tiple maxima, which clearly shows that multiple reen-trant behavior takes place for ¯nite interchain coupling inthe ground state. It should be noted that the H-¸c(Hst)curves are insensitive to the values of Hst around thesemaxima. However, around the dips and minima, the val-ues of ¸c(Hst) have signi¯cant Hst-dependence.For p = 0:8, ¸c(Hst) remains signi¯cantly small abovethe main plateaus compared with the peak values on themain plateaus. Therefore, we expect no disordered phasefor moderate values of interchain coupling in this re-gion where the magnetization curve appears almost con-tinuous. Even away from the main plateaus, however,the magnetization curve shows a series of small plateausand narrow continuous parts between them. Correspond-ingly, ¸c(Hst) tends to a ¯nite value as Hst ! 0 onthese plateaus. The detailed features of such behavior areshown in Fig. 4 for 2:17 · H · 2:21 as a representative.On these small plateaus, ¸c(Hst) clearly tends to small¯nite values as shown in Fig. 4 around H = 2:173 andH = 2:208. On the other hand, in the true o®-plateaustate, ¸c(Hst) tends to zero, suggesting the divergenceof Âst. In this case, the transverse antiferromagnetic or-der is stabilized in the presence of in¯nitesimal inter-chain interaction. In Fig. 4, such behavior is observedat H = 2:1905. To investigate this behavior in more de-tail, we present the Hst-dependence of ¸c(Hst) in Fig.5 at H = 2:1925; 2:1905 and 2.188 using the data forN =480. Only a 0.2% deviation from H = 2:1905 causesa clear upturn of ¸c(Hst). Although a weak size depen-dence is present, the data for N = 240 plotted in smaller0 1 2 300.20.401λc(Hst)MH(a)0 1 2 300.20.401λc(Hst)MH(b)Fig. 3. H-dependence of ¸c(Hst) with Hst = 0:0005 for (a) p =0:2 and (b) p = 0:8. The magnetization curves are also shownfor reference. The staggered magnetizationm is measured for themiddle 60 sites to reduce the boundary e®ect. The chain lengthis N = 120 and the average is taken over 512 samples. Error barsare shown only for selected points.symbols also show a similar behavior. Therefore, we ex-pect that this is not the ¯nite size e®ect but is an essen-tial feature of the present system in the thermodynamiclimit. A similar behavior is observed for other values ofH above the main plateaus. Therefore, we conclude thatthe antiferromagnetic order is stabilized by in¯nitesimalinterchain coupling only within a narrow region wheremagnetization increases continously between successivesmall plateaus.5. Correlation FunctionsTo obtain more insight into the nature of eachstate on the basis of the properties of single chains,we also investigated the spin-spin correlation func-tion­Sxi Sxj®as a function of ji ¡ jj. Figure 6 shows¯¯­Sxi Sxj®¯¯ ¡= (¡1)i¡j ­Sxi Sxj ®¢ for H = 2:1905(±) where¸c tends to 0 and Âst(Hst) diverges. Even in this case, thespin-spin correlation function is short ranged. Indeed, thebehavior of the corelation function is almost the same as4 J. Phys. Soc. Jpn. Full Paper Kazuo Hida2.18 2.200.020.040.060.20.25λc(Hst)HHst=0.002Hst=0.0001Fig. 4. H-dependence of ¸c for 2:17 · H · 2:21. The values ofthe staggered ¯eld are Hst = 0:002; 0:0015; 0:001; 0:0005; 0:00025and 0.0001 from top to bottom. The chain length is N = 480 andmeasurement is carried out for the middle 240 sites. The averageis taken over 256 samples. The error bars are within the size ofthe symbols.0.0002 0.001 0.00210−210−1.5H=2.188H=2.1905H=2.1925N=240 480λc(Hst)HstFig. 5. Hst-dependence of ¸c around H = 2:1905. The big sym-bols are for N = 480 and the small symbols are for N =240. The solid lines are power law extrapolation from Hst =0:0005; 0:001; 0:0015 and 0.002 for N = 480. The average is takenover 256 samples.0 10 20 3010−410−2|<SxiSxj>||i−j|H=2.1905H=2.1735Fig. 6. Transverse correlation function jDSxi SxjEj at H =2:1905(±) where Âst(Hst ! 0) diverges and at H = 2:1735(²)where Âst(Hst ! 0) is ¯nite. The average is taken over 512 sam-ples for N = 240.100 10110−410−2|<SixSjx>||i−j|H=2.1905p=0.8p=0Fig. 7. Log-log plot of correlation function with p = 0:8 (opencircles) and p = 1(¯lled squares) at H = 2:1905 for N = 240.orderenhanced fluctuationdisorderdisorderorderTHorderFig. 8. Schematic ¯nite temperature phase diagram on H ¡ T -plane.that for H = 2:1735(²) where ¸c tends to small but ¯nitevalues and Âst(Hst) tends to large but ¯nite values. InFig. 7, the log-log plot of the same correlation functionis compared with that for the regular chain with p = 1at H = 2:1905. It is clear that the rapid decay of cor-relation for the random chain is distinct from the powerlaw decay for the regular chain.This can be understood as follows. In the o®-plateauregion, the continuum of low energy excited states pileup on the ground state. In many of these excited states,the spins that are not correlated in the ground state arecorrelated. The staggered transverse magnetic ¯eld mixesup these excited states resulting in divergent staggeredsusceptibility. In this case, the long range transverse or-der can be stablized by in¯nitesimal interchain couplingeven though the spin correlation is short ranged in theground state. On the other hand, in the plateau state,there exists no low-energy excited states that supportthe long range order with small interchain coupling.It should also be noted that the divergence of Âst doesnot always contradict ¯nite correlation length, becausethe staggered magnetization does not commute with theHamiltonian and the summationPi;j(¡1)i¡j­Sxi Sxj®isnot directly proportional to Âst.6. Summary and DiscussionThe transverse magnetic ordering in the ground stateof the random quantum Heisenberg chain is investigatedusing the density matrix renormalization group and theinterchain mean ¯eld approximation. It is predicted thatthe multiple reentrant behavior takes place between thedisordered plateau phases and transverse antiferromag-netic ordered phases. This is in contrast to the case ofrandom dimer networks discussed by Mikeska et al.14)and Nohadani et al.,15,16) in which the reentrant transi-sition takes place only once.It is also pointed out that even in the non-plateauregime the spin-spin correlation of the single chain isshort ranged. Nevertheless, the long range order is es-tablished with in¯nitesimal interchain interaction withthe help of excited states that pile up near the groundstate and are mixed up by the interchain staggered mean¯eld.J. Phys. Soc. Jpn. Full Paper Kazuo Hida 5In this work we concentrated on the ground state phasetransition. Nevertheless, the reentrant behavior shouldsurvive even at ¯nite temperatures. The transition tem-perature should be high between the plateau region andlow or zero on the plateau region as shown in Fig. 8schematically. This behavior manifests itself as anoma-lous behavior even above the transition temperature.Therefore, if we increase magnetic ¯eld at a ¯xed temper-ature, the transverse spin °uctuation would be stronglyenhanced when we pass near the ordered phase.We expect that the present type of reentrant behavioris universal in random quantum spin systems in whichsinglet dimer formation is randomly perturbed to pro-duce local almost free spins. In contrast to the randomdimer network systems in which dilution produces iso-lated spins, the free spins in the present system are pro-duced by the random competition between two di®erentdimer interactions JS and J , each of which prefers dif-ferent dimer con¯guration. This is the origin of a morecomplicated structure of the phase diagram. Thus, weexpect the reentrant behavior due to similar mechanismin a variety of systems.The computation in this work was carried out usingthe facilities of the Supercomputer Center, Institute forSolid State Physics, University of Tokyo and the Informa-tion Processing Center, Saitama University. This work issupported by a Grant-in-Aid for Scienti¯c Research fromthe Ministry of Education, Culture, Sports, Science andTechnology, Japan.1) T. Nikuni, M. Oshikawa, A. Oosawa and H. Tanaka: Phys.Rev. Lett. 84, (2000) 5868.2) Z. Honda, K.Katsumata, Y.Nishiyama, and I. Harada: Phys.Rev. B63, (2001) 064420.3) M.Matsumoto, B.Normand, T.M.Rice and M.Sigrist: Phys.Rev. Lett. 89, (2002) 77203.4) H. Tanaka, A. Oosawa, T. Kato, H. Uekusa, Y. Ohashi, K.Kakurai and A. Hoser: J. Phys. Soc. Jpn. 70 (2001) 939 andreferences therein.5) H.Manaka, I. Yamada, H.Mitamura and T.Goto: Phys. Rev.B 66, (2002) 064402 and references therein.6) M.Hase, I. Terasaki, Y. Sasago, K.Uchinokura and H.Obara,Phys. Rev. Lett. 71, (1993) 4059.7) K.Uchinokura: Prog.Theor. Phys. Suppl.145 (2002) 296 andreferences therein.8) C. Yasuda, S. Todo, M. Matsumoto and H. Takayama: Phys.Rev. B64, (2001) 092405.9) C. Yasuda, S. Todo, M. Matsumoto and H. Takayama: Prog.Theor. Phys. Suppl. 145 (2002) 339 and references therein.10) V. Villar, R. M¶elin, C. Paulsen, J. Souletie, E. Janod and C.Payen: Eur. Phys. J. B25 (2002) 39.11) K. Hida: J. Phys. Soc. Jpn. 72, 688 (2003).12) K. Hida: J. Phys. Soc. Jpn. 72, 911 (2003).13) D. C. Cabra, A. De Martino, M. D. Grynberg, S. Peysson andP. Pujol: Phys. Rev. Lett. 85 (2000) 4791.14) H.-J.Mikeska, A.Ghosh and A.K.Kolezhuk: Phys.Rev.Lett.93, (2004) 217204.15) O. Nohadani, S. Wessel and S. Haas: Phys. Rev. Lett. 95,(2005) 227201.16) O. Nohadani, S. Wessel and S. Haas: Phys. Rev. B72, (2005)024440.17) D.J.Scalapino, Y. Imry and P.Pincus: Phys.Rev.B11 (1975)2042.

Field-induced multiple reentrant quantum phase transitions in randomly dimerized antiferromagnetic S=1/2 Heisenberg chains

Field Induced Multiple Reentrant Quantum Phase Transitions in Randomly
  Dimerized Antiferromagnetic S=1/2 Heisenberg Chains

Field Induced Multiple Reentrant Quantum Phase Transitions in Randomly Dimerized Antiferromagnetic S=1/2 Heisenberg Chains

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