A real-space effective c-axis lattice constant theory of superconductivity X. Q. Huang1,2∗ 1Department of Telecommunications Engineering ICE, PLAUST, Nanjing 210016, China 2Department of Physics and National Laboratory of Solid State Microstructure, Nanjing University, Nanjing 210093, China (Dated: January 27, 2010) Based on the recent developed real-space picture of superconductivity, we study the stability of thesuperconductingvortexlatticesinlayeredsuperconductors. Itisshown thattheeffectivec-axis lattice constant play a significant role in promoting the superconducting transition temperature in these materials. An unified expression Tcmax = 10c∗ −28 can be applied to estimate the highest 0 possible Tcmax for a given layered superconductor with an effective c-axis lattice constant c∗. For 1 the newly discovered iron-based superconductors, our results suggest that their Tc cannot exceed 0 60 K, 50 K and 40 K for the 1111, 21311 and 122 series, respectively. In the case of copper-based 2 oxidesuperconductors,it seems thatthehighestTc canreach about 161 Kwithout applyingof the external pressure. In our theoretical framework, we could interpret the experimental results of the n completely different superconducting transition temperatures obtained in two very similar cuprate a J superconductors(La2−xBaxCuO4 of40KandSr2−xBaxCuO3+δ of98K).Inaddition,thephysical reason why the superconductivity does not occur in noble metals (like gold, silver and copper) is 7 discussed. Finally, we argue that the metallic hydrogen cannot exhibit superconductivity at room 2 temperature, it even cannot bea superconductor at any low temperature. ] l PACSnumbers: 74.20.-z,74.25.Qt,74.90.+n e - r t I. INTRODUCTION is very difficult to reach60 K by means of elements sub- s . stitution or by applying hydrostatic pressure, and this t a prediction is still correct up to now. As pointed out by Finding the room temperature superconductors has m Chu recently, “The discovery of iron-based pnictide su- been an elusive dream of scientists in the field of con- perconductors may have reinvigorated the field of high- - d densed matter physics. In 1986, the discovery of high temperature superconductivity, but the cuprate super- n temperature cuprate superconductivity by Bednorz and conductors are still in the game”.7 o Müler1 shocked the superconductivity community and In addition, physicists considered that a high pressure c rekindled the dream of room-temperature superconduc- [ can make the hydrogen molecules into atoms and make tivity. Sincethen,greateffortshavebeendevotedtofind- it a metallic conductor. Moreover, it was predicted ac- 1 ingoutnewmaterialswithahighercriticaltemperature.2 cording to the BCS theory8 in 1968 by Ashcroft9 that v Many cuprate superconductors have since been discov- solid metallic hydrogen may be superconducting at high 7 ered and the highest temperature superconductor was temperature, perhaps even roomtemperature. However, 6 HgBa Ca Cu O with T = 138 K. Its T can be in- 0 2 2 3 8+δ c c to get metallic hydrogen is still a distant dream, not to creased as high as 164 K under a high pressure of about 5 mention the realization of the superconductivity. Based . 30 GPa.3 Later, several materials have been claimed to on our theory,10,11 we would like to point out that even 1 be room-temperature superconductors which have been 0 if there exists metallic hydrogen, it is also impossible to quickly provedto be false. However,how to enhance the 0 exhibit the superconductivity at any low temperature. superconducting transition temperature is always one of 1 In this paper, the discussionof enhancement of super- : central concerns in the field of superconductivity. conductivity is presented in the framework of the real- v i In2008,Japaneseresearchersdiscoveredthesupercon- spacesuperconductingvortexlattices. We showthatthe X ductivity in the iron-oxypnictide family of compounds.4 effectivec-axislatticeconstantplayakeyroleinpromot- r LiketheCu-basedsuperconductors,1–3thenewsupercon- ing the superconducting transition temperature in the a ductors have layered atomic structures and can conduct layered superconductors. electricity without resistance at relatively high temper- atures than the conventional low-temperature supercon- ductors. Similarly,thenewdiscoveryhastriggeredinten- II. A COMPARISON BETWEEN TWO sive research worldwide and the maximum critical tem- SUPERCONDUCTING THEORIES ESTABLISHED IN MOMENTUM SPACE AND peraturehasbeenraisedfromtheinitialreportofT =26 c KinLaO1−xFxFeAs4toabout55KinSmO1−xFxFeAs5. REAL SPACE Facing the rapid increase of T , some researchers seem c too optimistic about the new discovery and they even A. BCS theory of superconductivity claimed that these compounds could be useful for de- veloping room-temperature superconductivity. In fact, In the framework of the BCS theory,8 the supercon- morethanoneyearago,weprovedtheoreticallythatthe ducting current is carried by the so-called Cooper pairs maximum T of the new iron arsenide superconductors of electronswhich are held together by lattice vibrations c 2 - k lustrated in Fig. 1(b). More importantly, the Coulomb (cid:1) interaction is the elementary electrical force that causes (cid:0)(cid:3) (cid:2) (a) two negative electrons to repel each other, hence, two important questions arise: (1) How can the real-space - k (cid:0)(cid:3) (cid:1) repulsions among electrons (or pair-pair repulsions) and (cid:4)(cid:5)(cid:6)(cid:7)(cid:6)(cid:7)(cid:8)(cid:7)(cid:9)(cid:10)(cid:11)(cid:12)(cid:13)(cid:9)(cid:8)(cid:6)(cid:7) (cid:2) the attractions among electrons and ions be eliminated ~ to support the formation of the Cooper pairs? (2) Nor- (cid:12) (cid:22)(cid:23)(cid:24)(cid:24)(cid:25)(cid:26)(cid:27)(cid:28)(cid:29)(cid:23)(cid:26)(cid:25)(cid:30)(cid:31)(cid:23) !"# !"$%& mally, there are two kinds of interactions in the super- (b) ~ conducting materials, one is the very strong short-range ’()*+,-)./0)1)23./*45 (cid:1)67 electron-electroninteractions[see Fig. 1(b)], the otheris the rather weak long-range electron-phonon interactions - k k [seeFig. 1(a)]. Now,thequestioniswhycanthestronger short-range electron-electron interactions be completely ignored in the BCS theory? B. Wigner crystal and the real-space superconducting theory x » (cid:14)(cid:15)(cid:6)(cid:6)(cid:4)(cid:10)(cid:11)(cid:16)(cid:4)(cid:12)(cid:8)(cid:11)(cid:17)(cid:8)(cid:18)(cid:10) (cid:19)(cid:20)(cid:20)(cid:7)(cid:21) Asweknowtherearemanytheoriesaboutthecauseof Figure 1: (a) Two electrons are bound into a Cooper pair in thesuperconductivityincupratehightemperaturesuper- themomentumspace,thepairedelectronshaveoppositespin conductors. Unfortunately,mostofthesetheoriescontra- and opposite momentum and gives rise to the superconduc- dict each other and they may be on the wrong track as tivity. (b)Intherealspace,thepairedelectrons(onemoving emphasized by Anderson6. In our opinion, the natural left, the other moving right.) can be separated by a coher- encelength(theCooper-pairsize)ofupto100nm. Andthere strong repulsion between two electrons is impossible to mayexist107 electrons(orelectronpairs)betweenthepaired be totally overpowered by a lattice vibration (known as electrons. a phonon) and all superconductors should share exactly the same physical reason. The present situation of one- material one-mechanism of superconductivity should be (anexchangeofphonon)inthematerial. Theusualanal- changed. Inotherwords,anewandunifiedtheorywhich ysis in the BCS theory relies on a momentum-space pic- can explain all superconducting phenomena has proved ture,theCooperpairsareformedinmomentumspace(k- more important and urgent today. space) and the paired electrons have opposite spin and With increasingly better samples and advances in ex- opposite momentum (k↑,−k↓), as shown in Fig. 1(a). perimentaltechniques(forexampletheScanningTunnel- Of course, if the two electrons are to remainin the same ing Microscopy12), a vast amount of data from these ex- paired state forever, then they must undergo a continu- perimental studies reveal that the superconducting elec- ous exchange of virtual phonon in the BCS picture. trons are more likely to congregate in some real space AlthoughthephysicscommunityacceptsthattheBCS quasi-one-dimensionalriversofchargeseparatedbyinsu- theory can successfully describe the behaviors of most latingdomains.12–15Obviously,acorrectandreliablethe- metallic superconductors, it is commonly believed that ory of superconductivity has to take into account these the phonon based BCS theory is invalid for the descrip- new results. Although many researchers have been try- tion of the behavior of the high-temperature supercon- ing to replace the conventional superconducting picture ductors. As pointed out by Anderson,6 the need for a (dynamicscreening)witharealspacepicture,buthowto bosonicglue(phonon)incupratesuperconductorsisfolk- constructa proper model relatedto the formationof the lore rather than the result of scientific logic. It is well one-dimensional charge rivers will still be a major chal- knownthatthe superconductingelectrons(asdefined by lenge for those devotingthemselves to crackthe mystery BCS theory) are a momentum space order phase, while of high-temperature superconductivity. at the same time a disorder phase in real-space. From In recent years, we have tried to propose a real space both the physics and mathematics point of view, the superconducting mechanism which may provide new in- fundamental differences between two descriptions (one sights into the nature of the superconductivity.10,11 In orderandonedisorder)ofsuperconductingelectronsim- our scenarios, all the superconducting electrons can be ply that the BCS theory may not be scientifically self- considered as the ‘inertial electrons’ moving along some consistent. From the perspective of the real-space corre- quasi-one-dimensional real-space ballistic channels, as lations,twoboundelectrons(aCooperpair)canseparate shown in Fig. 2(a). In the previous paper,11 it was by a coherence length of ξ up to 100 nm, which is also provedtheoreticallythatastaticone-dimensionalcharge calledthecoherencelength. Itshouldbenotedthatthere stripe can be naturally formed inside the superconduct- are about 107 randomly distributed electrons (or pairs) ing plane and the Coulomb repulsion between electrons betweenthemintheconventionalsuperconductors,asil- can be suppressed completely, as indicated in Fig. 2(a). 3 89:;<=>?@ABC@D?ECB>?AB=FGH=IJC>KI?LCM><LCIGABD<GK?BJJIA<BD>K=KCN (cid:148) (cid:148) (cid:148) (cid:148) (cid:148) (cid:148) (cid:148) (cid:148) (cid:138) (cid:138) (cid:138) (cid:138) (cid:138) (cid:138) (cid:138) (cid:138) {|d}|~(cid:127)(cid:128)(cid:129)d(cid:130)(cid:131)}(cid:132) OPPQRSQTUS v v s 1 2 + g + (cid:148) (cid:148) (cid:148) (cid:148) (cid:148) (cid:148) (cid:148) (cid:148) + (cid:138) (cid:138) (cid:138) (cid:138) (cid:138) (cid:138) (cid:138) (cid:138) (cid:141) hw 8j: kMl=NmnmGo(cid:133)(cid:134) V^X Y_‘(cid:133)a-b(cid:134)Z[V](cid:135)(cid:133)Z(cid:134)(cid:135)[(cid:136)c(cid:135)d(cid:133)-(cid:134)(cid:135)X y (cid:139)(cid:140)(cid:148) (cid:149) (cid:148) (cid:148) (cid:148) (cid:148) (cid:148)(cid:141)(cid:143) (cid:148) (cid:144) (cid:148)(cid:146)(cid:147) (cid:142) (cid:148) x (cid:148) (cid:148) (cid:148) (cid:148) (cid:148) (cid:148)d (cid:148) (cid:145) Figure 3: When two electrons moving along the same direc- (cid:137)uv xqyz (cid:137)uv xqyz ytiocnoo(ryd-ainxaist)ew),itthhethxe-saaxmiseCvoeulolocmityb(roerpsutlasitoicn, bweitthwetehnetshameme i h g VeXYZ[f(cid:214) \] pqrs VWXYZ[(cid:214) \] pqrs cbaanckbgreoufunldly. overcome (fB = F1 −F2) by the positive ion perconducting vortex lattices. It is easy to find that the competitive interactions between stripes can be greatly reduced by increasing the stripe-stripe spacing and this, in turn, enhances the stability of the superconducting state and increases the corresponding superconducting tuv xqyz tuv xqyz transition temperature. For the layered superconduct- pqrs pqrs ing materials, there are usually two ways to control the stripe-stripe spacing inside the superconductors. The Figure 2: (a) The short-range repulsive forces among elec- trons can be canceled out by arranging them into one- first is the carrier concentration and the second is the dimensional real-space charge river (charge stripe). A stable c-axis lattice constant of the samples. Normally, a su- one-dimensionalchargestripeisconfinedbythedomain-walls perconducting sample with a low carrier concentration ofthepositiveions. Itisprovedthattheelectron-electronre- and a largec-axis lattice constantmay have a higher su- pulsionsinsidethestripecan beeliminated completely asin- perconductingtransitiontemperature. Ofcourse,thetoo dicatedinthefigure. (b)-(e)Thelong-rangeelectron-electron low carrier concentration is not conducive to the forma- repulsionsamongdifferentstripescanalsobecanceledoutby tionofsuperconducting vortexlattices due tothe lackof arranging the stripes into some periodic Wigner crystals. To effective competition among electrons. achieve the highest superconducting transition temperature, To form a stable superconducting vortex lattice, both the superconducting vortex lattices should be in the follow- electron-electronrepulsiveinteractionswithinthe charge ingfourstablestructures,(b)and(c)thevortexlatticeswith tetragonal symmetry, while (d) and (e) having the trigonal stripesandbetweenthe stripes shouldbe inhibited thor- symmetry,where h is a positive integer. oughly. The former situation was studied and resolved in one of our previous papers,11 here we will pay our at- tention to the later situation. It will be shown that the Accordingto the principle ofminimum energy,forthree- nature of the electron-electron repulsive interaction can dimensional bulk superconductors, the one-dimensional even be changed into an attractive type because of the chargestripescanfurtherself-organizeintosomethermo- positive ion background. dynamically stable vortex lattices (the Wigner crystal) Ourtheoryisbasedontheexperimentalfactsthatthe with trigonal or tetragonal symmetry, as shown in Figs. superconductingelectronsmaybeassociatedwithalong- 2(c)-(f). It is not difficult to prove that the electron- rangespatialcoherencechargeorderedstate. Inorderto electron repulsions among different stripes can also be studythestabilityofthe superconductingvortexlattices completely canceled out due to the symmetries in the of Fig. 2, we can consider the simplest case where the Wigner crystals. stripe-stripeinteractioncanbesimplifiedastheelectron- electron interaction, as shown in Fig. 3. We will show that by adjusting the parameters δ the electron interac- tioncannotonlybe repulsivebut canbe alsoattractive. III. THE STABILITY OF THE Moreover,there is a special value of δ that can lead to a SUPERCONDUCTING VORTEX LATTICES completelysuppressionofthe Coulombrepulsion,thatis On the basis of our theory as described in Fig. 2, the f =F −F (1) B 1 2 superconducting critical temperature of the layered su- perconductors is closely related to the stability of the In the following, we will discuss how electron-electron vortexlattices. Obviously,thestripe-stripeinteractionis repulsion between the two adjacent charge stripes be the most importantfactor relevantto the stability of su- overcome? It is worth noting is that this is merely the 4 ‰¯ +‰ ‚+ +” +¿ ¸ (a) (n=1) ˘†‡·(cid:181)¶ ›fi ›– ›` ›ˆ a Æ(cid:226)(cid:217)(cid:219)(cid:212)ª l=10 y + + «˙‹ +›fl • +›˜›(cid:192) + (cid:223)(cid:214)(cid:221)(cid:224) repulsive l=1 …¯ d la d›(cid:176) ›´ a (cid:222)¨ attractive x » … ' „x d(cid:190) (cid:213)(cid:217) (cid:150)(cid:151)(cid:152)(cid:152)(cid:153)(cid:152)(cid:154)(cid:155)(cid:156)(cid:157)(cid:158)(cid:159)(cid:152)(cid:153)(cid:152)(cid:154)(cid:155)(cid:156)(cid:157)(cid:158)(cid:160)¡¢(cid:154)£(cid:158)⁄ ¥ƒ§¤'“¢¤' (cid:212)(cid:221) (cid:216) (cid:215)(cid:211) Figure 4: A diagram illustrates how the Coulomb repul- (cid:211) sion between two electrons be eliminated by considering the (cid:213)(cid:217) electron-ion interactions. Note that the electron A and B (cid:211) (cid:204)¸ (cid:216) ¨(cid:201)¨ ¨(cid:201)˚ ¸(cid:201)¨ (which is not shown in this figure) are located inside two ad- (cid:213)(cid:221)¨(cid:201)¸ (b) jacent stripes, respectively. (cid:212)(cid:218) l=10 (cid:217) (cid:211) (cid:220) (cid:211) well-known Coulomb screening effect of the positive ion (cid:218)(cid:219)(cid:217) l=1 (cid:217) background. For simplicity, apart from the Coulomb (cid:213)¨(cid:201)¨ (cid:216) l repulsion between two electrons, we consider only the (cid:215) nneeaarreesstt-nneeiigghhbboorrss((boontlhyininxxa-dnidreyc-tdioirne)cteiolencst)roann-dionnexint-- (cid:211)(cid:212)(cid:213)(cid:212)(cid:214) (cid:230) l (cid:229) l (cid:210) teractions in this study, as shown in Fig. 4. Here we (cid:209) (cid:228) analyze mainly the forces applied on the electron A of (cid:204)¨(cid:201)¸ ¨(cid:201)˝˛ ¨(cid:201)˚¨ ¨(cid:201)˚ˇ d /a ¨(cid:201)˚˝ ¨(cid:201)˚— ¨(cid:201)˚˛ Fig. 4 and the discussion is similar to another electron B (not shown in this figure). According to Fig. 3 and Fig. 4, the Coulomb forces Figure5: AnalyticaltotalconfinementforceFtotalonelectron appliedtotheelectronAcanbedividedintothreeparts. Aversusδ/afordifferentlwiththespecialconditionQ=+e The first part is electron-electron (A and B) repulsion (or n=1). Fig. (b) is the enlarged figure of the rectangular which is given by area of Fig. (a). e2 The resultantforce ofthis partonthe electron A canbe f = , (l =1,2,3,···) (2) B 4πε [(l+2)a+2δ]2 expressed as: 0 F =F(12)+F(34)+F(56)+F(78). (7) The second part is contributed by the eight ions (they x x x x x aremarkedby1,2,3,4,5,6,7and8inFig. 4,andeach The third part is contributed by the other eight ions ion carries a positive charge ne) around the elect on A, aroundthe elect on B, the correspondingresultant force they are ′ F can be written as: x F(12) = f +f x 1 2 = −n e2 δ , (3) F′ =−n e2 4 δ+(i+2)a . (8) 4πε0[(a/2)2+δ2]3/2 x 4πε0 Xi=1 (a/2)2+[δ+(i+2)a]2 3/2 h i F(34) = f +f Nowwecanobtainageneralformulaofthe totalforce x 3 4 e2 a−δ Ftotal applied to the electron A = n , (4) 4πε0[(a/2)2+(a−δ)2]3/2 F =f +F +F′. (9) total B x x Figure 5 shows the relationship between total confine- Fx(56) = f5+f6 ment force Ftotal and δ/a for different l with the special e2 a+δ condition Q=+e (or n=1). From the Fig. 5(a), it can = −n , (5) 4πε0[(a/2)2+(a+δ)2]3/2 beseenclearlythattherearetwomainregionswherethe right region indicates the repulsive interaction between electron A and B, while the left region indicates the at- tractiveinteractionbetweentwoelectrons. Furthermore, F(78) = f +f x 7 8 for a given l, as better shown in the enlarged Fig. 5(b) e2 2a−δ that there exists a special position λ (the deviation of = n . (6) l 4πε0[(a/2)2+(2a−δ)2]3/2 the electron from its initial equilibrium position a/2) at 5 º(cid:237)ºØ l (l ) 1 △E ∼ △ξ. (11) ß (cid:238)(cid:239)(cid:240) a e ξ2 l= œ º(cid:237)ºŁ From Eq. (11), it is not difficult to find that the ∇E x e œ canbeeffectivelyreducedbyincreasingξorbydecreasing △ξ. In fact, the physical essence of E can root to the c º(cid:237)º(cid:231) (cid:238)(cid:239)ø energy of △Ee. Physically, we argue that the parameter λ of Fig. 6 is closely related to the △ξ of Eq. (12), for convenience,we assume that they are linearly related by (cid:238)(cid:239)ł º(cid:237)º(cid:236) λ∼△ξ. Thenaccordingtotheaboverelation(λ=1/ξ2) (cid:238)(cid:239)(cid:247) and Eq. (12), the energy E can be simply expressed as: (cid:238)(cid:239)(cid:246) c (cid:238)(cid:239)ı (cid:238)(cid:239)(cid:240)æ (cid:238)(cid:239)(cid:244) (cid:238)(cid:239)(cid:243) 1 1 1 (cid:238)(cid:239)(cid:242) E ∼ △ξ ∼ λ∼ . (12) º(cid:237)ºº c ξ2 ξ2 ξ4 (cid:231) Ł x Ø /a (x Œ/ºa) Œ(cid:236) Œ(cid:231) This equation tells us that in order to obtain a more ß stable superconducting vortex lattice with a higher tem- perature, the stripe-stripe spacing should be sufficiently Figure 6: The relationship between λl (the deviation of the electron from its initial equilibrium position a/2) and ξl/a, increased. Amoredetaileddiscussionwillbegiveninthe where ξl isthespacing of theelectronA and B. Therelation next section. canbequantitativelydescribedasthefollowingequationλ= a2/ξ2, as indicated as the blueline in thefigure. IV. THE EFFECTIVE C-AXIS LATTICE CONSTANT AND THE SUPERCONDUCTING which the force F is equal to zero, indicating a com- CRITICAL TEMPERATURE total pletesuppressionoftheCoulombinteractionbetweentwo electrons. From Fig. 4 and Fig. 5, we can see that as l Basedontheabovediscussions,wewillfurtherexplore increases, the corresponding electron-electron (or stripe- how to enhance the superconducting transition temper- stripe)spacingξ andthe value(λ )ofzeroforceposition ature of the layered superconductors. In our scenario, l will decrease respectively. a higher T means a smaller energy E , consequently, a c c Moreover, according to the numerical results, we can largerξ accordingto Eq. (12). It was pointed out in the obtain the λ as a function ξ /a (where ξ is the spacing previous section, for the doped layered superconducting l l l of the electronA andB) for electronA with l from 1 to materials, there are two ways (the carrier concentration 10, as shown in Fig. 6. The relationship between them andthec-axislatticeconstant)toadjustthestripe-stripe canbequantitativelydescribedasthefollowingequation: λ=a2/ξ2, illustrated as the blue line in Fig. 6. In our theoretical framework, for a stable supercon- Table I: The relationship between the effective c-axis lattice ducting vortex lattice, the superconducting electrons constant c∗ and the highest superconducting transition tem- should develop their self-organized at the correspond- peraturesTcmaxwhichareachievedinthelayeredcuprateand ing equilibrium positions (λ = 0) due to competition iron pnictidesuperconductors so far. l between the stripes. This result implies that the for- mation of an ordered superconducting vortex lattice is Materials c(A˚) c∗(A˚) Tcmax(K) always accompanied by the existence of electromagnetic ∗LBaa21−−xxBKaxxFCeu2OA4s2 1133..221320 66..660165∗∗ 3480 energy (Ec) inside the superconducting phase because ∗(Sr4V2O6)Fe2As2 15.673 7.837∗ 46 of the interaction among the vortex lines. This energy ∗SmO1−xFxFeAs 8.447 8.447 55 may directly influence the stability of the superconduct- La2Ca1−xSrxCu2O6 19.420 9.710∗ 60 ingvortexlatticeandthecorrespondingsuperconducting DyBaSrCu3O7 11.560 11.560 90 transitiontemperatureofthesuperconductor. Inthefol- Tl2Ba2CuO6+δ 23.239 11.620∗ 92 lowing, we will discuss qualitatively which factors might YBa2Cu3O7−δ 11.676 11.676 93 influence the energy Ec. We know that the interaction Sr2CuO3+δ 12.507 12.507 95 energy between two electrons spaced ξ apartcan be pre- Sr2−xBaxCuO3+δ 12.780 12.780 98 sented by TlCaBa2Cu2O7 12.754 12.754 103 ∗ Tl2CaBa2Cu2O8 29.318 14.659 119 1 (Tl0.5Pb0.5)Sr2Ca2Cu3O9 15.230 15.230 120 Ee ∝ . (10) Hg2Ba2Ca2Cu3O8 15.850 15.850 133 ξ HgBa2Ca2Cu3O8+δ 16.100 16.100 136 ∗ ∗ Tl2Ca2Ba2Cu2O10 35.900 17.950 128 Supposethe distancebetweentwoelectronsdecreasesby ∗ Hg2Ba2Ca3Cu4O10 19.008 19.008 126 △ξ, then the interaction energy E will increase by e 6 c ToobtaintheanalyticalrelationshipbetweentheTmax T =10 - 28 c (cid:254)(cid:253)(cid:255) (cid:20)(cid:21)(cid:22) (cid:24) andc∗,theexperimentalresultsofTableIarerepresented (cid:23) + in Fig. 7. Surprisingly, except for the last two samples (cid:254)(cid:252)(cid:255) (cid:25)(cid:6)(cid:25)(cid:4) + (Tl2Ca2Ba2Cu2O10 and Hg2Ba2Ca3Cu4O10), the figure showsclearlythatalloftheexperimentaldataalmostfall (cid:25)(cid:5)Z(cid:4) on a same straight line which can be described with the (cid:254)(cid:0)(cid:255) equation: K) (cid:254)(cid:3)(cid:255) 687 9: BCD ( 4345 ?>=A= Tcmax =10c∗−28. (13) TEFGc (cid:254)(cid:255)(cid:255) /02131;<>=?@= It should be emphasized that the Eq. (13) proposed here has its scope of applicationsince our superconduct- (cid:253)(cid:255) ing mechanism requires an effective competition among ∗ (cid:6)(cid:2)(cid:4) electrons and stripes, too intensive (for a small c ) or (cid:252)(cid:255) ∗ (cid:5)(cid:2)(cid:4) %& too weak (for a large c ) competition is not conducive ’ (cid:0)(cid:255) (cid:1)(cid:2)(cid:4) (cid:26)(cid:27) (cid:7)(cid:8)(cid:9)(cid:10)(cid:11)(cid:12)(cid:13)()*+*+,-. tisoetshteimfaotremdatfiroonmoEf qs.upe(1rc3o)ntdhuacttinwghevnorct∗exislaltetsiscet.haInt (cid:3)(cid:255) (cid:28)(cid:29)(cid:30)(cid:31)(cid:30) !"#(cid:14)$(cid:15)(cid:16)(cid:17)(cid:12)(cid:18)(cid:19)(cid:12) 2h.i8bÅit,tthheescuoprerrecsopnodnudcintigvitlayy.erOedf cmouatresrei,altshecraenmnuosttebxe- " ∗ a maximum value of c which also led to the failure max (cid:255) of the establishment of the superconducting vortex lat- (cid:252) (cid:253) (cid:254)(cid:255) (cid:254)(cid:3) (cid:254)(cid:0) (cid:254)(cid:252) (cid:254)(cid:253) (cid:3)(cid:255) tice inside the materials. We note from the figure that, HIJJKKJLMNOJLPQRNSTQMMNLJLUVSMQVMWXY as unexpected, the superconducting transition tempera- Figure 7: The relationship between the experimental data turesofTl2Ca2Ba2Cu2O10 andHg2Ba2Ca3Cu4O10 devi- ofthehighestsuperconductingtransitiontemperaturesTcmax ate seriously from the linear equation of Eq. (13). We and the newly defined parameter of effective c-axis lattice thinkthattheremaybetworeasonsforthesedeviations. ∗ constant c for the layered cuprate and iron pnictide super- First, since the carrier concentrations of these two su- conductors. We argue that the possible maximum Tcmax for perconductors are unadjustable, it is likely that the vor- SmO1−xFxFeAs of 55 K (1111 series), (Sr4V2O6)Fe2As2 of tex lattices are not in best consistent with those of the 46 K (21311 series) and Ba1−xKxFe2As2 of 38 K (122 series) crystal structures. Second, their effective c-axis lattice cannot exceed 60 K, 50 K and 40 K, as indicated by three constants have been very close to the maximum value of cyan lines in thefigure. c∗ . Personally,we believe that the maximum Tmax of max c the cuprate superconductors may be raised to the theo- reticalvalue (about 161K,as markedinFig. 7) without spacing ξ inside the superconductors. Our theory sug- applying of the external pressure. Then, can we predict gests that the changing of the carrier concentration can thelimitsoftheTmaxaccordingtoourtheory? Fromthe c only modestly increaseTc, while the increasingofthe ef- viewpoint of lattice stability and competition among su- fectivec-axislatticeconstantcanleadtoasignificanten- perconductingelectrons,amaximumvalueofc∗ values max hancement of Tc of the superconducting materials. This rangefrom19Å(thec∗ ofHg2Ba2Ca3Cu4O10 )to19+3Å argument has been well confirmed by numerous exper- (where 3Å is about the thickness of two atomic layers). imental investigations in the cuprate and iron pnictide Hence by Eq. (13), we conclude that the limits of the superconductors, as shown in Table I and Fig. 7. Tmax(∼ 192K) is very difficult to break through 200 K c Table I shows the experimental data of the c-axis lat- in three-dimensional bulk superconductors. tice constant c and the highest superconducting tran- As is well known, soon after the discovery of the iron- sition temperatures Tmax for the layered cuprate and based superconductors, some physicists have believed c newly discovered iron pnictide superconductors. Also in room temperature superconductivity may be possible in Table I, we introduce the effective c-axis lattice constant these new compounds. We think that these predictions ∗ ∗ c whichcanbe dividedintotwodifferentclasses: c =c are apparently lack of solid scientific basis. As can be ∗ and c =c/2 depending on the number of the supercon- found from Table I and Fig. 7, the experimental data of ducting planes inside a unit cell of the superconductors. three iron-basedsuperconductors: SmO1−xFxFeAs of 55 The former class indicates that the superconducting lay- K (1111 series),5 Ba1−xKxFe2As2 of 38 K (122 series)16 ers are separated by a distance of the c-axis lattice con- and(Sr V O )Fe As of46K(21311series)17 According 4 2 6 2 2 stant, while the superconducting layer-layer separation to the theory suggested in this paper, we argue that the along the c-axis is reduced by half for the later class. possible maximum Tmax for 1111, 122 and 21311 series c Importantly, although the crystal structure and physical cannot exceed 60 K, 40 K and 50 K, as indicated in Fig. property vary considerably among the superconductors, 7 (three cyan lines). it is easy to find that the Tmax increases monotonically Furthermore, we will show that our theory can pro- c withtheincreasingoftheeffectivec-axislatticeconstant. vide a qualitative explanation of why the superconduc- 7 tivity does not occur in noble metals (for example, Ag, (a) (b) }~ Au, and Cu) and a also new insights into the problemof the superconductivity in metallic hydrogen. It is a com- mon knowledge that gold, silver and copper are the best | conductorsofelectricalcurrent. However,aquestionhas long plagued the physics community: why an ideal con- {zxyz ductor that is not a superconductor? With the help of the Fig. 2 and Eq. (13), we try to unravel this mys- [[ [(cid:149)(cid:150)(cid:151) tery in a very simple way. Under normal circumstances, good conductors always have an extremely high level of carrierconcentration. One canassume thatthese metals vwxyz have the superconducting properties, in our view, it is necessary that the superconducting electrons should be [(cid:149)(cid:150)(cid:151)(cid:152)(cid:153) arrangedasthe specificvortexlatticesofFig. 2withthe \]^_‘abcdefg stripe-stripe spacingsξ ∼2Å(≪2.8Å). In this case,the hijklmjnnopqqrimstu crowded vortex lattices are unstable owing to the strong ( ) ( ) electromagnetic interactions between vortex lines, as a (cid:127)(cid:128) (cid:132)(cid:128)(cid:133)(cid:134)(cid:135) (cid:137)(cid:139)(cid:140)(cid:141)(cid:142) (cid:143)(cid:144) (cid:132)(cid:128)(cid:133)(cid:134)(cid:135) d (cid:137)(cid:139)(cid:147)(cid:148)(cid:142) result,thechargecarriersaremorelikelytobeformedin (cid:129)(cid:130)(cid:131) (cid:131) (cid:136) (cid:138) (cid:129)(cid:130)(cid:131) (cid:131) (cid:145)(cid:146) (cid:138) a random and lower-energy stable non-superconducting Figure8: Twoanalogoussuperconductors(a)La2−xBaxCuO4 phase. Thesediscussionscanalsobeappliedtothe over- of40K,and(b)Sr2−xBaxCuO3+δ of98K.Inourtheoretical doped high-T superconductors where the stripe-stripe framework of the effective c-axis lattice constant, they have c spacinginsidethesuperconductingCuOplanesisfarless completely different relation between the c-axis lattice con- ∗ ∗ stant c and the effective c-axis lattice constant c : c = c/2 than 2.8Å. for La2−xBaxCuO4 with two superconducting planes inside Physicists predicted that hydrogen in solid-state can one unit cell, while c∗ = c for Sr2−xBaxCuO3+δ with only be a high-temperature superconductor, and maybe even onesuperconductingplaneinsideoneunitcell. Wethinkitis a room-temperature superconductor. Indeed, this pre- thedifferenceoftheeffectivec-axislatticeconstantthatleads diction sounds very interesting and attractive, but we totheverydifferencebetweentwosamplesinsuperconducting would like to point out that it cannot be realized as de- transition temperature. sired. Fromtheperspectiveofatomicstructure,thereare the same number of carriers (free electrons) in metallic hydrogen, lithium (BCC, a = b = c = 3.51Å), sodium which look very similar to that of La2−xBaxCuO4 but (BCC, a = b = c = 4.29Å) and potassium (BCC, with partially occupied apical oxygen sites, as shown in a=b=c=5.33Å)withthesamenumberofatoms. The Fig. 8(b). Why can two almost the same superconduct- theoretical predicted lattice constants of metallic hydro- ing materials have completely different superconducting gen (BCC, a=b=c=2.89Å) are smaller than those of transition temperatures? Although several factors have theotherthreematerials,indicatingthatmetallichydro- beenconsideredinwhatenhancetheTc,18itisintuitively gen has the highest carrier concentration among them. obvious that the actual reason has not been elucidated As lithium, sodium and potassium do not exhibit super- yet. In our theoretical framework of the effective c-axis conductivity,nowwecanboldlypredictthatthemetallic lattice constant, it is most likely that the introducing of hydrogen with the highest carrier concentration cannot partially occupied apical oxygen sites could cause one of beasuperconductoratanylowtemperature,nottomen- theCuOlayersnolongertofunctionasthesuperconduct- tion the room temperature superconductivity. ingplane. Therefore,thetwoanalogoussuperconductors ofFig. 8havecompletelydifferentrelationbetweencand Finally, it is worth to note that the suggested real- ∗ ∗ ∗ space effective c-axis lattice constant theory of super- c : c =c/2forLa2−xBaxCuO4ofFig. 8(a),whilec =c conductivity has been excellently confirmed by recent for Sr2−xBaxCuO3+δ of Fig. 8(b). From the experi- measurements.18 Fig. 8(a) shows a unit-cell of cuprate mental results of Sr2−xBaxCuO3+δ (c∗ = c = 12.78Å)18 and Eq. (13), one can get immediately Tmax ≈ 99.8 K La2−xBaxCuO4of 40 K with the c-axis lattice constant c which is in good agreementwith the experimental result c = 13.23Å. It is easy to find from the figure that (Tmax ≈98 K).18 superconducting layer (CuO plane) spacing (the effec- c tive c-axis lattice constant) of the superconductor is ∗ c = c/2 = 6.615Å. If there are experimental methods thatcancauseoneoftheCuOplanetolosetheabilityof V. CONCLUDING REMARKS conductingsuperconductingcurrent,thentheeffectivec- ∗ axislatticeconstantcanbepromotedtoc =c=13.23Å, We have proposed the real-space effective c-axis lat- consequently,the correspondingmaximumTmax maybe tice constant theory of superconductivity based on the c dramatically enhanced to 104 K calculated according to self-organized picture of the superconducting electrons Eq. (13) . This prediction has just been experimen- and studied the stability of the superconducting vortex tallyverifiedbyGaoetal.18incuprateSr2−xBaxCuO3+δ lattices in layered superconductors. It has been shown 8 clearlythattheeffectivelatticeconstantplayasignificant (La2−xBaxCuO4 of 40K andSr2−xBaxCuO3+δ of98 K) role in promoting the superconducting transition tem- would have such a different superconducting transition perature inlayeredsuperconductors,suchas the copper- temperatures,thelatterisabout2.5times oftheformer. based and newly discovered iron-based compounds. Ac- The physical reasonwhy the superconductivity does not cordingto a largenumber of experimentaldata,we have occur in gold, silver and copper has also been provided obtainedanimportantequation: Tmax =10c∗−28which basedonthesuggestednewmechanism. Finally,wehave c can be used to estimate the highest possible Tmax for a argued that the metallic hydrogencannot exhibit super- c ∗ givenlayeredsuperconductor,where c is the effective c- conductivity at any low temperature. We think that the axis lattice constant. This result suggests that the max- real-space effective c-axis lattice constant theory of su- imum possible Tmax of the iron-based superconductors perconductivity may finally shed light on the mysteries c cannot exceed 60 K, 50 K and 40 K for the 1111, 21311 of superconductivity. With these results, the scientists and 122 series, respectively. It should be noted that this will be able to proceed to the materials design for the predictionhas stood the test oftime for abouttwo years new superconductors that may have a higher supercon- by many experiments. Furthermore, we have tried to ducting transition temperature. explain why two very similar cuprate superconductors ∗ Electronic address: [email protected] 11 X.Q. 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