The Hall constant R H in a tight-binding model of correlated electrons on a ladder at T 0 is expressed in terms of derivatives of the ground state energy with respect to external magnetic and electric fields. This novel method is used for the analysis of the t-J model on finite size ladders. It is found that for a single hole R H is holelike and close to the semiclassical value, while for two holes it can vary with ladder geometry. In odd-leg ladders, R H behaves quite regularly changing sign as a function of doping, the variation being quantitatively close to experimental results in cuprates. PACS numbers: 71.27. + a, 71.10.Fd, 72.15.Gd The Hall response in materials with strongly correlated electrons remains one of the properties least understood theoretically. The subject has been stimulated by experiments in superconducting cuprates [1], revealing anomalous doping and temperature dependence of the Hall constant R H ͑T ͒ in the normal metallic state. For instance, it is well established that the Hall effect is holelike, R H . 0, in materials with a low density of holes n h , introduced by doping the reference antiferromagnetic (AFM) insulator. The clearest realization is La 22x Sr x CuO 4 (LSCO), where the doping x can be directly related to the concentration of mobile holes per unit cell n h x and the semiclassical result R H 1͞n h e 0 seems to be obeyed at lowest T . T c and at low doping [1,2].Theoretical attempts to calculate the Hall effect in models of strongly correlated electrons resulted in quite controversial conclusions. Even for weak correlations [3] or for the problem of a single carrier in a Mott-Hubbard insulator [4], the analysis of the Hall response is fairly involved. In more recent investigations relevant to cuprates, the dynamical Hall constantR H ͑v͒ has been studied within linear response theory for the t-J and Hubbard models, analytically by high-v, T expansion [5] and numerically via exact-diagonalization studies of small systems [6,7]. The obtained results are quite consistent for the high-frequency quantity R ء H R H ͑v !`͒, showing at high T a transition from a holelike, R ء H . 0, to an electronlike, R ء H , 0, at a finite crossover n ء h ϳ 1͞3 [5]. For the most interesting dc limit R H R H ͑v 0͒ the majority of results obtained for 2D systems at low doping and T ! 0 indicate R H , 0 [7], instead of the expected holelike behavior [8]. On the other hand, one of the present authors [9] recently showed that for a single hole doped into a 2D AFM at T 0 the result should be the semiclassical one with R H . 0.From another perspective and stimulated by synthesis and experiments on novel cuprates, models of interacting electrons on ladder systems have also been extensively studied in recent years [10]. The idea is that ladders with a variable number of legs can offer a broader insight into the behavior of correlated electrons and thus can lead to an understanding of the more challenging 2D systems. Again, results for the Hall responseR H ͑v͒ at low doping obtained through linear ...
