We performed zero and transverse field µSR experiments on a large number of YBa2Cu3O6+x samples. We detect coexistence of antiferro-type (AF) short range magnetism with superconductivity below T f 10 K in compositions 0.37 x 0.39. Most muons experience local AF fields, even when SQUID detects a full superconducting volume fraction, which points to a local minimal interference organization of short AF stripes embedded in the superconductor. A detailed phase diagram is produced and the consequences of the minimal interference are discussed. Neutron scattering also detects magnetic correlations, notably [10] in YBa 2 Cu 3 O 6.35 , exclusively dynamic in nature, although their static counterpart could be elusive due to a very short correlation length. The doubled magnetic unit cell indicates an antiferromagnetic (AF) structure, with a suggested stripe-like character.In all the samples explored so far by µSR [5,6,7,8,9] it has been hinted that the cluster spin glass nature of magnetism (low spin freezing temperature, T f , large distributions of B i and absence of long range order as from neutron diffraction [11,12]) might be favored by the disorder inherent in cation substituted perovskites, which directly influences the CuO 2 layers. Conversely in YBa 2 Cu 3 O 6+x (123, hereafter) the source of disorder, namely the basal CuO x layers, are farther removed from the CuO 2 layers, but systematic µSR data were lacking, prior to the present work. Our aim is to clarify whether the appearance of coexisting superconducting and magnetic properties is indeed intrinsic to the unperturbed underdoped CuO 2 layers and whether the two properties cooperate or interfere.We performed µSR measurements on twenty-four polycrystalline 123 samples (Y 1−24 ) prepared by the topotactic technique, which consists of oxygen equilibration of stoichiometric quantities of the two end member specimens, tightly packed in sealed vessels [13]. Low temperature annealing yields high quality homogeneous samples with an absolute error of δx=±0.02 in oxygen content per formula unit and a much smaller relative error between samples of the same batch. The width of the interval were the resistance drops from 90% to 10% of the onset value is 0.5 K at optimal doping and 6-7K at x 0.4 (vs. e.g. 10K in Ref.10). The hole content h was determined from the resistive T c for the superconducting samples [14], and from the Seebeck coefficient S at 290 K for the non-superconducting ones, using the exponential dependence [14] of S on h, with fit parameters determined from our series of samples [15]. Samples Y 1−8 , with oxygen content 0.20≤x≤0.32 and hole content per planar Cu atom 0.033≤h≤0.055, never superconduct, and their AF properties were reported previously [16]. Samples Y 9−24 , with 0.32≤x≤0.42 and 0.055≤h≤0.08, are superconductors and are the subject of the present work.The µSR experiment were performed on the MUSR spectrometer of the ISIS pulsed muon facility, where the external magnetic field H may be applied either parallel to the initial muon spin S µ , in...
