First order reversal curves (FORC) diagrams of Co nanowire arrays.

Nanowire arrays of Co and Ni have been obtained by current pulse electrodeposition into nanoporous alumina templates. By adjusting the pH of the bath, the microstructure of the Co wires was tailored, resulting in two types of arrays of crystalline Co--hcp, with c-axis nominally parallel (Co (c parallel)), or nominally perpendicular (Co (c perpendicular)) to the wire. First-order reversal curve (FORC) diagrams provide information on average coercivity of the individual nanowire and the factors influencing the field created in the saturated array by the magnetostatic interactions.

Magnetostatic interactions and coercivities of ferromagnetic soft nanowires in uniform length arrays.

First-order reversal curve diagrams have been used to investigate magnetostatic interactions and average coercivity of individual wires in soft ferromagnetic uniform length nanowire arrays. We present a method for identifying these physical parameters on the out-of-plane first-order reversal curve diagrams: the position of the irreversible part on the critical axis is a good approximation to the average value of the nanowire coercivity and the maximum interaction field is equal to the interaction field at saturation. Their dependence upon material (CoFeB and Ni) and nanowire length are presented.

Minimal steric difference study of structural requirements for the luteinizing hormone-releasing hormone (LH-RH) receptor.

Quantitative structure-activity relation for amino acid substitution analogues of the LH-RH decapeptide were established by means of the receptor site mapping procedure based upon minimal steric differences. For a series of 17 analogues of LH-RH, obtained by substitutions of the C-terminal Gly-NH2 residue, a corelation coefficient r = 0.93 was obtained, for a series of 7 analogues, obtained by substitutions of the Leu7 residue, r = 0.