Rotational state-resolved differential cross sections (DCS) for spin-multiplet-changing collisions of NO(X (2)Pi(1/2)-->X (2)Pi(3/2)) with Ar are presented and compared to results from previous experimental and theoretical studies performed on the NO/Ar system. A crossed molecular beam apparatus coupled with velocity-mapped ion imaging was used to measure complete (theta=0degrees-180degrees) DCS for scattering of NO(X (2)Pi(1/2),j=0.5) into NO(X (2)Pi(3/2),j(')) rotational states ranging from j(')=1.5 to j(')=12.5. Scattered products were detected by state-selective ionization using (1+1') resonance-enhanced multiphoton ionization via the A (2)Sigma(+) state. State-to-state DCS were extracted in the center-of-mass frame of reference for energy transfer at a center-of-mass collision energy of similar to530 cm(-1). Studies performed using horizontally and vertically polarized excitation laser beams yielded DCS which were remarkably similar, indicating that state-to-state scattering for this system is insensitive to probe beam polarization. Experimentally determined angular scattering distributions show primarily forward scattering for low-energy rotational states (j<7.5), with side- and back-scattering increasing with product angular momentum. The scattering results are compared and contrasted to results from earlier experimental investigations and to theoretical results from quantum close-coupling calculations based on ab initio coupled cluster CCSD(T) potential energy surfaces.