A slit viscometer was designed and fabricated, which could be applied for studying the magneto-viscosity of low viscosity (about 1 cP) magnetic nanofluids. The validity of the measurement using the slit viscometer was checked against measurement using a commercial Brookfield viscometer with kerosene and Fe3O4-Kerosene nanofluids. The main findings are as follows. (i)The theory of the slit viscometer is based on the analytical solution of the steady fully-developed flow in a square straight channel. The channel was fabricated on an acrylic sheet using precision machining. The test fluid was pumped through the channel using a syringe pump. The viscosity was accessed through the pressure drop in the channel measured via a manometer. The magnetic field was applied through two permanent magnet plates sandwiching the channel from the top and bottom wall (for generating field perpendicular to the flow vorticity) or from both side walls (for generating field parallel to the flow vorticity); and the field strength was adjusted by varying the distance between those two magnets. (ii) Fe3O4 nano particles were generated using chemical co-precipitation method, coated with oleic acid, and then dispersed into kerosene for synthesizing stable nanofluids. The average diameter of the particle monomer was measured as 9 nm, and the average diameter of the suspended particles in nanofluid is 30 nm. (iii) Magnetization curves of nanofluids at different volume fractions (1 – 4%) were measured, and it was found the magnetization increases as both the volume fraction and the magnetic field strength increase. (iv)As for the magneto-viscosity, we have performed measurements using different volume fractions (1 – 4%), magnetic field directions, magnetic field strengths (200 – 500 Gauss), shear rates (70 – 189 s-1), aspect ratio of the channel (8 or 12)、and the times for measurement after the fluids were synthesized. We found: (1) Viscosity enhancement increases as both the volume fraction and the magnetic field strength were increased. For example, the viscosity increase was 68% for a shear rate 70 s1, a volume fraction 4%、and moderate field strength 500 Gauss applied perpendicular to the flow vorticity. (2) The viscosity increase when the magnetic field is perpendicular to the flow vorticity is about 3 – 4 times greater than that when the field is parallel to flow vorticity. (3) Shear thinning is obvious; the reduction of the viscosity increase increases as both the volume fraction and shear rate increase. For example, the 59% viscosity increase at a shear rate 70 s1 is reduced to 33% at 190 s1 for a fluid with volume fraction 4% under a field applied perpendicular to the vorticity at 500 Gauss. (4) Viscosity increase was reduced by about 60% and would be stable three weeks later after the fluid has been synthesized. (5) Effect of aspect ratio of the channel on magneto-viscosity and shear thinning are minor.