Knowledge of how molecular fluids’ thermodynamic and rheological properties change is of considerable importance from both theoretical and industrial perspective. Using non-equilibrium molecular dynamics simulations, we performed three computer experiments of basic flow fields, namely, steady state shear flow, oscillatory shear flow, and nano-extrusion flow. In steady state shear flow of liquid n-hexadecane under different temperatures, pressures, and densities, material functions—the shear rate dependence of viscosity, first and second normal stress coefficients—present shear thinning phenomena. At extreme shear rates, specific behavior of shear dilatancy is observed in the variations of non-equilibrium thermodynamic states. More importantly, viscoelastic material functions of oscillatory shear flows—storage and loss moduli, and phase angle—can be obtained while two significant corroborated manifestations are that the n-hexadecane fluid undoubtedly possesses linear viscoelasticity and thermorheological simplicity. Viscoelastic spectra, the frequency dependence of storage and loss moduli, determine the phase of the fluid: a solid-like state, liquid-like state, and gel-like state. Furthermore, nano-extrusion flows of linear short polyethylene chains that were uniformly extruded by a constant-speed piston into surrounding vacuum from a reservoir through an abrupt contraction nozzle were built. Since the length of a molecular chain is larger than the nozzle diameter, we are interested in understanding how a molecular chain flows through the nozzle region. Molecular motions are explored during contraction flow while the velocity and temperature profiles in the nozzle region are presented. Similar to capillary rheometer, the relationship between the apparent shear viscosity and shear rate for the isothermal nozzle region emerges obviously both important characteristics—first-Newtonian plateau and shear thinning slope.