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Abstract

The subject of viscoelastic flow phenomena is crucial to many areas of engineering and the physical sciences. Although much of our understanding of viscoelastic flow features stem from carefully designed experiments, preparation of model viscoelastic fluids remains an outstanding challenge; for example, fabricating a series of fluids with varied fluid shear moduli $G_0$, but with an identical relaxation time $\tau$, is nontrivial. In this work, we harness the non-ideality of nearly constant-viscosity elastic fluids (commonly known as `Boger fluids') made with polyisobutylene to develop an experimental methodology that produces a set of fluids with desired viscoelastic properties, specifically, $G_0$, $\tau$, and the first normal stress difference coefficient $\psi_1$. Through a simple linear algebraic manipulation between the rheological properties of interest ($G_0$, $\tau$, $\psi_1$) and the fluid compositions in terms of polymer concentration $c$, molecular weight $M_w$, and solvent viscosity $\eta_s$, we developed a `design equation' that takes $G_0$, $\tau$, $\psi_1$ as inputs and calculates values for $c$, $M_w$, $\eta_s$ as outputs. Using this method, fabrication of sample viscoelastic fluids whose rheological properties are \textit{a priori} known can be achieved.