Most massive stars exchange mass with a companion, leading to evolution which is altered drastically from that expected of stars in isolation. Such systems are the result of unusual binary evolution pathways and, as such, may be used to place stringent constraints on the physics of these interactions. We use the R4 systems B[e] supergiant, which has been postulated to be the product of a binary stellar merger, to guide our understanding of such outcomes by comparing observations of R4 to the results of simulations of mergers performed with the 3d hydrodynamics code FLASH. Our approach tailors the simulation initial conditions to the observed properties of R4 and implements realistic stellar profiles generated by the 1d stellar evolution code MESA onto the 3d grid, resolving the merger inspiral to within $0.02, R_{odot}$. We then map the merger remnant into MESA to track its evolution on the HR diagram over a period of $10^4$ years. This generates models for a B[e] supergiant with stellar properties, age, and nebula structure in qualitative agreement with that of the R4 system. Our calculations provide concrete evidence to support the idea that R4 was originally a member of a triple system in which the inner binary merged after its most massive member evolved off the main sequence, producing a new object that is of similar mass yet significantly more luminous than the A supergiant companion. The potential applications of the code framework presented in this paper are wide ranging and can be used to generate models of a variety of merger stellar remnants.
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