The metastable phase diagram of the two-component system heptyloxycyanobiphenyl (7OCB)+nonyloxycyanobiphenyl (9OCB) was determined by means of modulated differential scanning calorimetry (MDSC) and optical microscopy measurements. It was experimentally established that the 7OCB+9OCB two-component system exhibits a monotropic re-entrant nematic behavior. A complete quantitative thermodynamic analysis, through Oonk's equal G analysis, was performed, allowing for the calculation of the monotropic re-entrant behavior and the prediction of two tricritical points, one of them experimentally accessible for the SmA(d)-to-N transition and the other non-experimentally accessible for the RN-to-SmA(d) transition. From specific-heat measurements, latent heats were obtained for those mixtures displaying a first-order SmA(d)-to-N transition. Additionally, for some mixtures, the specific-heat critical exponents (alpha), through the second-order SmA(d)-to-N transition, were obtained. Both batches of data enable us to access to the experimental tricritical temperature for the SmA(d)-to-N transition.