The structure of water-saturated Ca- and Mg-bearing carbonate melts under reducing and oxidizing conditions was investigated in a series of hydrothermal anvil cell experiments conducted at 400 - 1100 ^oC and 442 - 2839 MPa. Equilibria were investigated in the calcite-H₂O, calcite-CaO-H₂O, magnesite-H₂O and magnesite-MgO-H₂O systems, with redox conditions controlled by Re/ReO₂ and Ti/TiO₂ assemblages. Melting relationships and the C-O-H speciation of the coexisting aqueous fluid and melt were assessed in-situ by Raman vibrational spectroscopy. Hydrous melting of MgCO₃-MgO occurred at ~ 850 ^oC, 1.5 - 2 GPa. In the CaCO₃-CaO-H₂O system, melt was formed at 600 - 900 ^oC and pressures of 0.5 - 1.5 GPa because of melting-point depression imposed by the presence of CaO. The C-O-H speciation of the carbonate melts and coexisting supercritical aqueous solutions was mainly H₂O and CO₃^2-, with traces of CO_2(aq) and CH_4(aq) in the fluid phase. The melt-fluid H₂O partition coefficients attained in the Mg-bearing melt (median 0.5) were higher than in the Ca-bearing melt (median 0.3). Under oxidizing redox conditions, dissolved ReO^4- was present in all phases, underscoring the enhanced solubility of trace elements and metals in carbonate-bearing melts and carbonatites. In effect, the enhanced solubility of H₂O along with the ionic nature of the carbonate melts may promote the solvation of ionic species in the melt structure.From in-situ vibrational spectroscopy, the v₁-CO₃^2- vibration recorded in the melt spectra suggests the presence of intermolecular interactions between the oxygen of the carbonate ion with water dissolved in the melt. The thermodynamic properties of this water appear to be similar to the supercritical aqueous phase. For example, the estimated enthalpy for the breakage of the hydrogen bonding between water molecules attained values of 6.8 ± 1.5 kcal/mol and 8.4 ± 1.3 kcal/mol in the melt and fluid phase, respectively. The calculated partial molar volume of H₂O in the melt (~ 48 ± 6 cm³/mol) is also comparable to the partial molar volume of supercritical water at similar conditions. Interestingly, this value is considerably greater than published partial molar volume values for H₂O in silicate melts (10-12 cm³/mol).The pressure-temperature melting relationships of the CaO-CO₂-H₂O and MgO-CO₂-H₂O systems highlight the important role of water and alkali earth oxides on the hydrous melting of the carbonate-bearing subducting oceanic crust. Carbonates present in marine sediments or serpentinized peridotites may melt before complete dehydration at the slap-mantle wedge transition zone, and thus, never reach sub-arc depths. To this end, melting of carbonate minerals at crustal temperatures and pressure can contribute to the volcanic CO₂ flux at the arc through melt/fluid interactions.