The effect of pressure and temperature on the structure of silicate melts coexisting with silica-saturated aqueous electrolyte solutions enriched in fluorine or chlorine in the Na₂O-Al₂O₃-SiO₂-H₂O system has been determined. In-situ measurements were conducted with the samples at desired temperatures and pressures in a hydrothermal diamond anvil cell (HDAC) by using microRaman and FTIR spectroscopy techniques. The data were acquired at high temperature and pressure (up to 800oC and 1264 MPa, respectively), and during cooling/decompression to ambient conditions.The intensity of the Raman bands assigned to stretch vibration of the OH-groups relative to those of coexisting molecular H₂O in silicate melts is lower in the presence of F and Cl. This difference reflects the interaction of F or Cl with H₂O in the melts. With decreasing pressure and temperature (P-T) conditions, SiF complexes are favored in the melt rather than in the fluid, perhaps because of decreasing silicate concentration in fluids with decreasing temperature and pressure. In melts, the solubility of Cl, likely in the form of NaCl_(aq), increases with decreasing P-T conditions, whereas the abundance of such complexes in coexisting fluids decreases.Our experiments data were employed to help model the ascent of a magma-fluid system from the upper mantle to the shallow crust. The information offers particular insights into F and Cl partitioning between and the speciation of F and Cl in melts and magmatic fluids. We suggest that the formation of stable SiF and NaCl complexes and their increasing solubilities during magma ascent explain the late volcanic degassing of F and Cl, compared to other volatile species. It explains why F and Cl are often undersaturated in arc basaltic magmas (Carroll and Webster, 1994), indicating that they often do not a significant experience a degassing event. In contrast to H₂O, CO₂ and S, F and Cl signature in primary arc magmas (arc melt inclusions) can be consider as primary and likely retain information on arc magma sources. Those results also imply that, while Cl is enriched in aqueous fluids from slab dehydration, F preferentially dissolves in slab melts or supercritical fluids, during flows from the subducted slab into the zone of melting in the mantle wedge. It is therefore expected that at given pressure and temperature, the Cl/F ratio is significantly lower in slab melt and supercritical fluids, than in aqueous fluids. This difference in Cl/F signatures decrease when slab components are dragged down to the deep mantle.