Integrated hydrothermal process to upgrade heavy oil

That which is claimed is: 1. An integrated hydrothermal process for upgrading heavy oil, the integrated hydrothermal process comprising the steps of: mixing a heated water stream and a heated feed in a mixer to produce a mixed fluid, wherein the heated water stream is supercritical water, wherein the heated feed is at a feedstock temperature less than 300 deg C. and a feedstock pressure greater than the critical pressure of water; introducing the mixed stream to a reactor unit to produce a reactor effluent; allowing conversion reactions to occur in the reactor unit, wherein the reactor unit is maintained at a temperature greater than the critical temperature of water and at a pressure greater than the critical pressure of water, wherein the conversion reactions are operable to upgrade the hydrocarbons in the mixed fluid such that the reactor effluent comprises light fractions, heavy fractions, and water; cooling the reactor effluent in a cooling device to produce a cooled fluid, where the cooled fluid is at a temperature less than the critical temperature of water and less than the temperature of the reactor effluent; depressurizing the cooled fluid in a depressurizing device to produce a depressurized fluid, where the depressurized fluid is at a pressure less than the steam pressure corresponding to the temperature of the cooled fluid such that water in the depressurized fluid is present as steam; introducing the depressurized fluid to a flash drum; separating the depressurized fluid in the flash drum to produce a light fraction stream and a heavy fraction stream, wherein the light fraction stream comprises the light fractions and water, wherein the heavy fraction stream comprises the heavy fractions and water, wherein the heavy fraction stream comprises a water content between 0.1 wt % and 10 wt %; introducing the heavy fraction stream to an aqueous reforming unit; and allowing upgrading reactions to occur in the aqueous reforming unit to produce an aqueous reforming outlet, wherein the aqueous reforming unit comprises a catalyst, wherein the catalyst is operable to catalyze the upgrading reactions in the presence of steam, wherein the aqueous reforming outlet comprises a greater concentration of light fraction relative to the heated feed. 2. The integrated hydrothermal process of claim 1 , further comprising the steps of reducing the temperature of the light fraction stream in a lights cooling device to produce a cooled light fraction, wherein the cooled light fraction is at a temperature of 50 deg C; introducing the cooled light fraction to a lights separation zone; and separating the cooled light fraction in the lights separation zone to produce a gas product, a petroleum product, and a water product. 3. The integrated hydrothermal process of claim 2 , further comprising the step of: introducing the petroleum product to a hydrogenation unit to produce a hydrogenated product. 4. The integrated hydrothermal process of claim 2 , further comprising the steps of: separating a slip stream from the gas product; introducing the slip stream to a gas sweetening unit; removing an amount of hydrogen sulfide from the slip stream to produce a sweetened gas stream; and introducing the sweetened gas stream to the aqueous reforming unit. 5. The integrated hydrothermal process of claim 1 , further comprising the steps of: mixing the aqueous reforming outlet and the light fraction stream in a product mixer to produce a mixed fraction; reducing the temperature of the mixed fraction in a lights cooling device to produce a cooled mixed fraction, wherein the cooled mixed fraction is at a temperature of 50 deg C; introducing the cooled mixed fraction to a lights separation zone; and separating the cooled mixed fraction in the lights separation zone to produce a gas phase product, a petroleum phase product, and a water phase stream. 6. The integrated hydrothermal process of claim 1 , further comprises the steps of: increasing a pressure of a petroleum feed in a feed pump to produce a pressurized feed, wherein a pressure of the pressurized feed is greater than the critical pressure of water; increasing a temperature of the pressurized feed in a feed heater to produce the heated feed, wherein the heated feed is at the feedstock temperature; increasing a pressure of a water stream in a water pump to create a pressurized water, wherein a pressure of the pressurized water is greater than the critical pressure of water; and increasing a temperature of the pressurized water in a water heater to produce the heated water stream. 7. The integrated hydrothermal process of claim 6 , wherein the petroleum feed is selected from the group consisting of whole range crude oil, reduced crude oil, atmospheric distillates, atmospheric residue streams, vacuum distillates, vacuum residue streams, cracked product streams, decanted oil, C10+ oil, liquefied coal, and biomaterial-derived hydrocarbons. 8. The integrated hydrothermal process of claim 1 , wherein the catalyst is selected from the group consisting of a homogeneous catalyst and a heterogeneous catalyst. 9. The integrated hydrothermal process of claim 8 , wherein the catalyst is a heterogeneous catalyst that comprises an active species, a promoter, and a support material. 10. The integrated hydrothermal process of claim 9 , wherein the heterogeneous catalyst is a 2 wt % Ni-5 wt % Mg catalyst supported on silicon dioxide. 11. The integrated hydrothermal process of claim 8 , wherein the catalyst is a homogeneous catalyst that comprises an active species and a ligand. 12. The integrated hydrothermal process of claim 1 , further comprising the steps of: dispersing the catalyst in a dispersal fluid to produce a catalyst feed, wherein dispersal of the catalyst in the dispersal fluid is achieved using ultrasonic waves; injecting the catalyst feed at an injection rate into the flash drum such that the injection rate maintains a weight ratio of hydrocarbons to catalyst in the range between 0.05 and 0.07, such that the catalyst mixes with the heavy fraction to produce a heavy stream; and introducing the heavy stream to the aqueous reforming unit. 13. The integrated hydrothermal process of claim 6 , wherein a ratio of a volumetric flow rate of the water stream to a volumetric flow rate of the petroleum feed at standard ambient temperature and pressure is between 1:10 and 10:1. 14. An integrated hydrothermal system for upgrading heavy oil, the integrated hydrothermal system comprising: a mixer, the mixer configured to mix a heated water stream and a heated feed to produce a mixed fluid, wherein the heated water stream is supercritical water, wherein the heated feed is at a feedstock temperature less than 300 deg C. and a pressure greater than the critical pressure of water; a reactor unit fluidly connected to the mixer, the reactor unit configured to maintain a temperature greater than the critical temperature of water, and further configured to maintain a pressure greater than the critical pressure of water such that conversion reactions occur in the reactor unit, the conversion reactions are operable to upgrade the hydrocarbons in the mixed fluid such that a reactor effluent comprises light fractions, heavy fractions, and water; a cooling device fluidly connected to the reactor unit, the cooling device configured to reduce the temperature of the reactor effluent to produce a cooled fluid, wherein the cooled fluid is at a temperature less than the critical temperature of water and less than the temperature of the reactor effluent; a depressurizing device fluidly connected to the cooling device,