Synergistic heat pumped thermal storage and flexible carbon capture system

1 . A power plant system configured to generate electricity, the power plant system comprising: a carbon-based fuel-fired power plant including a combustor configured to receive and combust air and a carbon-based fuel thereby producing heat and exhausting a flue gas, and a turbine configured to generate electricity; a carbon capture system configured to remove at least a portion of carbon-based gasses from the flue gas downstream from the combustor; and a thermal storage system including a hot storage unit configured to store heat generated at least by resistively-heated gas at a hot temperature, the hot temperature greater than ambient temperature; wherein the power plant is configured to operate in at least a first mode for storing thermal energy in the thermal storage system and a second mode for releasing the stored thermal energy from the thermal storage system; and wherein during the second mode, heat stored in the hot storage unit is transferred to the carbon capture system. 2 . The power plant system of claim 1 , wherein the resistively-heated air is generated by a resistive heater powered by electricity from the power grid. 3 . The power plant system of claim 1 , wherein the thermal storage system includes a cold storage unit configured to store thermal energy at a cold temperature, the cold temperature less than ambient temperature; and wherein during the second mode, before the air is combusted in the combustor the air is configured to transfer heat to the cold storage unit thereby lowering the temperature of the air received in the combustor. 4 . The power plant system of claim 3 , wherein the thermal storage system includes a first heat pump using a refrigerant as a first working fluid and a second heat pump using a second refrigerant as a second working fluid; and wherein the first refrigerant is configured to transfer heat from the cold storage unit and the second refrigerant is configured to transfer heat to the hot storage unit. 5 . The power plant system of claim 4 , wherein the second refrigerant is steam. 6 . The power plant system of claim 1 , wherein the thermal storage system includes a heat pump configured to use the flue gas as a working fluid. 7 . The power plant system of claim 1 , wherein the thermal storage system includes a heat pump configured to use air as a working fluid. 8 . The power plant system of claim 7 , wherein the flue gas is configured to transfer heat to the air in the heat pump during the first mode. 9 . The power plant system of claim 1 , wherein the thermal storage system includes a heat pump configured to use steam as a working fluid. 10 . The power plant system of claim 7 , wherein the flue gas is configured to transfer heat to the steam in the heat pump during the first mode but not in the second mode. 11 . The power plant system of claim 7 , further comprising a heat recovery steam generator including at least one heat exchanger and at least one steam turbine, the at least one heat exchanger configured to receive the flue gas and transfer heat from the flue gas to a fluid before the fluid enters the at least one steam turbine. 12 . The power plant system of claim 11 , wherein steam from the heat recovery steam generator is configured to transfer heat to the steam in the heat pump during the first mode. 13 . The power plant system of claim 11 , wherein steam from the heat recovery steam generator is configured to be the working fluid. 14 . The power plant system of claim 11 , wherein steam from the heat recovery steam generator is configured to transfer heat to the hot storage unit during the first mode. 15 .- 29 . (canceled) 30 . A method of operating the power plant system of claim 1 , the method comprising: generating, with the power plant system from claim 1 , electricity to be supplied to a power grid; determining, with a controller, when to begin the first mode for temporarily storing thermal energy with the thermal storage system; determining, with the controller, when to begin the second mode for transferring heat from the hot storage unit to the carbon capture system; and transferring, during the second mode, heat from the hot storage unit to the carbon capture system. 31 . The method of claim 30 , further including resistively-heating the gas with a resistive heater powered by electricity from the power grid. 32 .- 33 . (canceled)