Chemical looping fluidized-bed concentrating solar power system and method

What is claimed is: 1. A concentrating solar power plant comprising: a receiver containing a solid metal oxide (solid Me x O y ), the receiver configured to receive thermal energy from sunlight and transfer the thermal energy to the solid Me x O y ; a fluidized-bed heat exchanger containing a reduced solid metal oxide (solid Me x O y-2 ) and the solid Me x O y , the fluidized-bed heat exchanger configured to transfer heat from at least one of the solid Me x O y or the solid Me x O y-2 to a working fluid in a working fluid circuit; a first gas that fluidizes the solid Me x O y and the solid Me x O y-2 in the fluidized-bed heat exchanger; a first turbine fluidly coupled to the working fluid circuit; and a second turbine fluidly coupled to the fluidized-bed heat exchanger, wherein: the thermal energy from sunlight converts in the receiver at least a portion of the solid Me x O y to the solid Me x O y-2 resulting in the storage of chemical energy in the solid Me x O y-2 and the formation of an oxygen (O 2 ) stream, at least a portion of the O 2 stream is delivered to the fluidized-bed heat exchanger to form at least a portion of the first gas, and is ignited and reacted with the solid Me x O y-2 in the fluidized-bed heat exchanger to convert at least a portion of the solid Me x O y-2 to the solid Me x O y and a heated second gas, the conversion of the solid Me x O y-2 to the solid Me x O y releases at least a portion of the chemical energy to form the heat transferred to the working fluid, the working fluid is directed to the first turbine such that the first turbine produces a first source of electricity, and the heated second gas is directed to the second turbine such that the second turbine produces a second source of electricity. 2. A method comprising: directing sunlight to a receiver containing a solid metal oxide (solid Me x O y ); transferring thermal energy from the sunlight to the solid Me x O y such that at least a portion of the solid Me x O y is converted to oxygen (O 2 ) and a reduced solid metal oxide (solid Me x O y-2 ) containing stored chemical energy; in a fluidized-bed heat exchanger, fluidizing the solid Me x O y-2 with a first gas comprising O 2 produced in the transferring such that the fluidizing results in the igniting and reacting, in the fluidized-bed heat exchanger, of at least a portion of the solid Me x O y-2 with at least a portion of the O 2 produced in the transferring to form the solid Me x O y and a heated second gas, such that the reacting results in the converting of a portion of the stored chemical energy to heat; transferring at least a portion of the heat to a working fluid to form a heated working fluid; generating a first portion of electricity by passing the heated working fluid through a first turbine; and directing the heated second gas through a second turbine resulting in the generating of a second portion of electricity. 3. The method of claim 2 , further comprising: after the fluidizing, separating the second gas from the solid Me x O y ; storing the separated solid Me x O y ; and selectively delivering at least a portion of the separated solid Me x O y to the receiver for the transferring of the thermal energy from the sunlight to the separated solid Me x O y . 4. The method of claim 2 , further comprising: before the fluidizing, compressing the first gas; and delivering the compressed first gas to the fluidized-bed heat exchanger to perform the fluidizing.