Rydberg atom mixer and determining phase of modulated carrier radiation

What is claimed is: 1. A Rydberg atom mixer for determining a phase of modulated carrier radiation comprising: a reference radiofrequency source that provides reference radiofrequency radiation; a modulated carrier source that provides modulated carrier radiation; a vapor cell comprising a vapor cell wall and vapor space physically bounded by the vapor cell wall to contain gas atoms in the optical overlap volume, such that the vapor cell: receives gas atoms in the vapor space; receives the reference radiofrequency radiation; receives the modulated carrier radiation, such that the gas atoms are subjected to the reference radiofrequency radiation and the modulated carrier radiation; and produces modulated light modulated at an intermediate frequency IF by the gas atoms in response to subjecting the gas atoms to the reference radiofrcquency radiation and the modulated carrier radiation; and a transmission detector that receives the modulated light from the vapor cell and produces a transmission signal from the transmission detector for determination of a phase of the modulated carrier radiation, wherein the Rydberg atom mixer mixes the reference radiofrequency radiation and the modulated carrier radiation by the gas atoms in a Rydberg electronic state to produce the intermediate frequency IF that corresponds directly to the phase of the modulated carrier radiation. 2. The Rydberg atom mixer of claim 1 , further comprising: a probe laser that produces probe light that comprises a probe frequency that is resonant with a probe electronic transition of the gas atoms; and a coupling laser that produces coupling light that comprises a coupling frequency that is resonant with a Rydberg electronic transition of the gas atoms, wherein the vapor cell further: receives the probe light from the probe laser, the coupling light from the coupling laser, the modulated carrier radiation, and the reference radiofrequency radiation; and subjects the gas atoms to the probe light, and the gas atoms undergo a probe electronic transition from a first electronic state to an intermediate excited electronic state in response to receiving the probe light; subjects the gas atoms in the intermediate excited electronic state to the coupling light, and the gas atoms in the intermediate excited electronic state undergo a Rydberg electronic transition from the intermediate excited electronic state to a Rydberg electronic state in response to receiving the coupling light; and subjects the gas atoms in the Rydberg electronic state to the modulated carrier radiation and the reference radiofrequency radiation, and the gas atoms in the Rydberg electronic stale undergo a radiofrequency Rydberg transition from the Rydberg electronic state to a final Rydberg electronic state in response to receiving the modulated carrier radiation and the reference radiofrcquency radiation. 3. The Rydberg atom mixer of claim 2 , further comprising: a modulation analyzer in communication with the transmission detector and that receives the transmission signal from the transmission detector and determines a probe modulation of live probe light from the transmission signal that is due to mixing the reference radiofrequency radiation and the modulated carrier radiation by the gas atoms in the Rydberg electronic state, such that the phase of the modulated carrier radiation is determined from the probe modulation. 4. The Rydberg atom mixer of claim 3 , further comprising: a signal analyzer in communication with the transmission detector and that receives the transmission signal from the transmission detector and determines an in-phase quadrature map from the transmission signal. 5. The Rydberg atom mixer of claim 2 , further comprising: a first antenna in communication with the reference radiofrcquency source and that receives a reference radiofrequency signal from the reference radiofrequency source and produces the reference radiofrequency radiation from the reference radiofrequency signal; a second antenna in communication with the modulated carrier source and that receives a modulated carrier signal from the modulated carrier source and produces the modulated carrier radiation from the modulated carrier signal, wherein the gas atoms receive the reference radiofrequency radiation from the first antenna and the modulated carrier radiation from the second antenna. 6. The Rydberg atom mixer of claim 5 , further comprising: a position manipulation stage on which the second antenna is disposed ami that moves the second antenna along a movement direction relative to the vapor cell to change a pathlength between the second antenna and the vapor cell through which the modulated carrier radiation propagates. 7. The Rydberg atom mixer of claim 2 , further comprising: a power combiner in communication with the reference radiofrequency source and the modulated carrier source and that: receives a reference radiofrequency signal from the reference radiofrequency source; receives a modulated carrier signal from the modulated carrier source; and produces a combined radiofrequency signal from the reference radiofrequency signal and the modulated carrier signal; an antenna in communication with the power combiner and that: receives the combined radiofrequency signal from the power combiner, and produces radiofrequency radiation that comprises the reference radiofrequency radiation and the modulated carrier radiation from the combined radiofrequency signal, wherein the gas atoms receive the radiofrequency radiation from the antenna. 8. The Rydberg atom mixer of claim 2 , further comprising: an antenna in communication with the modulated carrier source and that receives a modulated carrier signal from live modulated carrier source and produces the modulated carrier radiation from live modulated carrier signal; a parallel-plate waveguide antenna in which the vapor cell is disposed and that: is in communication with the reference radio frequency source; receives a reference radiofrequency signal from the reference radiofrequency source; produces the reference radiofrequency radiation from the reference radiofrequency signal; and communicates the reference radiofrequency radiation to the vapor cell, wherein the gas atoms receive the modulated carrier source from the antenna and the reference radiofrequency radiation from the parallel-plate waveguide antenna. 9. A process for determining a phase of modulated carrier radiation with a Rydberg atom mixer of claim 1 , the process comprising: disposing gas atoms in the vapor space; receiving, by the vapor cell, the reference radiofrequency radiation; receiving, by the vapor cell, the modulated carrier radiation; subjecting the gas atoms to the reference radiofrequency radiation and the modulated carrier radiation; mixing the reference radiofrequency radiation and the modulated carrier radiation by the gas atoms in the Rydberg electronic state to produce the intermediate frequency IF; producing modulated light modulated at the intermediate frequency IF by the gas atoms in response to being subjected to the to the reference radiofrequency radiation and the modulated carrier radiation; receiving, by the transmission detector, the modulated light from the vapor cell; producing, by the transmission detector, the transmission signal; and determining the phase of tire modulated carrier radiation from the transmission signal. 10. The process for determining the phase of modulated carrier radiation of claim 9 , further comprising: producing probe light that comprises a probe frequency that is resonant with a probe electronic transition of the gas atoms; producing coupling light that comprises