Chalcogenides-based dual-band tuning for changing resistance states of reconfigurable intelligent surfaces of devices

What is claimed is: 1. A capacitive device, comprising: a first capacitor having a first capacitance value, the first capacitor comprising a first conductor, a second conductor, and dielectric material between the first conductor and the second conductor; a second capacitor having a second capacitance value, the second capacitor comprising a third conductor, a fourth conductor, and the dielectric material between the third conductor and the fourth conductor; a tunable capacitive device configured to selectively adjust the first capacitance value of the first capacitor of the capacitive device to a first different capacitive value from the first capacitance value and the second capacitance value of the second capacitor of the capacitive device to a second different capacitive value, the tunable capacitive device comprising a first contact coupled to the first conductor and a second contact coupled to the second conductor, and further comprising a capacitive circuit, the capacitive circuit comprising a switching element comprising phase change material that changes to a lower resistance state when heated by a first energy pulse, and changes to a higher resistance state when heated by a second energy pulse that is different from the first energy pulse, the switching element being coupled to a third capacitor to couple the third capacitor to the capacitive circuit, and decouple the third capacitor from the capacitive circuit, based on whether the phase change material is in the lower resistance state or in the higher resistance state; and a controllable energy transfer component that selectively transfers first heat to the phase change material via the first energy pulse to change the phase change material to the lower resistance state, and transfers second heat via the second energy pulse to the phase change material to change the phase change material to the lower resistance state. 2. The capacitive device of claim 1 , wherein the first capacitor comprises a first split-ring resonator capacitor, wherein the second capacitor comprises a second split-ring resonator capacitor, and wherein the second split-ring capacitor is nested within the first split-ring capacitor. 3. The capacitive device of claim 1 , wherein the first capacitor comprises a first split-ring resonator capacitor, wherein the second capacitor comprises a second split-ring resonator capacitor, and wherein the first split-ring capacitor is nested within the second split-ring capacitor. 4. The capacitive device of claim 1 , wherein the first capacitor comprises a distributed array of conducting interconnects. 5. The capacitive device of claim 1 , wherein the capacitive device is incorporated into a unit cell of a reconfigurable intelligent surface. 6. The capacitive device of claim 5 , wherein the capacitance value of the capacitive device is variable to control a first phase shift of a first frequency, and a second phase shift of a second frequency that is different from the first frequency, reflected by the unit cell. 7. The capacitive device of claim 5 , wherein the unit cell is part of a group of reconfigurable unit cells that are collectively arranged into the reconfigurable intelligent surface. 8. The capacitive device of claim 1 , wherein the switching element is electrically coupled in parallel with a fifth capacitor to join the fifth capacitor to the capacitive circuit when the switching element is in the higher resistance state to increase the capacitance value of the first capacitor to the first different capacitance value and the second capacitor to the second different capacitance value. 9. The capacitive device of claim 8 , wherein the capacitive circuit is one capacitive circuit of a group of electrically coupled capacitive circuits, the group comprising the fifth capacitor and at least one other capacitive circuit, and wherein for each other capacitive circuit of the at least one other capacitive circuit, the other capacitive circuit comprises a respective switching element comprising phase change material that changes to the lower resistance state when heated by the first energy pulse, and the higher resistance state when heated by the second energy pulse that is different from the first energy pulse, and the respective switching element of the other capacitive circuit is coupled to a sixth capacitor to couple the second capacitor to the other capacitive circuit, and decouple the sixth capacitor from the other capacitive circuit, based on whether the phase change material of the other capacitive circuit is in the lower resistance state or in the higher resistance state. 10. The capacitive device of claim 9 , wherein the capacitive circuits of the group are independently controllable via respective switching elements to tune the capacitive device to one capacitance value of a group of available capacitance values based on respective states of the respective switching elements. 11. The capacitive device of claim 9 , wherein the capacitive circuits of the group are electrically coupled in parallel with one another, and wherein at least one of the capacitive circuits of the group has a different capacitance value relative to at least one other capacitive circuit of the group. 12. The capacitive device of claim 9 , wherein the capacitive circuits of the group have different capacitance values varying from one another according to an exponential function. 13. A variable capacitor, comprising: a first conductor and a second conductor configured as a first capacitor with a first capacitance value; a third conductor and a fourth conductor configured as a second capacitor with a second capacitance value; a variable capacitive circuit coupled between the first conductor and the second conductor to controllably adjust a capacitance of the variable capacitor by adding a first variable amount of capacitance to the first capacitance value and a second variable amount of capacitance to the second capacitance value, the variable capacitive circuit comprising a group of respective subcircuits, and the respective subcircuits of the group comprising respective capacitors electrically coupled to respective chalcogenide material-based switching elements that, independent from one another, remain in respective higher resistance states or respective lower resistance states until selectively actuated; and respective actuators configured to selectively apply heat output to the respective chalcogenide material-based switching elements, the heat output of the respective actuators being selectively controlled with respective electrical pulses that set at least some of the respective chalcogenide material-based switching elements to a lower resistance state or reset at least some of the respective chalcogenide material-based switching elements to a higher resistance state, wherein the respective subcircuits add different amounts of capacitance to the variable capacitive circuit based on whether the respective switching elements of the respective subcircuits are independently set to the lower resistance state or independently reset to the higher resistance state. 14. The variable capacitor of claim 13 , wherein the first conductor and the second conductor are configured as a first split-ring resonator capacitor, and wherein the third conductor and the fourth conductor are configured as a second split-ring resonator capacitor. 15. The variable capacitor of claim 13 , wherein the first conductor and the second conductor are configured as a first split-ring resonator capacitor, wherein the third conductor and the fourth conductor are configured as a second split-ring resonator