Systems and methods for monitoring temperature using acoustic waves during processing of a material

What is claimed: 1. A system for processing a material, the system comprising: a first energy source; a second energy source; a first acoustic wave generator; a first acoustic wave detector; and a controller coupled to the first energy source, the second energy source, the first acoustic wave generator, and the first acoustic wave detector, the controller being configured so as to: control the first energy source so as to heat a first region of the material; control the first acoustic wave generator so as to excite a first acoustic wave in the material, the first acoustic wave being transmitted through the heated first region of the material, the heated first region of the material changing at least one property of the first acoustic wave; control the first acoustic wave detector so as to detect the change in at least one property of the first acoustic wave; characterize a temperature of the material in the heated first region based on the detected change in at least one property of the first acoustic wave; compare the characterized temperature of the material in the heated first region to a threshold; and based on the characterized temperature of the material in the heated first region being less than the threshold or being above the threshold for an insufficient amount of time, control the second energy source so as to modify a property of the heated first region. 2. The system of claim 1 , wherein heating the first region of the material by the first energy source melts a powder or a wire in the first region to form the material. 3. The system of claim 1 , wherein heating the first region of the material by the first energy source excites a portion of the material. 4. The system of claim 1 , wherein the acoustic wave comprises one or more of a surface acoustic wave, a bulk acoustic wave, a guided acoustic wave, and a phonon. 5. The system of claim 1 , wherein the controller further is configured to: characterize a defect in a morphology of the material in the heated first region based on the detected change in at least one property of the first acoustic wave; and based on the characterized defect, control the second energy source so as to heat the first region of the material to a temperature above the threshold. 6. The system of claim 1 , wherein modifying the property of the heated first region with the second energy source comprises heating the first region of the material to a temperature above the threshold. 7. The system of claim 1 , further comprising: a second acoustic wave generator; and a second acoustic wave detector, the controller being coupled to the second acoustic wave generator and the second acoustic wave detector, the controller further being configured so as to: control the second acoustic wave generator so as to excite a second acoustic wave in the material, the second acoustic wave being transmitted through a heated second region of the material, the heated second region of the material changing at least one property of the second acoustic wave; control the second acoustic wave detector so as to detect the change in at least one property of the second acoustic wave; characterize a temperature of the material in the heated second region based on the detected change in at least one property of the second acoustic wave; compare the characterized temperature of the material in the heated second region to a threshold; and based on the characterized temperature of the material in the second region being less than the threshold or being above the threshold for an insufficient amount of time, control the second energy source or a third energy source so as to heat the second region of the material to a temperature above the threshold. 8. The system of claim 1 , wherein the change in at least one property of the first acoustic wave is based on detecting a change in an arrival time, a change in a disturbance amplitude, or changes both in the arrival time and the disturbance amplitude, of at least one frequency component of the first acoustic wave. 9. The system of claim 8 , wherein the first acoustic wave detector is configured to detect the change in the arrival time, the change in the disturbance amplitude, or the changes both in the arrival time and the disturbance amplitude, of the at least one frequency component of the first acoustic wave based on receiving laser light reflected from the material. 10. The system of claim 1 , wherein the first energy source comprises a first laser or a first particle beam. 11. The system of claim 10 , wherein the first acoustic wave generator comprises the first laser. 12. The system of claim 10 , wherein the second energy source comprises a second laser or a second particle beam that is discrete from the first laser or the first particle beam.