Monitoring temperature with seebeck effect

What is claimed is: 1 . A printer for three-dimensional fabrication of metallic objects, the printer comprising: a reservoir with an entrance to receive a metallic build material from a source, the metallic build material having a working temperature range with a flowable state exhibiting rheological properties suitable for fused filament fabrication; a heating system operable to heat the metallic build material within the reservoir to a temperature within the working temperature range; a nozzle including an opening that provides an exit path for the metallic build material from the reservoir, wherein the nozzle is formed of a conducting nozzle material different than the metallic build material; a drive system operable to mechanically engage the metallic build material and advance the metallic build material from the source into the reservoir with sufficient force to extrude the metallic build material, while at a temperature within the working temperature range, through the opening in the nozzle; a voltage detector configured to measure a voltage between a pair of terminals positioned across an interface between the metallic build material exiting the nozzle and the opening of the nozzle; and a processor configured to calculate a temperature difference between the opening of the nozzle and the metallic build material exiting the nozzle based upon the voltage and a Seebeck coefficient for each of the metallic build material and the conducting nozzle material. 2 . The printer of claim 1 further comprising a temperature sensor configured to measure an absolute temperature of the nozzle, wherein the processor is configured to calculate an estimate of an absolute temperature of the metallic build material based upon the absolute temperature of the nozzle and the temperature difference between the opening of the nozzle and the metallic build material. 3 . The printer of claim 2 wherein the processor is further configured to control the heating system based on the estimate of the absolute temperature of the metallic build material. 4 . The printer of claim 1 wherein the processor is further configured to monitor a change in a temperature of the metallic build material based on a change in the voltage between the pair of terminals. 5 . The printer of claim 1 wherein the processor is configured to calibrate the temperature difference based on one or more measurements under known conditions. 6 . The printer of claim 1 wherein the Seebeck coefficient for each of the metallic build material and the conducting nozzle material are provided as constants based on material types for the metallic build material and the conducting nozzle material. 7 . The printer of claim 1 wherein the metallic build material includes a bulk metallic glass, and wherein the working temperature range includes a range of temperatures above a glass transition temperature for the bulk metallic glass and below a melting temperature for the bulk metallic glass. 8 . The printer of claim 1 wherein the metallic build material includes an off-eutectic composition, and wherein the working temperature range includes a range of temperatures between a lowest and highest melting temperature. 9 . The printer of claim 1 wherein the metallic build material includes a composite material having a metallic base that melts at a first temperature and a high-temperature inert second phase in particle form that remains inert up to at least a second temperature greater than the first temperature, and wherein the working temperature range includes a range of temperatures above a melting point of the metallic base. 10 . The printer of claim 1 wherein the metallic build material includes a peritectic composition and the working temperature range includes a range of temperatures where the peritectic composition exhibits an equilibrium volume fraction containing a substantial percentage by volume of liquid and a substantial percentage by volume of solid, and wherein the peritectic composition exhibits a medium viscosity of between about one hundred and one thousand Pascal seconds. 11 . The printer of claim 1 wherein the printer comprises a fused filament fabrication additive manufacturing system. 12 . A method for controlling a printer in a three-dimensional fabrication of a metallic object, the method comprising: extruding a metallic build material through a nozzle of the printer; moving the nozzle along a build path relative to a build plate of the printer to fabricate an object on the build plate in a fused filament fabrication process based on a computerized model of the object; monitoring a voltage between the nozzle and the metallic build material; estimating a temperature parameter of the metallic build material based upon the voltage; and controlling a temperature of the metallic build material in response to the temperature parameter. 13 . The method of claim 12 wherein the temperature parameter includes a relative temperature between the nozzle and the metallic build material. 14 . The method of claim 12 wherein the temperature parameter includes an absolute temperature of the metallic build material. 15 . The method of claim 14 further comprising measuring a temperature of the nozzle, and estimating a temperature difference between the nozzle and the metallic build material based on the voltage and a Seebeck coefficient for each of the metallic build material and a material of the nozzle. 16 . The method of claim 12 wherein the metallic build material includes at least one of a bulk metallic glass, an off-eutectic composition of eutectic systems, and a composite material having a metallic base that melts at a first temperature and a high-temperature inert second phase in particle form that remains inert up to at least a second temperature greater than the first temperature. 17 . The method of claim 12 wherein controlling the temperature of the metallic build material includes at least one of controlling an extrusion rate, controlling a heating system, and controlling a nozzle speed. 18 . A computer program product for controlling a printer in a three-dimensional fabrication of a metallic object, the computer program product comprising computer executable code embodied in a non-transitory computer readable medium that, when executing on the printer, performs the steps of: extruding a metallic build material through a nozzle of the printer; moving the nozzle along a build path relative to a build plate of the printer to fabricate an object on the build plate in a fused filament fabrication process based on a computerized model of the object; monitoring a voltage between the nozzle and the metallic build material; estimating a temperature parameter of the metallic build material based upon the voltage; and controlling a temperature of the metallic build material in response to the temperature parameter. 19 . The computer program product of claim 18 wherein the temperature parameter includes a relative temperature between the nozzle and the metallic build material. 20 . The computer program product of claim 18 wherein the temperature parameter includes an absolute temperature of the metallic build material. 21 . The computer program product of claim 18 further comprising code that performs the steps of measuring a temperature of the nozzle, and estimating a temperature difference between the nozzle and the metallic build material based on the voltage and a Seebeck coefficient for each of t