Metal printer with vibrating ultrasound nozzle

What is claimed is: 1 . A printer for three-dimensional fabrication of metallic objects, the printer comprising: a reservoir to receive a metallic build material from a source, the metallic build material having a working temperature range between a solid and a liquid state where the metallic build material exhibits plastic properties suitable for extrusion; 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 a path for the metallic build material; a drive system operable to mechanically engage the metallic build material in solid form below the working temperature range 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; and an ultrasonic vibrator coupled to the nozzle and positioned to convey ultrasonic energy to the metallic build material where the metallic build material extrudes through the opening in the nozzle. 2 . The printer of claim 1 further comprising a controller that operates the ultrasonic vibrator with sufficient energy to ultrasonically bond an extrudate of the metallic build material exiting the extruder to an object formed of one or more previously deposited layers of the metallic build material on a build plate. 3 . The printer of claim 1 further comprising a controller that operates the ultrasonic vibrator with sufficient energy to interrupt a passivation layer on a receiving surface of a previously deposited layer of the metallic build material. 4 . The printer of claim 1 further comprising a controller that operates the ultrasonic vibrator with sufficient energy to augment thermal energy provided by the heating system to maintain the metallic build material at the temperature within the working temperature range within the reservoir. 5 . The printer of claim 1 further comprising a controller that operates the ultrasonic vibrator with sufficient energy to reduce adhesion of the metallic build material to the nozzle and an interior of the reservoir. 6 . The printer of claim 1 further comprising: a sensor for monitoring a suitability of a receiving surface of a previously deposited layer of the metallic build material for additional build material; and a controller configured to dynamically control operation of the ultrasonic vibrator in response to a signal from the sensor. 7 . The printer of claim 1 further comprising: a sensor for measuring a force applied to the metallic build material by the drive system; and a controller for increasing ultrasonic energy applied by the ultrasonic vibrator to the reservoir in response to a signal from the sensor indicative of an increase in the force applied by the drive system. 8 . The printer of claim 1 wherein the metallic build material includes a bulk metallic glass, the printer further comprising a controller coupled to the ultrasonic vibrator, the controller configured to operate the ultrasonic vibrator with sufficient energy to liquefy the bulk metallic glass at a layer between an object fabricated with the bulk metallic glass from the nozzle and a support structure for the object fabricated with the bulk metallic glass. 9 . The printer of claim 1 further comprising a mechanical decoupler interposed between the ultrasonic vibrator and one or more other components of the printer to decouple ultrasound energy from the ultrasonic vibrator from the one or more other components. 10 . The printer of claim 1 further comprising: a sensor for measuring a quality of a bond between adjacent layers of the metallic build material based on electrical resistance between the adjacent layers; and a controller configured to increase an application of ultrasound energy in response to a signal from the sensor indicating that the quality of the bond is poor. 11 . The printer of claim 1 wherein the metallic build material includes a bulk metallic glass. 12 . The printer of claim 11 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. 13 . The printer of claim 1 wherein the metallic build material includes a non-eutectic composition of eutectic systems that are not at a eutectic composition. 14 . The printer of claim 13 wherein the working temperature range includes a range of temperatures above a eutectic temperature for the non-eutectic composition and below a melting point for each component species of the non-eutectic composition. 15 . The printer of claim 1 wherein the metallic build material includes 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. 16 . The printer of claim 15 wherein the working temperature range includes a range of temperatures above a melting point for the metallic base. 17 . The printer of claim 1 wherein the printer comprises a fused filament fabrication additive manufacturing system. 18 . The printer of claim 17 further comprising a build plate and a robotic system, the robotic system configured to move the nozzle in a three-dimensional path relative to the build plate in order to fabricate an object from the metallic build material on the build plate according to a computerized model of the object. 19 . The printer of claim 18 further comprising a controller configured by computer executable code to control the heating system, the drive system, and the robotic system to fabricate the object on the build plate from the metallic build material. 20 . The printer of claim 18 further comprising a build chamber housing at least the build plate and the nozzle, the build chamber maintaining a build environment suitable for fabricating an object on the build plate from the metallic build material. 21 - 30 . (canceled)