Feedback-assisted rapid discharge heating and forming of metallic glasses

The invention claimed is: 1. A rapid discharge heating and forming (RDHF) apparatus comprising: an electrical circuit comprising: a source of electrical energy; a sample of metallic glass; at least two electrodes connecting the source of electrical energy to a sample of metallic glass feedstock disposed in a feedstock barrel; a feedback control loop comprising: a temperature-monitoring device disposed in temperature monitoring relationship with the sample configured to generate a signal indicative of the temperature of the sample, the temperature-monitoring device coupled to a fiber-optic feedthrough across the feedstock barrel; a computing device in signal communication with the temperature-monitoring device configured to convert the signal from the temperature-monitoring device to a sample temperature T, compare T to a predefined temperature value T o , and generate a current terminating signal when T substantially matches T 0 ; and a current interrupting device electrically connected with the source of electrical energy and in signal communication with the computing device, and where the current interrupting device is configured to terminate the electrical current generated by the source of electrical energy when the current terminating signal is received from the computing device; and a shaping tool disposed in forming relation to the sample. 2. The RDHF apparatus of claim 1 , wherein the temperature-monitoring device is at least one of pyrometer or thermographic camera. 3. The RDHF apparatus of claim 1 , wherein the current interrupting device is selected from a group consisting of gate turn-off thyristor, power metal oxide semiconductor field emission transistor (MOSFET), integrated gate-commutated thyristor, and insulated gate bipolar transistor, or combinations thereof. 4. The RDHF apparatus of claim 1 , wherein the source of electrical energy of the RDHF apparatus comprises a capacitor. 5. The RDHF apparatus of claim 1 , wherein the shaping tool of the RDHF apparatus comprises an injection mold. 6. The RDHF apparatus of claim 1 , wherein the shaping tool of the RDHF apparatus comprises an extrusion die. 7. The RDHF apparatus of claim 1 , wherein the shaping tool of the RDHF apparatus comprises a forging die. 8. The RDHF apparatus of claim 1 , wherein the shaping tool of the RDHF apparatus comprises a blow molding die. 9. A method of rapidly heating and shaping a metallic glass using the RDHF apparatus according to claim 1 , the method comprising: discharging electrical energy uniformly through the sample of metallic glass formed of a metallic glass forming alloy to generate an electrical current that uniformly heats the sample; monitoring the temperature of the sample; terminating the electrical current when the temperature of the sample substantially matches a predefined temperature T o , where T o is between the glass transition temperature of the metallic glass and the equilibrium melting point of the metallic glass forming alloy; applying a deformational force to shape the heated sample into an article; and cooling the article to a temperature below the glass transition temperature of the metallic glass. 10. The method of claim 9 , wherein the electrical energy discharged ranges from 50 J to 100 kJ. 11. The method of claim 9 , wherein the electrical energy is at least 100 J and a discharge time constant of between 10 us and 100 ms. 12. The method of claim 9 , wherein T 0 is within 50 degrees of the half-way point between the glass transition temperature of the metallic glass and the equilibrium melting point of the metallic glass forming alloy. 13. The method of claim 9 , wherein the predefined temperature T o is such that the viscosity of the heated sample is from 1 to 10 4 Pas-sec. 14. The method of claim 9 , wherein the metallic glass is an alloy based on an elemental metal selected from the group consisting of Zr, Pd, Pt, Au, Fe, Co, Ti, Al, Mg, Ni and Cu. 15. The method of claim 9 , wherein the step of discharging the electrical energy generates a dynamic electrical field in the sample, and wherein the electromagnetic skin depth of the dynamic electric field generated is larger than at least one of the radius, width, thickness, and length of the sample. 16. The method of claim 9 , wherein applying a deformational force comprises a step selected from the group consisting of injection molding, forging, extrusion, and blow molding. 17. The method of claim 9 , comprising uniformly heating the sample at a rate of at least 500 K/s.