Method and system based on thermoplastic forming to fabricate high surface quality metallic glass articles

What is claimed is: 1. A method of shaping a bulk metallic glass comprising: providing a bulk metallic glass feedstock having an inner bulk region surrounded by an initial rough outer surface region, the feedstock being heated to a temperature within thermoplastic zone of the bulk metallic glass; placing the outer region of the feedstock into contact with at least one solid surface in fluid communication with at least one shaping tool; inducing the feedstock to flow along the at least one solid surface toward the shaping tool such that the leading edge of the flow of the feedstock forms a contact-line with the solid surface, and wherein the motion of the contact-line along the solid surface induces an interfacial flow of the feedstock material from the bulk towards the solid surface, wherein within 1 to 10 nm of the contact-line a stress of 10 3 -10 5 MPa is exerted on the outer surface of the feedstock; and maintaining the flow of the feedstock along the solid surface until substantially all of the initial outer region of the feedstock at the contact-line of the alloy is replaced with a new smooth outer region formed from the interfacial flow of the bulk of the feedstock to the outer region of the feedstock prior to the feedstock coming into contact with the at least one shaping tool. 2. The method of claim 1 , wherein the feedstock is placed into contact with at least two parallel solid surfaces. 3. The method of claim 2 , wherein the at least two solid surfaces form a channel. 4. The method of claim 1 , wherein the at least one shaping tool is selected from the group consisting of dies, compression moulds and extrusion tools. 5. The method of claim 1 , wherein the shaping tool includes at least one feature that has a dimensional scale of less than 50 nm. 6. The method of claim 1 , wherein the point of initial contact between the feedstock and the solid surface is outside the area of the at least one shaping tool. 7. The method of claim 1 , wherein the step of inducing the flow is performed by applying a pressure to the feedstock. 8. The method of claim 1 , further comprising varying the application of force to select the direction and speed of the flow of the feedstock. 9. The method of claim 1 , wherein there are at least two shaping tools. 10. The method of claim 1 , wherein the bulk metallic glass is based on an inert material selected from the group consisting of Pt, Au, Pd and Ni. 11. A method of shaping a bulk metallic glass comprising: providing a bulk metallic glass feedstock having an inner bulk region surrounded by an initial rough outer surface region, the feedstock being heated to a temperature within thermoplastic zone of the bulk metallic glass; placing the outer region of the feedstock into contact with at least one solid surface in fluid communication with at least one shaping tool, wherein the at least one solid surface is atomically smooth; inducing the feedstock to flow along the at least one solid surface toward the shaping tool such that the leading edge of the flow of the feedstock forms a contact-line with the solid surface, and wherein the motion of the contact-line along the solid surface induces an interfacial flow of the feedstock material from the bulk towards the solid surface; and maintaining the flow of the feedstock along the solid surface until substantially all of the initial outer region of the feedstock at the contact-line of the alloy is replaced with a new smooth outer region formed from the interfacial flow of the bulk of the feedstock to the outer region of the feedstock prior to the feedstock coming into contact with the at least one shaping tool. 12. A method of shaping a bulk metallic glass comprising: providing a bulk metallic glass feedstock having an inner bulk region surrounded by an initial rough outer surface region, the feedstock being heated to a temperature within thermoplastic zone of the bulk metallic glass; placing the outer region of the feedstock into contact with at least one solid surface in fluid communication with at least one shaping tool; inducing the feedstock to flow along the at least one solid surface toward the shaping tool such that the leading edge of the flow of the feedstock forms a contact-line with the solid surface, and wherein the motion of the contact-line along the solid surface induces an interfacial flow of the feedstock material from the bulk towards the solid surface; and maintaining the flow of the feedstock along the solid surface until substantially all of the initial outer region of the feedstock at the contact-line of the alloy is replaced with a new smooth outer region formed from the interfacial flow of the bulk of the feedstock to the outer region of the feedstock prior to the feedstock coming into contact with the at least one shaping tool; wherein an article formed in the at least one shaping tool has a peak-to-valley surface roughness of from 1 to 10 nm.