Low-cost high-purity vacuum pumps and systems

What is claimed is: 1 . A hermetic tube adaptor, comprising: a hollow tube composed of a tube material that is hermetically impervious to diffusion of gases therethrough, having at least one open tube end such that a hollow interior of the hollow tube terminates at the open tube end which supports thereon a first gasket sealing surface that circumscribes the open termination of said hollow interior, an adaptor arrangement including: (i) a flange composed of a hermetically impermeable flange material, that includes a second gasket sealing surface having a shape that matches and faces the first gasket sealing surface such that a vacuum gasket can be sandwiched between said gasket sealing surfaces, (ii) a gasket serving as a vacuum seal composed of a non-hermetic gasket material sandwiched between said first and second gasket sealing surfaces (iii) a clamping arrangement that mechanically engages both the hollow tube and the flange and is configured for clamping the first and second gasket sealing surfaces towards one another to cause compression force upon said open gasket, and wherein the hollow interior of the tube can be hermetically sealed from outside ambient air employing a hermetic sealing arrangement including: (i) the gasket serving as a non-hermetic vacuum seal that exhibits at least some gasket leakage as a gaseous diffusion through and/or around said non-hermetic gasket of any gas that surrounds an outer periphery of said gasket, (ii) a groove in one or both of said tube end and said flange disposed around an outer perimeter of the gasket and configured to receive a flow of oxygen free sweep gas that is injected therein through an injection channel within said flange such that said sweep gas surrounds the outer periphery of said gasket, (iii) an external Peclet seal surrounding the vacuum gasket and interposed in a series arrangement between said vacuum gasket and the outside ambient air, and configured to receive said flow of oxygen free sweep gas to provide diffusion sealing, by gas flow of said oxygen free sweep gas, from an interior perimeter of the Peclet seal, in gaseous communication with said groove, to an outside perimeter of the Peclet seal, in gaseous communication with outside ambient air, such that the Peclet seal can substantially isolate the gasket from exposure to outside air, wherein a majority of said flow of oxygen free sweep gas flows through the Peclet seal and a trace minority of the oxygen free sweep gas flows through and/or around said gasket as said leakage such that the non-hermetic vacuum seal provides sufficient sealing to support and allow for vacuum pressure within the hollow tubes, yet would not provide sufficient hermiticity against outside ambient air in an absence of any surrounding additional seal, and the Peclet seal serving as a surrounding additional seal provides for sufficient isolation from the outside air such that said leakage through and/or around the non-hermetic gasket seal is substantially free of outside air. 2 . The hermetic tube adaptor of claim 1 wherein the Peclet seal has an inlet in gaseous communication with said groove for receiving said sweep gas therefrom, and an outlet in gaseous communication with said outside air, and a Peclet flow path length L from the inlet to the outlet with sufficient flow velocity such that said sweep gas flow causes suppression of back diffusion of said outside air to provide for said hermetic isolation. 3 . The hermetic tube adaptor of claim 2 wherein the hollow tube includes a first Peclet sealing surface and the adaptor includes a second Peclet sealing surface that faces and matches the shape of the first Peclet sealing surface such that the two Peclet sealing surfaces face one another in a confronting relationship to define a Peclet Gap G as a gap size therebetween. 4 . The hermetic tube adaptor of claim 2 wherein for an end portion extending along the tube axially from the rim of the tube for said path length L, said first Peclet sealing surface wraps around and encircles said end portion and faces radially outward and is surrounded and encircled by the opposing, second Peclet sealing surface also extending along said axial direction for said flow path length L and radially facing inward such that the two opposing Peclet sealing surfaces define said Peclet gap G as a radial gap therebetween having a gap size of G. 5 . The hermetic tube adaptor of claim 1 wherein said hollow tube serves as a first hollow tube and a second hollow tube is hermetically attached to and/or cofabricated with the flange such that a hollow interior of the second hollow tube is arranged in gaseous communication with the hollow interior of the first hollow tube. 6 . The hermetic tube adaptor of claim 5 wherein said gasket is an open gasket having an inner perimeter that defines an opening that allows for said gaseous communication between the interior of the second hollow tube and the hollow interior of the first hollow tube. 7 . The hermetic tube adaptor of claim 6 wherein the open gasket is a peripheral gasket that extends around the open rim of the first hollow tube. 8 . The hermetic tube adaptor of claim 2 wherein the rim of the hollow tube includes said first Peclet sealing surface that is flat and extends around the outer perimeter of the groove and the flange supports said second Peclet sealing surface, surrounding the outer perimeter of the groove and extending radially along said flow path length, that faces the first Peclet sealing surface in a confronting spaced apart relationship defining said Peclet gap G therebetween having said flow path length L. 9 . The hermetic tube adaptor of claim 2 wherein said majority of sweep gas that surrounds the open gasket and flows into and through the Peclet seal, flows along the Peclet flow path at a velocity sufficient to suppress diffusion of outside air towards the inner volume to the degree that said any sweep gas in the groove that flows through and/or around the gasket into the hollow interior of the tube, as said leakage, contains at least an order of magnitude less air than would otherwise be the case if the flow of sweep gas were deactivated for a sustained period of time and thus exposed the gasket to outside air. 10 . The hermetic tube adaptor seal of claim 9 wherein the sweep gas flows through the Peclet seal at a rate of between and inclusive of 0.01 to 0.1 standard liters per minute (SLM) to 10 SLM for every linear centimeter of circumferential gasket perimeter. 11 . The hermetic tube adaptor of claim 10 wherein the sweep gas flows through the Peclet seal at a rate of between and inclusive of 0.1 to 1.0 SLM. 12 . The hermetic tube adaptor of claim 9 wherein the gasket material is one of (i) sufficiently porous such that a majority of said leakage flows through the gasket as opposed to around the gasket and the leakage can be readily detected by monitoring steady state pressure rise in a closed system at vacuum (ii) an elastomeric material that is sufficiently diffusive to oxygen such that diffusion therethrough can be detected by use of a Helium leak tester. 13 . The hermetic tube adaptor seal of claim 2 wherein the sweep gas is a highly purified oxygen free inert gas. 14 . The hermetic tube adaptor of claim 13 wherein the sweep gas is a pure, laboratory grade, inert gas with a purity substantially better than 1 ppm of oxygen or any other gaseous contaminates including hydrocarbon gases. 15 . The hermetic tube adaptor of claim 13 wherein a majority of the sweep gas is highly purified Argon. 16 . The hermetic tube adapt