Liquid purification or separation – Processes – Ion exchange or selective sorption
Reexamination Certificate
2002-02-28
2004-05-11
Hopkins, Robert A. (Department: 1724)
Liquid purification or separation
Processes
Ion exchange or selective sorption
C210S683000
Reexamination Certificate
active
06733678
ABSTRACT:
FIELD OF THE INVENTION
The present invention pertains generally to devices, apparatus and methods for separating selected metal ions from a plasma. In particular, the present invention pertains to collectors for removing ions of a selected material from a plasma separator. More particularly, the present invention pertains to metal ion collectors for plasma separators that include silica (glass) substrates which liquify when diffused by metal ions to create a collectable liquid.
BACKGROUND OF THE INVENTION
In the operation of a plasma mass filter, as well as in the operation of other types of plasma separators, it is always necessary to somehow establish a mechanism for effectively collecting the target material that is being processed. To this end, the collection process needs to be as efficacious and as easy to implement as possible. Various techniques for collecting material from a plasma mass separator have been heretofore suggested. These suggestions include the more obvious task of physically removing and replacing collectors of the target material. Additionally, these suggestions include more subtle processes, such as introducing a medium into the plasma chamber for in situ cleaning of collectors, as disclosed in U.S. Pat. No. 6,139,681, which issued to Ohkawa for an invention entitled “Plasma Assisted Process Vessel Cleaner” and which is assigned to the same assignee as the present invention. Still, the very nature of plasmas lend themselves to other possible collection methods.
It is known that when oxygen and metal vapors of a plasma come into contact with the surface of a solid glass substrate close to its melting point, the nature of the substrate surface is changed. An important change results from the fact that as oxides of the metal diffuse into the substrate, a surface layer of the substrate softens and turns from a solid state into a liquid state. The viscosity of this resulting liquified surface layer will depend on both the species of the metal oxides that are involved in the process and their concentration in the surface layer.
Once a surface layer of the glass substrate begins to liquify, the tendency is for the surface layer to drip from the substrate. In this condition, it is possible that the diffusion rate at which metal atoms diffuse into the substrate will exceed the rate at which metal atoms are deposited onto the substrate surface. If so, there will be no solid deposit on the surface layer. On the other hand, it is also possible that the deposition rate will be higher than the diffusion rate. In this latter case, a solid deposit will form on the liquified surface layer. In either event, at some point in time, the liquified surface layer of the substrate will begin to drip from the substrate. When this happens, the drip will include the metal atoms that have diffused into the surface layer of the substrate, as well as any solid deposit that may have formed on the surface layer.
A mathematical expression for the motion of a liquified surface layer relative to an underlying substrate can be obtained by balancing the viscous forces in the surface layer and the gravitational forces that are acting on the layer. For this expression, we assume the substrate is vertically oriented and we obtain
dy/dt≈[&rgr;g/&eegr;]d[d+w]
(eqn. 1)
where “y” is the vertical position of the substrate, “&rgr;” is the mass density of the surface layer, “g” is the gravitational acceleration, “&eegr;” is the viscosity of material in the surface layer, “d” is the thickness of the surface area, and “w” is the thickness of the solid deposit.
As indicated above, any movement of the liquified surface layer should account for the possibilities that for a given throughput per unit area, &Ggr;, a solid deposit layer may, or may not, form on the surface layer. Accordingly, the throughput, &Ggr;, will include a diffusion term (surface layer) and a deposition term (deposition layer), and can be expressed as
&Ggr;=
nD/d+ndw/dt
(eqn. 2)
where “n” is the solid density, and “D” is the diffusion coefficient of metal atoms in the substrate glass.
As diffusion occurs, the diffusion depth of the surface layer at any given time “t” can be expressed as
d~[Dt]
1/2
. (eqn. 3)
Returning for the moment to the expression for throughput, &Ggr; (eqn. 2), it will be appreciated that the diffusion term (nD/d) dominates early in time until the thickness of the surface layer reaches d
1
, given by the expression
d
1
~nD/&Ggr;. (eqn. 4)
With the above in mind, it is possible to define a low throughput regime wherein no solid deposit is formed on the liquified surface layer, and a high throughput regime wherein there is a solid deposit. For this purpose we can define the low throughput regime by the transit time it takes for the surface layer to move across the collector substrate through a vertical height “h.” Specifically, this low throughput regime persists when the transit time “t
t
” for the thickness of the surface layer “d” to reach “d
1
” (eqn. 4) is shorter than the diffusion time “t
1
”. In this regime, the expression given above for movement of the surface layer (eqn. 1) becomes
dy/dt≈[&rgr;g/&eegr;]d
2
(eqn. 5)
and the transit time t
2
is given by
t
2
≈[2
h&eegr;/&rgr;gD]
1/2
. (eqn. 6)
Under conditions wherein t
2
<t
1
, the throughput, &Ggr;, becomes
&Ggr;<
n[&rgr;gD
3
/2
h&eegr;]
1/4
. (eqn. 7)
If the throughput, &Ggr;, is larger than the critical value defined in the above expression, the movement of the surface layer can be approximated by
dy/dt≈[&rgr;g/&eegr;]d
1
w.
(eqn. 8)
The thickness of the deposition layer “w” during the transit time can then be given by the expression
w≈[&Ggr;
][
2
h&eegr;/D&rgr;g]
1/2
. (eqn. 9)
In light of the above it is an object of the present invention to provide an apparatus and method for removing selected metal ions from a plasma which includes a collector that can be used in the vacuum chamber of a plasma separator to continuously remove collected material from the chamber. It is another object of the present invention to provide an apparatus and method for removing selected metal ions from a plasma which incorporates a collector that allows for a periodic replenishment of the collector in the vacuum chamber of a plasma mass separator. Still another object of the present invention is to provide an apparatus and method for removing selected metal ions from a plasma which allows material having a relatively high throughput, and other material having a relatively low throughput, to be simultaneously collected on respective collectors.
Yet another object of the present invention is to provide an apparatus and method for removing selected metal ions from a plasma which is relatively easy to implement, is simple to use, and is comparatively cost effective.
SUMMARY OF THE PREFERRED EMBODIMENTS
An apparatus for removing selected metal ions from a plasma uses a plasma filter which has a chamber (container) for processing a multi-species plasma. More specifically, the plasma filter separates the multi-species plasma into relatively light ions which have a charge to mass ratio M
1
, and relatively heavy ions which have a charge to mass ratio M
2
. The plasma filter does this by directing the ions M
1
and the ions M
2
onto separate trajectories inside the plasma chamber. Within this context, the present invention is directed to the collectors that are mounted in the chamber for the purposes of separately collecting the ions M
1
and the ions M
2
, and removing them from the chamber.
In accordance with the present invention, both the M
1
ion collector and the M
2
ion collector include a substrate that is mounted and exposed in the plasma chamber for contact with the selected metal ions (M
1
or M
2
). Preferably, each substrate is made of a crystalline compound, such as silica (SiO
2
), which is interactive with the metal ions (M
1
Archimedes Technology Group, Inc.
Hopkins Robert A.
Nydegger & Associates
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