Opposed migration aerosol classifier gas and heat exchanger

A method is provided for changing a property of a sample. A sample, comprising particles suspended within a sample fluid, is introduced into a channel which comprises two walls that are permeable to a flow of fluid. A cross-flow is introduced at a predetermined temperature and of a predetermined chemical composition into the channel through a wall. This cross-flow flows at a first velocity and exits in a first direction through the other wall. An imposed field is applied on the particles in a second direction counter to the first direction of the cross-flow. The imposed field causes the particles to migrate at a second velocity opposite and/or equal to the first velocity of the cross-flow. Particles that are approximately balanced by the first and second velocities travel through the channel and are discharged in a fluid of predetermined chemical composition and at the predetermined temperature of the cross-flow.

This application is also related to the following commonly-assigned patent and patent applications, which are incorporated by reference herein:

U.S. patent application Ser. No. 13/769,122, filed on Feb. 15, 2013, by Richard C. Flagan et al., entitled “RADIAL OPPOSED MIGRATION AEROSOL CLASSIFIER WITH GROUNDED AEROSOL ENTRANCE AND EXIT,”, which claims priority to Provisional Application Ser. No. 61/600,409, filed on Feb. 17, 2012, by Richard C. Flagan et al., entitled “RADIAL OPPOSED MIGRATION AEROSOL CLASSIFIER WITH GROUNDED AEROSOL ENTRANCE AND EXIT,”.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates generally to methods, apparatuses, and articles of manufacture for changing a property of a sample, and in particular, for changing a temperature, particle size, and/or chemical composition of a fluidic sample with an opposed migration aerosol classifier (OMAC).

2. Description of the Related Art

(Note: This application references a number of different publications as indicated throughout the specification by reference numbers enclosed in brackets, e.g., [x]. A list of these different publications ordered according to these reference numbers can be found below in the section entitled “References.” Each of these publications is incorporated by reference herein.)

A number of different systems and techniques have been developed for separating and measuring particles contained in fluids such as gases (e.g. aerosols or atmospheric ultrafine particles) and liquids (e.g. colloids or suspensions). Common systems and techniques in the art include the usage of condensation particle counters (CPC) and differential electrical mobility classifiers (DEMC) such as differential mobility analyzers (DMA) and inclined grid mobility analyzers (IGMA). Such systems separate and measure particles according to specific particle properties/characteristics, for example a size, mass or charge of the particle. The systems may also separate and measure particles based on a change in a specific property/characteristic of the particles (e.g. size, mass, charge) when the particles are subjected to certain conditions and environments.

One exemplary application for DMAs in tandem measurements (i.e. tandem differential mobility analysis) is to probe for particle properties such as hygroscopicity and volatility [1, 2]. A typical tandem DMA setup comprises a fixed-voltage DMA that supplies a substantially monodisperse aerosol sample. The temperature and/or vapor composition is then changed, typically by flowing the sample through a denuder or a heated tube. The particles respond to this changed environment, and the extent to which they grow or shrink is determined by using a second DMA operating in scanning mode.

Independent of the system used, oftentimes the greatest difficulty in separating and measuring particles with changing environments is the different time histories of the particles as they traverse the intermediate step where a sample property, such as the temperature or composition, is changed. For example, temperature and vapor changes respectively rely on diffusion from and to the walls of the system, which is often a comparatively slow process relative to the sample flow through the system. Furthermore, particles that are near the walls may experience a substantially different environment as compared to those further away from the walls of the system. Thus, a final measured signal is often an amalgamation of particles subject to inconsistent conditions and environments under a wide range of time histories. Therefore, the effect of changing a property of a sample is difficult to measure and quantify with great certainty and the separation or measurement of specific particles is equally frustrated.

In view of the above, there is a need for a method, apparatus, and article of manufacture for rapidly changing sample properties, such as the fluid temperature, particle size, and/or fluid chemical composition. Furthermore, there is a need for a method, apparatus, and article of manufacture for performing tandem mobility analysis that subjects particles in a sample to uniform conditions and environments under more consistent time histories, which will allow for more easily quantifiable separations and measurements.

SUMMARY OF THE INVENTION

The invention provided herein has a number of embodiments useful, for example, in changing a property of a sample. According to one or more embodiments of the present invention, a method, apparatus, and article of manufacture are provided for rapidly changing a sample property, such as the fluid temperature, particle size, and/or fluid chemical composition, using an opposed migration aerosol classifier (OMAC).

In one aspect of the present invention, a method for changing a property of a sample is provided. The method comprises introducing a sample, comprising one or more particles suspended within a sample fluid, through a channel. The channel comprises two walls that are permeable to a flow of fluid. A fluid cross-flow of predetermined chemical composition is introduced at a predetermined temperature to the channel through one of the permeable walls. This cross-flow flows at a first velocity and exits in a first direction through the other permeable wall. An imposed field (where the field can be an electric, magnetic, thermal, gravitational field, amongst others) is applied on the one or more particles in the sample in a second direction counter to the first direction of the cross-flow. The imposed field causes the one or more of the particles of desired size and/or charge to migrate at a second velocity opposite and/or equal to a first velocity of the cross-flow. The particles that travel through the channel are discharged. Furthermore, the particles that travel through the channel are discharged at the predetermined temperature of the cross-flow fluid. In one or more embodiments, the sample fluid is substantially replaced by the cross-flow fluid as the sample flows through the channel. Therefore, the discharged particles that travel through the channel are no longer suspended within the sample fluid but are rather suspended within the cross-flow fluid.

In certain embodiments of the invention, the cross-flow fluid, which may contain one or more trace vapors, replaces a trace vapor in the sample fluid. In further embodiments of the invention, a size of the one or more particles of the sample is changed while the one or more particles travel through the channel due to a difference in the sample fluid and cross-flow fluid temperatures and/or a difference in the concentration of one or more vapors in the sample fluid and the cross-flow fluid. In still other embodiments, the chemical composition of the sample fluid is changed while the one or more particles of the sample travel through the channel.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Overview

An opposed migration aerosol classifier (OMAC) is an excellent option for nanoparticle classification in the gas phase [3]. Its performance is favorable relative to other alternatives in that it is well suited for classifying sub-10 nm aerosol and gas ions. Additionally, OMAC instruments may be made with a more compact footprint than the commonly used alternative of differential mobility analyzers (DMA) [4-6]. Thus, in one exemplary implementation, an OMAC may be used in tandem mobility analysis as a replacement to a first stage DMA. An OMAC may also be used as a replacement to a second stage DMA, though the design of a scanning OMAC is more complex.

In one aspect of the present invention, methods and systems are provided using an OMAC for replacing the diffusion-based methods currently used for changing fluid sample properties. These methods and systems that are related to the OMAC rely on the advection of a fluid sample through cross-flows and imposed fields, which are both considerably faster than diffusion, to change various properties of the sample and the particles within the sample. Thus, for example, OMACs are excellent for rapid gas exchange when compared to other mobility analyzers. For an aerosol sample, the aerosol inlet gas is rejected from the system almost immediately and replaced by a desired cross-flow gas, thereby rapidly changing the properties of the sample.

Though the usage of an OMAC is described in various embodiments of the invention as follows, other differential electrical mobility classifiers (DEMC) may also be used for changing the properties of a sample, such as rapidly changing the gas temperature and/or composition in which a charged aerosol is suspended. Suitable DEMCs include, but are not limited to, OMACs, DMAs, and IGMAs of planar, radial, coaxial cylindrical, conical, and other geometries. For example, an inclined grid mobility analysis (IGMA) may be used since, similar to an OMAC, it also shares favorable up-scaling in performance metrics when compared to DMAs [7].

Logical Flow

FIG. 1is a flow chart illustrating a logical flow100for changing a property of a sample in accordance with one or more embodiments of the invention. At block102, a sample, comprising one or more particles suspended within a sample fluid, is introduced into a channel. The sample may be a variety of substances in a variety of forms. For example, the sample may take the form of an aerosol, gas mixture, colloid, suspension of particles in a fluid, or liquid solution. Furthermore, the sample may be a polydisperse sample (i.e. comprising particles of various size, shape, and/or mass) or may be a monodisperse sample (i.e. comprising particles of uniform size, shape, and/or mass). The sample may also include trace vapors that are also introduced when the sample is injected or pumped into the channel. The channel has two or more walls that are permeable to the flow of fluid (liquid or gas). In one or more embodiments, the channel is part of a classification region of an opposed migration aerosol classifier (OMAC) or radial opposed migration aerosol classifier (ROMAC).

At block104, the sample flows through the channel between the two or more permeable walls. A pressure difference between the inlet/entrance region (i.e. where the sample is introduced) and outlet/exit region (i.e. where the sample is discharged) of the channel causes the sample to flow in one general direction through the channel. In one or more embodiments the sample flow is laminar.

At block106, a cross-flow at a predetermined temperature is introduced to the channel through one of the permeable walls. The cross-flow may also be a variety of substances in a variety of forms. For example, the cross-flow may be a liquid, gas, or comprise solids suspended in a fluid, etc. The cross-flow flows at a first velocity and exits in a first direction through the other permeable wall. In one or more embodiments, the cross-flow exits the channel through a wall directly opposite the wall it is introduced through. As the cross-flow exits the channel, the cross-flow forces the initial sample fluid to exit along with it through the permeable wall. Therefore, the sample fluid of the sample is replaced by the cross-flow as the sample flows through the channel. By replacing the sample fluid with the cross-flow, any trace vapors that were introduced along with the sample will also be forced out through the permeable wall. Moreover, the predetermined temperature of the cross-flow replaces and changes the temperature of the sample and its particles.

At block108, an imposed field is applied in a second direction that is counter to the first direction of the cross-flow. In one or more embodiments, the direction of the imposed field is orthogonal to the direction of the flow of the cross-flow. The imposed field causes the targeted particles in the sample to migrate at a velocity that is opposite and/or equal in magnitude to the velocity of the cross-flow. Therefore, as the cross-flow forces the sample fluid to exit along with it through the permeable wall, the particles that are balanced by the imposed field and cross-flow remain within the channel and are retained in the sample. For particles where the imposed field subjects a force that is not equal to the cross-flow, the particles will move in an overall direction towards one of the permeable walls rather than remain between the walls.

At block110, the particles remaining in the channel (i.e., those particles whose field migration velocity is opposite and equal to the cross-flow velocity) are discharged. It should be noted that the particles may migrate within a range of migration velocities that may not be exactly equal to the cross-flow but still travel through the channel and be discharged.

Since the temperature of the sample may be changed by the predetermined temperature of the cross-flow, the particles that travel through the channel are at the predetermined temperature of the cross-flow when they are discharged. Further, in one or more embodiments, a vapor-free cross-flow removes the trace vapors in the sample and thus the trace vapors are not included with the discharged particles that travel through the channel.

Subsequent actions may then process and/or use the discharged particles. In one or more embodiments, the discharged particles that travel through the channel are analyzed or scanned to determine a change in a property/characteristic of the discharged particles resulting from changing a property of the sample. In one exemplary application, a differential mobility analyzer (DMA) is used to scan the discharged particles. The discharged particles may also be collected as a classified and/or purified sample. In one or more other embodiments, the discharged particles that travel through the channel are classified based on a property of the discharged particles, for example a size, mass or charge of the discharged particles.

While particles that remain in the flow through the channel are discharged, various other particles may be removed from the flow. For example, particles that reach the permeable walls may be removed from the flow through the channel either by deposition on and adhesion to the walls or by passing through the walls.

It should be noted that the functions noted in the blocks may occur out of the order noted inFIG. 1. For example, in one or more embodiments, blocks106and108which are shown in succession may in fact occur concurrently/in parallel. In other embodiments, due to the positioning of the cross-flow, blocks106and108may occur in the reverse order, where the particles are subject to the imposed field before coming into contact with the cross-flow.

Illustrative System for Changing Sample Properties

FIG. 2is an illustrative diagram of how properties of a sample are changed in accordance with one or more embodiments of the present invention. A particulate-laden fluid sample200is pumped or injected into a channel202. A pressure difference between the inlet/entrance (i.e. where the sample is injected) and outlet/exit (i.e. where the sample is discharged) regions of the channel202causes the sample200to flow in one direction through channel202. In various embodiments, this channel202is part of the classification region of an OMAC. The particulate-laden sample200may be a polydisperse sample (i.e. comprising particles of various size, shape, and/or mass) or may be a monodisperse sample (i.e. comprising particles of uniform size, shape, and/or mass).FIG. 2shows, for example, a polydisperse sample200comprising particles of various sizes,218,220, and222.

The sample200travels between two walls204and206of channel202that are permeable to the flow of gases or liquids. The permeable walls204and206may include filters that can capture particles or may be made of a mesh, screen, foam, frit, honeycomb, or porous material (e.g., a porous metal such as sintered metal) that allows particles to pass through it.

A fluid cross-flow208enters the channel202through a wall206, and exits through the opposing wall204. The fluid cross-flow208follows streamlines210due to the orthogonal velocity of sample200relative to the initial velocity of cross-flow208. The fluid cross-flow208may be a gas or liquid and imparts a drag force214(FD) on the particles suspended within the sample fluid. The drag force214is strong enough to potentially cause all the particles in sample200to be lost by passing through the wall204or by deposition onto the wall204.

In one or more embodiments, the cross-flow208is at a desired temperature predetermined by a user. As the cross-flow fluid208replaces the sample fluid by forcing the sample fluid out of the channel202through the opposing wall204along streamlines210, the predetermined temperature of the cross-flow208rapidly replaces and changes the temperature of the sample and its particles.

In one or more further embodiments, the cross-flow208is vapor-less. By forcing the sample fluid out of the channel202through opposing wall204along streamlines210, a sample fluid that includes trace vapors224is replaced with a cross-flow fluid208that is vapor-less. Thus, any trace vapors224that are introduced when the sample200is injected into the channel202are removed/replaced with the vapor-less cross-flow.

Additionally, an imposed field imparts a force216counter to the drag force214. The imposed field can take several forms. For example, the particles218-222may be first charged or may already carry a charge and the imposed field may be an electric field that causes the particles218-222to move counter to the cross-flow208. Likewise, the imposed field may be a magnetic field that is imposed on magnetic particles. In another example, the channel202is horizontal or inclined at an angle so that gravitational sedimentation counters an upward cross-flow. The channel202may also be arranged in a drum and spun so that centrifugal forces are imposed on the particles218-222. Temperature differences between the two walls204and206may also be used to create a thermophoretic migration of the particles218-222that is counter to the cross-flow208.

In one or more embodiments, as illustrated inFIG. 2, the imposed field is an electric field created by a conductive wall204at a high voltage and a conductive wall206at ground voltage. The voltage difference imparts an electric force (FE)216on the particles218-222in a direction that is counter and opposite to the drag force214. Depending on certain properties/characteristics of the particles218-222, such as the size, shape, and/or mass, the electric force216will cause each particle218-222to migrate at a specific velocity towards wall206.

Due to the advective flow of the sample200through channel202, particles218-222of a certain property/characteristic (e.g. size, shape, mass, charge) that are substantially balanced by the drag force214and the force216created by the imposed field will traverse the classification region, while particles218-222that are different and subject to unbalanced forces will impact one of the walls204or206. In other words, if the cross-flow208velocity is exactly equal but opposite to the migration velocity of the particles218-222due to the imposed field, the particles218-222will remain entrained in the sample and be carried straight though channel202. Particles218-222that migrate at a higher or lower velocity than the velocity of the cross-flow208are transmitted to one of the walls204or206. These particles218-222are lost through the walls204/206or may be disposed of, for example by deposition on and adhesion to the walls204/206.

FIG. 2illustrates a polydisperse sample200, comprising particles218,220, and222of varying sizes that migrate at different velocities, which result in varying mobility separations. By adjusting the cross-flow velocity and the imposed field, a particle of a desired size220will remain in the channel202while the other particles218and222are removed. Specifically, a smaller particle222exits the channel202through wall206and a larger particle218exits through wall204, while a particle of the desired size220exits through the outlet region of channel202. In other embodiments, for example when the imposed field is gravity-based, the respective directions of larger and smaller particles218and222are opposite of that for an imposed electric field.

Note however, that for the particle220to reach the outlet of the channel202, the velocity of the cross flow208need not be exactly equal and opposite the particle migration velocity caused by the imposed field. Particles218-222subject to slightly unbalanced counteracting velocities may still successfully traverse the channel202due to the finite length of channel202. Particles218-222migrating at a velocity that is sufficiently close to and opposite the cross-flow208may possibly remain entrained in the sample200for a sufficient amount of time to travel through channel202and be discharged before impacting wall204or206. Thus, the length of the channel202may be changed depending on the desired level of specificity for particles218-222of particular properties/characteristics (e.g., size, shape, mass, charge). Successful particle travel through a longer channel202would require more balanced counteracting forces on the particle218-222, which means a smaller range of variability in the properties/characteristics (e.g., size, shape, mass, charge) of the particles218-222discharged. On the other hand, successful particle travel through a shorter channel202would require less balancing of the counteracting forces on the particle218-222, which means a greater range of variability in the properties/characteristics (e.g., size, shape, mass, charge) of the particles218-222discharged.

The sample200comprising classified particles218-222of a certain property is continuously discharged from channel202as a classified sample flow212. As described previously, the cross-flow208is able to rapidly change the temperature of the sample200and its particles218-222as well as remove any trace vapors224within the sample200. Thus, as shown inFIG. 2, the discharged classified sample flow212is at a desired temperature, vapor-less, and comprising particles218-222of a desired characteristic.

Furthermore in one or more embodiments, the invention is able to change the size of the particles218-222within a sample200. By changing the temperature of the sample200, the particles218-222within the sample200are rapidly and uniformly heated or cooled as they travel through the channel202. With the heating or cooling of the particles218-222, the size of the particles218-222may be respectively increased or decreased through thermal expansion or contraction. Thus, by controlling the predetermined temperature of the cross-flow208, the size of the discharged particles218-222may be controlled.

In further embodiments, the invention is able to change the chemical composition of the sample200. In addition to removing trace vapors224with a vapor-free cross-flow208, the fluid cross-flow208is able to remove and/or replace other compositions, vapors, and gases within a sample200depending on the composition of the replacement cross-flow208. Moreover, volatile particles218-222or components within the sample200may be evaporated from the sample by heating the sample200with a predetermined cross-flow temperature and/or removing vapors within the sample200, thereby decreasing in size particles218-222. Additionally, particles218-222may be increased in size if the replacement cross-flow208is composed of vapors that can condense onto particles218-222and the temperature of cross-flow208does not prevent these additional vapors from condensing onto particles218-222. The composition of a sample200may be finely controlled due to the different evaporation or condensation rates of the particles or components. If certain volatile compounds are desired in the classified sample flow212, the cross-flow208will contain these compounds in the desired concentrations. These concentrations can be set at a level to condense onto and grow particles218-222, or at a level to cause no change in the size of particles218-222and maintain the particle size after exiting the invention in the classified sample flow212.

The cross-flow208exiting through wall204or the sample flow212exiting the channel202may be analyzed or scanned continuously to determine particle property/characteristic (e.g., size, mass, charge) distributions. For example, knowledge of the particle size dependence for migration velocity or mobility and the strength of the cross-flow208and the imposed field would enable a determination of the particle size distributions.

To allow even larger flows, multiple channels202may be arranged in parallel, with a single cross-flow208passing through the successive channels202. In the case of electrophoretic migration, the electric potential on successive walls may be alternated, which would enable large volumetric flows to be separated without having to resort to unreasonably high voltages.

In addition, if the particles218and222are allowed to migrate through the walls204or206, provision may be taken to remove the particles218and222from the cross flow208so that the cross-flow208can be re-circulated. Such provisions may include filtration of the cross-flow208after it exits the channel202.

Details of Changing Sample Properties with a Radial Opposed Migration Aerosol Classifier (ROMAC)

In one or more embodiments of the invention, a radial opposed migration classifier (ROMAC) is used to change the properties of a sample.FIG. 3is an illustrative diagram of how a sample300would traverse a ROMAC302.

ROMAC302has an inlet port304and outlet port306for a sample300, such as polydisperse, positively charged aerosol, and an inlet port308and outlet port310for a vapor-free cross-flow312. The aerosol inlet port304of the ROMAC302would receive the sample300, which would enter a flow distributor314(“racetrack”). In one or more embodiments, the sample300enters the flow distributor314tangentially. Due to the pressure difference between the racetrack314and the sample outlet306, the sample300will be uniformly and radially drawn toward the center outlet port306through a narrow knife edge gap316. After passing through the narrow knife edge gap316, the sample300is now in the classification region318, where only the particles that are balanced by both the drag and imposed field forces imparted on them will successfully traverse the classification region318and exit the ROMAC302through the central outlet port306.

The aerosol inlet port304may be open to ambient fluid or connected to an apparatus that would provide the sample, such as a reaction chamber, electrospray ionization chamber, or nebulizer. The aerosol outlet port306may be connected to an apparatus that would provide negative pressure, such as a condensation nuclei counter pulling a vacuum. The cross-flow inlet port308may be connected to an apparatus that would provide vapor-free clean air at a controlled temperature and flow rate, while the cross-flow outlet port310may be connected to a vacuum that would result in a matched flow rate to the cross-flow inlet. In one or more embodiments, the upper plate320of the classification region is at electrical ground voltage, while the bottom plate322of the classification region is at a high positive voltage.

FIG. 4shows a perspective view of a 2-plane sectional cut of an assembled ROMAC system400in accordance with one or more embodiments of the invention. A top lid410, a bottom lid428, and a side case418form an outer enclosure for the system400.

A classification region, similar to the channel202illustrated inFIG. 2and channel318illustrated inFIG. 3, is created by a knife edge top402, knife edge bottom404, variable gap spacer406, bottom base408, and conductive, porous screens (not shown) stretched across top screen holder416and bottom screen holder420. The thickness dimension of variable gap spacer406may be adjusted to change the space between the knife edge top402and bottom base408. A top screen holder416and a bottom screen holder420are used to hold respective top and bottom permeable walls, such as stretched stainless steel mesh (not shown). A top frit414and bottom frit422serve to laminarize the cross-flow before it enters the classification region. The top frit414is held in place and may be positionally adjusted within the system400by a threaded frit spacer412. Similarly, bottom frit422is held in place and may be positionally adjusted within the system400by a bottom frit spacer424.

Additionally, the top frit414, threaded frit spacer412, and top lid410all include central openings434,436, and438for a single outlet tube (not shown) to pass through the respective central openings434,436, and438and rest on a screen stretched across top screen holder416. The single outlet tube is connected to the classification region and provides a negative pressure that allows particles that are balanced by both the drag and imposed field forces to be discharged from the system400through the single outlet tube (not shown).

A flow distributor430includes a narrowing gap432, similar to the narrow knife gap316illustrated inFIG. 3, which leads to the classification region. The narrowing gap432is created by the knife edge top402and knife edge bottom404. In one or more embodiments, the sample is introduced tangentially into the flow distributor430.

In one or more embodiments, top lid410, knife edge top402, knife edge bottom404, top screen holder416, top frit414, threaded frit spacer412, and the outlet tube (not shown) that passes through central openings434-438and rests on a conductive screen (not shown) stretched across top screen holder416are at electrical ground. Side case418, variable gap spacer406, and bottom lid428are electrical insulators. Bottom base408, bottom screen holder420, bottom frit422, bottom frit spacer424, variable gap compensator spacer426, and a conductive screen (not shown) stretched across bottom screen holder420are at a non-ground electrical potential. A post446extends from variable gap compensator spacer426through bottom lid428serves as a means to apply a non-ground electric potential.

Illustrative Models and Simulations

As illustrative examples, the invention was modeled as a radially symmetric space similar to the ROMAC302depicted inFIG. 3in COMSOL™ Multiphysics 4.1™ to obtain values for fluid properties, fluid flows, electric fields, and concentrations of dilute vapors in the region of the invention through which aerosol particles will flow through. The electric potential solution is shown inFIG. 5, the combined sample and cross-flow fluid velocity magnitude solution is shown inFIG. 6, the fluid temperature solution is shown inFIG. 7, and the dilute species vapor concentration is shown inFIG. 8. All four of the figures were modeled at an aerosol flow rate of 1 lpm and a cross-flow rate of 2 lpm, with a cross-flow temperature of 320 K, an incoming aerosol vapor concentration of 5.1 mol/m3, and an incoming sample vapor diffusivity of 5.8×10−6m2/s.

FIG. 7demonstrates that the invention as modeled sufficiently exchanges the gas such that it is rapidly and uniformly heated to the desired temperature (in this case, 320 K) by the time the particles reach the aerosol outlet.

FIG. 8demonstrates that the invention as modeled sufficiently removes the trace vapors present in the original incoming aerosol gas, such that by the time the particles reach the aerosol outlet, they are surrounded in vapor-free fluid.

The COMSOL™ solutions were then used as inputs for a MATLAB™ script developed to simulate the trajectories of particles of a particular size when released into the invention. The trajectories used inputs of fluid velocity, density, viscosity, temperature, and electric potential to simulate the movement of particles, their change in size, and the change in chemical composition in finite time steps. In addition, diffusional movement of the particles was simulated as well.

FIG. 9shows a simulation of 100 nm particles composed of three organic substances with different volatilities traversing the invention with the porous, conductive walls having a voltage difference that was predicted to yield the maximum transmission of particles through the classification region. The aerosol flowrate was set at 0.1 lpm, cross-flow rate at 0.3 lpm, temperature at 320 K, and voltage at 490 V. The type of simulation illustrated inFIG. 9was repeated at various voltages to obtain a predicted transfer function (FIG. 10) for the invention. The results demonstrate the feasibility of the invention, as the numerical simulations were executed with well-reputed software and relied on the established knowledge of mechanisms of particle movement.

FIG. 10illustrates a simulated transfer function of 100 nm particles traversing through the invention at an aerosol flow rate of 0.1 lpm, cross-flow rate of 0.3 lpm, and temperature at 320 K. The vertical line indicates the theoretical voltage that would result in a balance of the drag force and electric force imparted on the particles (which would result in maximum transmission, i.e. 100% transmission of the particles). The peak of the simulated transfer function is in very good agreement with the theoretical voltage for 100% transmission, but is slightly shifted to the left, since particles were slowly evaporating and shrinking as they were traversing the classification region, due to the heat and gas exchanging functions of the instrument.

FIG. 11illustrates the simulated diameter change of each individual 100 nm particle, showing each particle's size evolution as it traverses the invention. The aerosol flow rate is set at 0.1 lpm, cross-flow rate at 0.3 lpm, temperature at 320 K, and voltage at 470 V.

FIG. 12illustrates the simulated chemical composition change of 100 nm particles traversing through the invention an aerosol flow rate of 0.1 lpm, cross-flow rate of 0.3 lpm, temperature of 320 K, and voltage of 470 V. Initial chemical composition is 33% of each of 3 species1202,1204, and1206.1202is the most volatile species, followed by1204, followed by1206being the least volatile species. The chemical composition change of each particle is shown as different components of the particles evaporate at different rates due the heat and vapor removal functions of the invention.

CONCLUSION

The foregoing description of the preferred embodiment of the invention has been presented for the purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise form disclosed. Many modifications and variations are possible in light of the above teaching. It is intended that the scope of the invention be limited not by this detailed description, but rather by the claims appended hereto. All publications, patents, and patent applications cited herein are hereby incorporated by reference in their entirety for all purposes.

REFERENCES