Classifications

• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B82—NANOTECHNOLOGY
  • B82B—NANOSTRUCTURES FORMED BY MANIPULATION OF INDIVIDUAL ATOMS, MOLECULES, OR LIMITED COLLECTIONS OF ATOMS OR MOLECULES AS DISCRETE UNITS; MANUFACTURE OR TREATMENT THEREOF
  • B82B3/00—Manufacture or treatment of nanostructures by manipulation of individual atoms or molecules, or limited collections of atoms or molecules as discrete units
• • C—CHEMISTRY; METALLURGY
  • C01—INORGANIC CHEMISTRY
  • C01B—NON-METALLIC ELEMENTS; COMPOUNDS THEREOF; METALLOIDS OR COMPOUNDS THEREOF NOT COVERED BY SUBCLASS C01C
  • C01B32/00—Carbon; Compounds thereof
  • C01B32/05—Preparation or purification of carbon not covered by groups C01B32/15, C01B32/20, C01B32/25, C01B32/30
• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B82—NANOTECHNOLOGY
  • B82Y—SPECIFIC USES OR APPLICATIONS OF NANOSTRUCTURES; MEASUREMENT OR ANALYSIS OF NANOSTRUCTURES; MANUFACTURE OR TREATMENT OF NANOSTRUCTURES
  • B82Y30/00—Nanotechnology for materials or surface science, e.g. nanocomposites
• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B82—NANOTECHNOLOGY
  • B82Y—SPECIFIC USES OR APPLICATIONS OF NANOSTRUCTURES; MEASUREMENT OR ANALYSIS OF NANOSTRUCTURES; MANUFACTURE OR TREATMENT OF NANOSTRUCTURES
  • B82Y40/00—Manufacture or treatment of nanostructures
• • C—CHEMISTRY; METALLURGY
  • C01—INORGANIC CHEMISTRY
  • C01B—NON-METALLIC ELEMENTS; COMPOUNDS THEREOF; METALLOIDS OR COMPOUNDS THEREOF NOT COVERED BY SUBCLASS C01C
  • C01B32/00—Carbon; Compounds thereof
  • C01B32/15—Nano-sized carbon materials
• • C—CHEMISTRY; METALLURGY
  • C01—INORGANIC CHEMISTRY
  • C01G—COMPOUNDS CONTAINING METALS NOT COVERED BY SUBCLASSES C01D OR C01F
  • C01G23/00—Compounds of titanium
  • C01G23/04—Oxides; Hydroxides
  • C01G23/047—Titanium dioxide
• • C—CHEMISTRY; METALLURGY
  • C01—INORGANIC CHEMISTRY
  • C01P—INDEXING SCHEME RELATING TO STRUCTURAL AND PHYSICAL ASPECTS OF SOLID INORGANIC COMPOUNDS
  • C01P2002/00—Crystal-structural characteristics
  • C01P2002/70—Crystal-structural characteristics defined by measured X-ray, neutron or electron diffraction data
  • C01P2002/72—Crystal-structural characteristics defined by measured X-ray, neutron or electron diffraction data by d-values or two theta-values, e.g. as X-ray diagram
• • C—CHEMISTRY; METALLURGY
  • C01—INORGANIC CHEMISTRY
  • C01P—INDEXING SCHEME RELATING TO STRUCTURAL AND PHYSICAL ASPECTS OF SOLID INORGANIC COMPOUNDS
  • C01P2002/00—Crystal-structural characteristics
  • C01P2002/80—Crystal-structural characteristics defined by measured data other than those specified in group C01P2002/70
  • C01P2002/82—Crystal-structural characteristics defined by measured data other than those specified in group C01P2002/70 by IR- or Raman-data
• • C—CHEMISTRY; METALLURGY
  • C01—INORGANIC CHEMISTRY
  • C01P—INDEXING SCHEME RELATING TO STRUCTURAL AND PHYSICAL ASPECTS OF SOLID INORGANIC COMPOUNDS
  • C01P2002/00—Crystal-structural characteristics
  • C01P2002/80—Crystal-structural characteristics defined by measured data other than those specified in group C01P2002/70
  • C01P2002/85—Crystal-structural characteristics defined by measured data other than those specified in group C01P2002/70 by XPS, EDX or EDAX data
• • C—CHEMISTRY; METALLURGY
  • C01—INORGANIC CHEMISTRY
  • C01P—INDEXING SCHEME RELATING TO STRUCTURAL AND PHYSICAL ASPECTS OF SOLID INORGANIC COMPOUNDS
  • C01P2004/00—Particle morphology
  • C01P2004/01—Particle morphology depicted by an image
  • C01P2004/04—Particle morphology depicted by an image obtained by TEM, STEM, STM or AFM
• • C—CHEMISTRY; METALLURGY
  • C01—INORGANIC CHEMISTRY
  • C01P—INDEXING SCHEME RELATING TO STRUCTURAL AND PHYSICAL ASPECTS OF SOLID INORGANIC COMPOUNDS
  • C01P2004/00—Particle morphology
  • C01P2004/51—Particles with a specific particle size distribution
  • C01P2004/52—Particles with a specific particle size distribution highly monodisperse size distribution
• • C—CHEMISTRY; METALLURGY
  • C01—INORGANIC CHEMISTRY
  • C01P—INDEXING SCHEME RELATING TO STRUCTURAL AND PHYSICAL ASPECTS OF SOLID INORGANIC COMPOUNDS
  • C01P2004/00—Particle morphology
  • C01P2004/60—Particles characterised by their size
  • C01P2004/64—Nanometer sized, i.e. from 1-100 nanometer

Definitions

• TECHNICAL FIELD This invention relates to methods and apparatus for generating nano-sized particles.
• these materials are suitable for use in applications requiring high concentration and high purity, including, but not limited to, inhalation toxicology studies, manufacturing applications, occupational safety and health studies, and as drug delivery systems.
• the invention is particularly well suited and enables the generation of high concentrations of nano-sized particles of Ceo aerosols.
• Nano scale materials can access regions of the body that are not open to larger particles, and that there is evidence that nano particles will be capable of crossing the blood-brain barrier, and leaking out of capillaries. Nano scale materials may enter via mechanisms that are distinct from larger particles and may escape common clearance pathways for particulate matter.
• nano materials have a very high surface to volume ratios; their high surface-free energy leads to facile adsorption of molecular contaminants, offering a potential route for such molecular contaminants into regions of the body not normally accessible. Accordingly, as will be appreciated by those having ordinary skill in the art, methods and apparatus suitable for generating nano-sized particles would thus be useful not only for inhalation studies, but also for any application where these nano-sized particles, and substances contained within them or chemically bonded to them, are introduced into regions of the body not readily accessible by other means. Accordingly, there is a need in the art for methods and apparatus suitable for generating nano-sized particles.
• One object of this invention is to provide a method and apparatus for generating nano particles at high concentration. It is another object of the present invention to provide a method for generating nano particles of Buckminster fullerene, Ceo at high concentration in a gas flow suitable for inhalation toxicology studies.
• the apparatus of the present invention begins with the use of a solid aerosol disperser.
• solid aerosol disperser refers to any apparatus which provides a flow of solid particles in a gaseous flow.
• solid air dispersers suitable for use with the present invention are currently available from a variety of vendors.
• a Model 3433 Small Scale Powder Disperser available from TSI, Inc. may be used alone or in conjunction with a TROSTTM Gem T mill, available from Plastomer Technologies, to generate a flow of particles in a gaseous stream.
• Battelle Memorial Institute (Columbus, OH) assignee of the present invention, also has available a solid aerosol disperser that is commercially available, and is particularly well suited to the practice of the present invention.
• the present invention thus provides a method whereby those particles are reduced further in size while maintaining purity, such that the resulting particles are of less than 100 nm count median diameter (CMD) and do not exhibit chemical decomposition of C ⁇ o to an amorphous phase or to carbon black.
• the "nano sized particles" produced by the present invention are defined herein as particles having less than 100 nm count median diameter (CMD).
• the present invention should not be viewed as limited to the solid aerosol disperser provided by any particular vendor.
• the present invention places some or all of the output of the solid aerosol disperser in communication with the input of the vaporization chamber of a furnace tube.
• a heating element is in proximity, and preferably surrounds, the vaporization chamber, which is kept at a temperature sufficient to heat the bulk materials within the furnace tube to a temperature sufficient to convert the bulk materials to the vapor phase.
• Other means of providing heating to the furnace to the levels described herein are possible, whether through direct conduction, radiant heating, a heating element, or other means whereby energy is conveyed to material in the furnace.
• Vaporized materials leaving the vaporization chamber enter the input end of a dilution chamber of the furnace tube.
• the dilution chamber is designed such that the bulk materials are rapidly condensed as they exit the furnace tube in a manner that prevents them from agglomerating with one and another. In this manner, the present invention successfully forms nano sized particles at high concentrations and at high levels of purity.
• the furnace tube condenses the bulk materials without agglomerating them because the furnace tube has an additional gas flow introduced into the dilution chamber through a dilution gas port.
• the increased gas flow introduced through the dilution gas port serves to rapidly evacuate the dilution chamber, thereby forcing the vaporized materials to be rapidly cooled at the exit of the dilution chamber at the same time that the velocity of the gas flow is dramatically increased.
• the result of this rapid cooling and increased gas flow is that the vaporized materials condense into nano sized particles within the gas flow, and do not agglomerate with one and another.
• rate of the gas into the vaporization chamber and the gas flow rate into the dilution chamber are adjusted to insure that the residence time that the vaporized bulk material in the dilution chamber is minimized.
• residence time that the vaporized bulk material in the dilution chamber is no more than 30 seconds, and it is more preferred that the vaporized bulk material are in the dilution chamber no more than 5 seconds.
• the present invention forms nano sized particles in a gas flow at higher concentrations than methods previously known in the art.
• the rapid transport of the vaporized materials through the dilution port is assisted by providing a cup receiver having an input end within the dilution chamber and an output end used as the output end of the dilution chamber.
• a cup receiver is any tube having a relatively large entrance at one end, and a relatively smaller exit at the opposite end.
• the cup receiver is positioned within the dilution chamber such that vaporized materials entering the dilution chamber traverse a short distance of open space, and then enter the relatively large opening of the cup receiver.
• the additional gas flow introduced through the gas port also enters the cup receiver at the relatively large end.
• the gas flow and the vaporized materials are combined within the cup receiver in a manner that minimizes the dilution of the vaporized materials.
• the dilution materials are thus moved through the cup receiver as quickly as possible, exiting at the output end, thus maximizing the temperature drop and cooling the vaporized materials as quickly as possible.
• Modeling of the gas flow in the preferred embodiment has shown that the dilution materials are moved through the cup receiver essentially along a linear pathway, thus maximizing the temperature drop thereby cooling the vaporized materials as quickly as possible.
• the present invention also enables the creation of less than pure nano sized particles, various particle sizes, and various particle size distributions.
• when forming particles of Ceo. adjusting the mass flow rate, gas flow rate, and furnace temperature will have an impact on the purity, particle sizes, and particle size distributions that can be formed in the apparatus of the present invention. As shown in the Table 1 below, both particle size and purity are affected by the furnace tube temperature.
• the present invention should be understood to encompass all systems which adjust mass flow rates, gas flow rates, and furnace temperatures to produce specific particle sizes, size distributions, and purities. Those having ordinary skill in the art will recognize that in applications such as toxicology studies and chemical manufacturing this adjustability will allow a practitioner the flexibility to produce a wide variety of outputs. Table 1
• the present invention also contemplates the use of an extraction port positioned between the solid aerosol disperser and the vaporization chamber.
• the extraction port is used to extract a portion of the gas flow prior to introduction into the vaporization chamber.
• the extraction port includes a separator, where a portion of the bulk material having relatively larger particle sizes is separated and extracted prior to introduction into the vaporization chamber. This assists in reducing the particle size further prior to introducing the particles to the inlet of the furnace tube.
• the separator may be a cyclone, an impact device, or combinations thereof.
• While the method of the present invention is particularly well suited to forming nano sized particles of C 6 o, other materials which may be processed by the present invention include, but are not limited to cerium oxide, carbon nano tubes, titanium dioxide, C 70 , C 76 , and C ⁇ 4 .
• the bulk material When forming nano particles of C 6 o with the present invention, it is preferred that the bulk material have a particle size of between about 1 ⁇ m and about 1.5 ⁇ m mass median aerodynamic diameter (MMAD) when introduced into the vaporization chamber. It is also preferred that the vaporization chamber be held at a temperature between about 500° C and 600° C to vaporize the bulk particles of C 6 o-
• MMAD mass median aerodynamic diameter
• the gas used to carry the bulk materials from the solid aerosol disperser to the furnace tube (referred to herein as the "first gas") and the gas introduced into the dilution chamber through a dilution gas port (referred to herein as the “second gas”) are both inert gases.
• inert gases simply means that the gases are not reactive with the bulk material or the nano particles formed of the bulk material. Accordingly, preferred inert gases include, but are not limited to He, N 2 , Ar, Kr, Ne, and combinations thereof.
• the present invention enables inhalation toxicology testing of Buckminster fullerenes (such as C 6 o) which previously could not be conducted as a result of the limitations of the prior art. While the present invention should not be considered as being limited to this use, it should be recognized that the present invention provides this ability because the present invention allows the generation of aerosols of Ceo at high concentration in an oxygen rich environment essentially identical to air.
• the flow of the second gas is sufficient to eject the bulk material from the exit, thereby condensing the bulk material into nano sized particles.
• the nano sized particles are then cooled to a temperature sufficient to prevent oxidation, whereupon a flow of oxygen may be introduced without oxidizing the nano sized particles.
• Figure 1a is a graph showing the phase identification of Ceo Buckminster fullerene bulk powder using X-Ray Diffraction Analysis.
• Figure 1b is a graph showing an exploded view of the XRO spectrum to confirm purity of Ceo sample.
• Figure 1c is a graph showing the Rietveld refinement of Ceo sample.
• Figure 1d is a graph showing the phase identification of nanoparticulate C 6 o on the filter using XRD.
• Figure 1e is a graph showing the phase identification of microparticulate C 6 o on the filter using XRD.
• Figure 2 shows the fully assembled rotary dust generator showing drum driver, body and cap.
• Figure 3a is a perspective view of PAC.
• Figure 3b is a schematic diagram of PAC.
• Figure 4 is two SEM images of Ceo aerosols without using the furnace.
• Figure 5 is a graph showing the concentration (y-axis) versus diameter (x-axis) at the inlet of SMPS.
• Figure 6 is two TEM images of the filter samples with furnace inline.
• Figure 7 is a histogram obtained using a Scion imaging software applied on TEM images.
• Figure 8 is a graph showing the MOUDl mass distribution.
• Figure 9 is a graph showing the Raman spectrum at two different temperatures of the furnace tube.
• Figure 10 is a graph showing the XPS Photoelectron Spectrum.
• Figure 11 is a graph showing the typical HPLC spectrum of a Ceo standard and a sample.
• Figure 12 is a schematic showing the assembly of a preferred embodiment of the present invention.
• Figure 13 is a schematic showing the design of the furnace tube.
• Figure 14 is a graph showing the particle size distribution of test aerosols obtained using SMPS.
• Figure 15 is a graph showing the particle size distribution of test aerosols obtained using MOUDI impactor.
• Figure 16 is a graph showing the chemical characterization using Raman spectroscopy.
• Figure 17 is a schematic showing the design of a preferred embodiment of the furnace tube.
• Figure 18 is a three dimensional model of a preferred embodiment of the furnace tube created by The FLUENT ® Computational Fluid Dynamics Package, Release 6.2.16 (3-dimensional, double precision, segregated solver, laminar flow model with conjugate heat transfer), Fluent Inc., Riverside, NH U.S.A.
• Figure 19 is a three dimensional view of the temperature profile inside a preferred embodiment of the furnace tube created by The FLUENT ® Computational Fluid Dynamics Package, Release 6.2.16 (3-dimensional, double precision, segregated solver, laminar flow model with conjugate heat transfer), Fluent Inc., Riverside, NH U.S.A.
• Figure 20 is a three dimensional view of the gas velocity profile inside a preferred embodiment of the furnace tube created by The FLUENT ® Computational Fluid Dynamics Package, Release 6.2.16 (3-dimensional, double precision, segregated solver, laminar flow model with conjugate heat transfer), Fluent Inc., Riverside, NH U.S.A.
• Figure 21 is a three dimensional view of the particle trajectories inside a preferred embodiment of the furnace tube created by The FLUENT ® Computational Fluid Dynamics Package, Release 6.2.16 (3-dimensional, double precision, segregated solver, laminar flow model with conjugate heat transfer), Fluent Inc., Riverside, NH U.S.A.
• the solid air disperser used to initially generate Ceo aerosols for these studies is available from the assignee herein, Battelle Memorial Institute, Columbus Ohio. Briefly, as shown in Figures 2, 3a and 3b, it consisted of a rotary dust feed device 10 coupled to a single jet Particle Attrition Chamber (PAC) 14. As shown in Figure 2, the rotary dust feed device 10 consists of a drum (not visible), a body 11 , a cap 12 and a drum rotation driver 13. The drum, which rotated during the generation, serves as the reservoir for the bulk material. The drum rotation is accomplished by a compressed air driven Valco valve driver (VICI Valco Instruments Co., Houston, TX) which in turn is controlled by the generator control unit.
• VICI Valco Instruments Co. Houston, TX
• metering ports in a disk on the bottom of the drum are filled with a small amount of the powdered Ceo bulk material.
• a stainless steel screen at the bottom of each metering port prevents the material from falling through the port, while allowing the carrier gas (nitrogen) to pass through from below.
• Each metering port is sequentially aligned with the carrier gas inlet in the body each time the driver was actuated by the generator control circuit.
• a carrier gas solenoid valve is then pulsed open by the generator control unit, creating a carrier gas puff which blows the bulk material from the port and disperses it into a flow of nitrogen.
• the output of the generator is regulated by adjusting the rotation cadence and duration of the nitrogen puff using the generator control unit.
• a Particle Attrition Chamber (PAC) 14 shown in Figures 3 and 3b serves to reduce the particle size of the suspended powder of the bulk material.
• the PAC 14 is similar to a cyclone separator with the addition of an air jet 15 operated at 30 psi at 90° to the aerosol inlet flow 17.
• the air jet 15 breaks up the particle clumps until the particles are small enough to exit the center aerosol outlet port 18.
• a portion of the flow exiting the PAC 14 was siphoned such that -0.400 lpm was passed through to the furnace tube 1 (shown on Figures 13 and 17). Referring to Figure 12, siphoning using a generator siphon 20, occurred at a t-joint 19, which may have had the additional effect of separating larger particles and passing smaller particles to the furnace tube 1.
• the t-joint 19 has the effect of acting as a separator by acting as an impact regime where the larger particles impact the t-joint 19 and are thus siphoned off, whereas smaller particles remain in the gas flow, and are directed toward the furnace tube 1.
• other devices such as a cyclone, could also be used as a separator.
• the furnace tube 1 consists of an inlet 2 and a vaporization chamber 3 in communication with a dilution chamber 4.
• the dilution chamber 4 has an exit 5 and a gas port 6.
• Surrounding the furnace tube 1 is a heating element 7.
• the vaporization chamber 3 was a 12 inch long glass tube with a 2 inch diameter.
• the dilution chamber 4 was a 2 inch long glass tube with a 2 inch diameter.
• the inlet 2 to the vaporization chamber 3 and the exit 5 were all 3/8 inch glass tubing.
• the opening between the vaporization chamber 3 and the dilution chamber 4 was also 3/8 inch.
• the gas port 6 in the dilution chamber 4 was % inch tubing.
• the heating element 7 for these experiments was a commercial furnace Model F21135 supplied by Barnstead International Dubuque, Iowa.
• the furnace was maintained at a temperature (550° C) and the flow rate through inlet 2 was ⁇ 0.400 Ipm, which was sufficient to ensure flash vaporization of the Ceo aerosol. Rapid cooling caused by the introduction of compressed nitrogen at -0.500 Ipm at gas port 6 resulted in the creation of nano-sized aerosols.
• the general arrangement of a preferred embodiment is shown in
• the furnace tube 1 consists of an inlet 2, a vaporization chamber 3 in communication with a dilution chamber 4.
• the dilution chamber 4 has a cup receiver 8, with an output or exit 5 and a gas port 6.
• a heating element 7 Surrounding the furnace tube 1 is a heating element 7.
• buffer zones 9 isolate the interior of the furnace tube 1 from the surrounding atmosphere.
• Figures 18, 19, 20 and 21 are models of the gas flow in the preferred embodiment of the furnace tube 1.
• the models were created by The FLUENT ® Computational Fluid Dynamics Package, Release 6.2.16 (3-dimensional, double precision, segregated solver, laminar flow model with conjugate heat transfer), Fluent Inc., Lebanon, NH U.S.A.
• Figure 18 is a three dimensional model of a preferred embodiment of the furnace tube 1
• Figure 19 is a three dimensional view of the temperature profile inside the furnace tube 1
• Figure 20 is a three dimensional view of the gas velocity profile inside the furnace tube 1
• Figure 21 is a three dimensional view of the particle trajectories inside the furnace tube 1.
• the dilution materials are moved through the cup receiver 8 essentially along a linear pathway, thus maximizing the temperature drop thereby cooling the vaporized materials as quickly as possible.
• the size distribution of the aerosols produced by the methods and apparatuses of the present invention was determined using a cascade impactor (In-Tox Products, Model No. 02-130/SMK, Albuquerque, NM), Scanning Mobility Particle Sizer (TSI Model 3034, Shoreview, MN) (SMPS) (see Figures 5 and 14), TEM imaging (JEOL 2010F, Jeol, Peabody, MA; (see Figures 6 and 7) and
• MOUDI impactor MSP Corp, 125B NanoMOUDI, Shoreview, MN
• MSP Corp 125B NanoMOUDI, Shoreview, MN
• the chemical characterization of Ceo was performed using Laser Raman Infrared spectroscopy (Spex Model 1877, Spex, Edison, NJ) (see Figures 9 and 16) and high performance liquid chromatography (HPLC, Agilent 1100) (see Figure 11 ).
• Samples of aerosols produced by the present invention were collected at sampling port 22 (see Figure 12).
• the collected samples were analyzed for particle size distribution using four different instruments.
• an 8 stage mercer cascade impactor was used to establish the proof of principle.
• the cut-point of the last stage of the impactor was ⁇ 230 nm.
• the flow rate through the impactor was approximately 1.645 Ipm.
• the cascade impactor stages were pre-coated with silicone grease.
• the individual stage filters were analyzed using High Performance Liquid Chromatography.
• the aerosols were sampled through a Scanning Mobility Particle Sizer (TSI Model 303s Shoreview, MN; (see Figures 5 and 14).
• the SMPS size separates the particles on the basis of electrical mobility of the particles.
• the Model 3034 has the size range from 10 to 487 nm electrical mobility diameter.
• the aerosol stream passes through a single-stage cyclone which removes large particles (>0.8 //m) outside the instrument measurement range.
• the aerosol then passes through a bipolar ion neutralizer that imparts a high level of positive and negative ions. Charged and neutral particles enter the differential mobility analyzer (DMA) column where particles are separated according to their electrical mobility.
• DMA differential mobility analyzer
• the particles exiting the DMA are first passed through a saturator picking up butyl alcohol vapor in the sample stream.
• a second cooling stage causes the vapor to condense on the particles, growing them to readily detectable size.
• These particles are then directed to a condensation particle counter where a determination of particle concentration is made by passing the particles through a focused laser light.
• the samples were also analyzed using a Scanning Electron Microscope (LEO 982 FE-SEM, Zeiss Thornwood, NY) (see Figure 4) and a Transmission Electron Microscope (JEOL 2010F, Jeol, Peabody, MA) (see Figure 6).
• the SEM images of the bulk material and during the initial stages of the experiments were taken to establish the size distribution of bulk test material.
• the aerosols were collected on a gold plated 25 mm membrane filters (Pal Gelman, NY).
• TEM images of the samples were taken.
• For TEM the samples were collected on a carbon coated lacy copper grid. The samples were collected for enough duration to have uniform coating of test material on the grid.
• the microscope was operated at 200KeV with a field emission gun.
• the compositional analysis software used was INCA x-ray energy spectroscopy system from Oxford Instruments.
• the particle size distribution was also determined using a Micro Orifice Uniform Deposit lmpactor (MOUDI, MSP Corp, 125B NanoMOUD.I
• This impactor has thirteen rotating stages with nominal cut points varying from 10 ⁇ m to 10 nm when operated at an inlet flow rate of 10.0 Ipm.
• the last few stages of the MOUDI impactor are under low pressure which increases the Cunningham slip correction and thus reduces the cut point of the stages.
• the detection of Ceo was also carried out using an Agilent 1 100 high pressure liquid chromatograph (HPLC) equipped with an Agilent 1 100 variable wavelength detector (see Figure 11 ).
• the detector was configured at a wavelength of 330 nm and a peak width of >0.1 min.
• the iso critical separation method involved a 5 ⁇ injection onto a Cosmosil BuckyPrep analytical column (25 cm x 4.6 mm ID; 5 ⁇ m) with toluene as the mobile phase.
• the flow rate of the mobile phase was set at 1 mL/min with a run time of 20 minutes; retention time for the Ceo was ⁇ 8 minutes.
• the Mercer cascade impactor analysis was very helpful during the early stages of the experiments while optimizing the furnace temperature and location.
• the mercer cascade impactor samples were collected without a tube furnace in line to determine the size distribution of the bulk material. Two samples were collected at different pressure of the compressed nitrogen in the PAC. Table 2 shows the MMAD and GSD of the results obtained.
• Figure 5 shows the SEM images of the filters at 2 different magnifications. Clearly, large aggregates were observed by both the TEM and the cascade impactor analysis.
• the furnace tube was then installed in-line into the system and the samples were collected at the sampling port at the outlet of the furnace tube.
• samples were collected on the mercer cascade impactor. Most of the particles were observed on the last 2 stages of the impactor with very less mass ( ⁇ 2% of total mass) on the first five stages (>490 nm).
• the cut point of the sixth stage was 0.49 ⁇ m and the last stage (eighth stage) was 0.23 ⁇ m. Nearly 92% of the total mass was collected on the last 2 stages with the cut points of 0.33 ⁇ m and 0.23 ⁇ m respectively.
• the SMPS was used to determine the particle size distribution for smaller particle sizes.
• the vaporization condensation process was able to reliably and reproducibly generate a Ceo aerosol with a count median size of 36.6 nm.
• Table 3 summarizes the aerosol data for a 3 minute sampling period during the stable generation of aerosol, and Figure 6 shows the particle number based distribution during a 3 minute sample.
• SMPS analysis showed that more 99.7% of the total number of particles were less than 100 nm electrical mobility diameter.
• the TEM images of the samples were also taken.
• Figure 7 shows the TEM images of the filter samples at two different resolutions. Five images of the grid were taken at 25KX magnification to provide sufficient particles for size analysis. These images were analyzed using a Scion Image imaging and analysis program (Gaithersburg, MD).
• Figure 8 shows the Kaleidagraph histogram obtained using this information. The mean particle size was observed to be ⁇ 24.6 nm.
• the samples were also run through a MOUDI impactor to determine the mass size distribution.
• the MOUDI impactor has 13 stages with the cut points ranging from 10 ⁇ m to 10 nm.
• the rotation of the stages during sampling helped in uniform deposition of the test material on the filter.
• the MOUDI impactor and SMPS were placed at the same distance from the sampling port and both of these instruments sampled simultaneously for same duration of time. The results obtained were compared to each other and the results were in good agreement with previous reported literature.
• Figure 9 shows a MOUDI mass distribution obtained at -10 LPM for a sample period of 20 minutes. The cumulative percent mass was plotted against nominal cut diameter of each stage and the MMAD was observed to be ⁇ 25 nm.
• Figure 10 shows the Raman spectrum obtained for nano and micro sized C 6O aerosols.
• a spectrum for bulk C 6 o powder is also shown on the same plot.
• the sample number 010906-2 represents the nano sized Ceo spectrum while sample number 010906-5 represents the spectrum for micro sized Ceo particles.
• HPLC high performance liquid chromatography

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