TECHNICAL FIELD
The present invention relates to a dispersoid particle analyzing method and an analyzing apparatus for analyzing dispersoid particles (for example, a particulate) using volume susceptibilities (magnetic susceptibilities per unit volume) of the dispersoid particles.
BACKGROUND ART
The present inventors proposed a method for measuring a voidage of a dispersoid particle using a volume susceptibility of the dispersoid particle (Patent Literature 1). The present inventors also proposed a method for measuring a surface area of a dispersoid particle, the number of pores formed in the dispersoid particle, and respective average values of diameters, depths, and volumes of the pores using a volume susceptibility of the dispersoid particle (Patent Literature 2).
CITATION LIST
Patent Literature
- [Patent Literature 1] International Publication No. 2013/021910
- [Patent Literature 2] International Publication No. 2015/030184
SUMMARY OF INVENTION
Technical Problem
The inventors have accomplished the present invention through continuous diligent study on a method for analyzing a dispersoid particle. The present invention accordingly has its object of providing a dispersoid particle analyzing method and an analyzing apparatus for evaluating affinity of a dispersoid particle for a dispersion medium in a quantitative manner using a volume susceptibility of the dispersoid particle.
Solution to Problem
A first dispersoid particle analyzing method according to the present invention includes: obtaining volume susceptibilities of respective dispersoid particles dispersed in a dispersion medium by magnetophoresis; and analyzing affinity of the dispersoid particles for the dispersion medium using the volume susceptibilities of the respective dispersoid particles and a volume susceptibility of the dispersion medium.
In one embodiment, in the analyzing affinity, the affinity of the dispersoid particles for the dispersion medium is analyzed through comparison between the volume susceptibilities of the respective dispersoid particles and the volume susceptibility of the dispersion medium.
In one embodiment, in the analyzing affinity, the affinity of the dispersoid particles for the dispersion medium is analyzed using differences in volume susceptibility between the respective dispersoid particles and the dispersion medium.
A second dispersoid particle analyzing method according to the present invention includes: obtaining particle diameters of respective dispersoid particles dispersed in a dispersion medium; obtaining volume susceptibilities of the respective dispersoid particles in the dispersion medium by magnetophoresis; and analyzing affinity of the dispersoid particles for the dispersion medium based on the particle diameters, a distribution of the volume susceptibilities of the respective dispersoid particles, a width of the distribution, and a volume susceptibility of the dispersion medium.
In one embodiment, the analyzing affinity includes: obtaining a regression line indicating a relationship between the particle diameters and the distribution of the volume susceptibilities of the respective dispersoid particles. The affinity of the dispersoid particles for the dispersion medium is then analyzed based on the width of the distribution of the volume susceptibilities of the respective dispersoid particles around the regression line.
In one embodiment, in the analyzing affinity, the affinity of the dispersoid particles for the dispersion medium is analyzed based on a width of a distribution of the particle diameters of the respective dispersoid particles.
A first analyzing apparatus according to the present invention includes a magnetic field generating section, a measurement section, and an operation section. The measurement section measures movement of a dispersoid particle of dispersoid particles dispersed in a dispersion medium while the magnetic field generating section generates a magnetic field. The operation section obtains volume susceptibilities of the respective dispersoid particles based on a measurement result by the measurement section. The operation section generates image data indicating a distribution of the volume susceptibilities of the respective dispersoid particles.
In one embodiment, the operation section generates image data indicating differences in volume susceptibility between the respective dispersoid particles and the dispersion medium.
In one embodiment, the operation section obtains particle diameters of the respective dispersoid particles in the dispersion medium. Further, the operation section generates image data indicating a distribution of the volume susceptibilities of the respective dispersoid particles each plotted for a corresponding one of the particle diameters.
In one embodiment, the operation section obtains a regression line indicating a relationship between the particle diameters and the distribution of the volume susceptibilities of the respective dispersoid particles. Further, the operation section generates the image data that includes the regression line.
A second analyzing apparatus according to the present invention includes a magnetic field generating section, a measurement section, and an operation section. The measurement section measures movement of a dispersoid particle of dispersoid particles dispersed in a dispersion medium while the magnetic field generating section generates a magnetic field. The operation section obtains volume susceptibilities of the respective dispersoid particles based on a measurement result by the measurement section. The operation section analyzes affinity of the dispersoid particles for the dispersion medium through analysis of a distribution of the volume susceptibilities of the respective dispersoid particles.
In one embodiment, the operation section analyzes the affinity of the dispersoid particles for the dispersion medium through analysis of a distribution of differences in volume susceptibility between the respective dispersoid particles and the dispersion medium.
In one embodiment, the operation section obtains particle diameters of the respective dispersoid particles in the dispersion medium. Further, the operation section analyzes the distribution of the volume susceptibilities versus the particle diameters of the respective dispersoid particles.
In one embodiment, the operation section obtains an approximate function indicating a relationship between the particle diameters and the volume susceptibilities of the respective dispersoid particles. Further, the operation section analyzes the distribution of the volume susceptibilities versus the particle diameters of the respective dispersoid particles using the approximate function.
Advantageous Effects of Invention
According to the present invention, affinity of a dispersoid particle for a dispersion medium can be evaluated in a quantitative manner using a volume susceptibility of the dispersoid particle.
BRIEF DESCRIPTION OF DRAWINGS
FIG. 1 is a schematic diagram illustrating an analyzing apparatus according to an embodiment of the present invention.
FIG. 2 is a schematic diagram illustrating a measurement section according to the embodiment of the present invention.
FIG. 3 is a graph representation indicating first and second distributions of dispersoid volume susceptibilities according to the embodiment of the present invention.
FIG. 4 is a graph representation indicating third and fourth distributions of dispersoid volume susceptibilities according to the embodiment of the present invention.
FIG. 5 is a graph representation showing fifth and sixth distributions of dispersoid volume susceptibilities according to the embodiment of the present invention.
FIG. 6 is a graph representation indicating seventh and eighth distributions of dispersoid volume susceptibilities according to the embodiment of the present invention.
FIG. 7 is a graph representation indicating ninth and tenth distributions of dispersoid volume susceptibilities according to the embodiment of the present invention.
FIG. 8 is a graph representation indicating an eleventh distribution of dispersoid volume susceptibilities according to an embodiment of the present invention.
FIG. 9 is a graph representation indicating a twelfth distribution of dispersoid volume susceptibilities according to the embodiment of the present invention.
FIG. 10 is a graph representation indicating a thirteenth distribution of dispersoid volume susceptibilities according to the embodiment of the present invention.
FIG. 11 is a graph representation indicating a fourteenth distribution of dispersoid volume susceptibilities according to the embodiment of the present invention.
FIG. 12 is a graph representation indicating a fifteenth distribution of dispersoid volume susceptibilities according to the embodiment of the present invention.
FIG. 13 is a graph representation indicating a sixteenth distribution of dispersoid volume susceptibilities according to the embodiment of the present invention.
FIG. 14 is a graph representation indicating a seventeenth distribution of dispersoid volume susceptibilities according to the embodiment of the present invention.
FIG. 15 is a graph representation indicating an eighteenth distribution of dispersoid volume susceptibilities according to the embodiment of the present invention.
DESCRIPTION OF EMBODIMENTS
The following describes embodiments of the present invention with reference to the accompanying drawings. Like numerals denote like elements or corresponding elements in the drawings, and description thereof is not repeated. Furthermore, the present invention is not limited to the embodiments described below and various alterations can be made within the scope not departing from the essence of the present invention.
First Embodiment
A dispersoid particle analyzing method according to the first embodiment includes a process of obtaining volume susceptibilities χs of dispersoid particles s (also referred to below as dispersoid volume susceptibilities χs) dispersed in a dispersion medium m by magnetophoresis. The dispersoid particle analyzing method according to the first embodiment further includes a process of analyzing affinity of the dispersoid particles s for the dispersion medium m using the dispersoid volume susceptibilities χs and a volume susceptibility χm of the dispersion medium m (also referred to below as dispersion medium volume susceptibility χm). In the process of analyzing the affinity of the dispersoid particles s for the dispersion medium m in the first embodiment, the affinity of the dispersoid particles s for the dispersion medium m is analyzed through comparison or using a difference between the dispersoid volume susceptibility χs and the dispersion medium volume susceptibility χm.
The dispersion medium m is water, for example. Alternatively, the dispersion medium m may be selected from methanol, ethanol, 1-propanol, acetonitrile, acetone, and the like. Alternatively, the dispersion medium m may be a mixture of two or more of water, methanol, ethanol, 1-propanol, acetonitrile, acetone, and the like. The dispersoid particles s are porous silica gel particles or cellulose, for example. Alternatively, the dispersoid particles s may be made of a resin such as polyethylene or polystyrene. Or, the dispersoid particles s may be silica particles to be used as spacers in a liquid crystal panel. Alternatively, the dispersoid particles s may be organic-inorganic hybrid particles in which organic matter and inorganic matter are present, such as an ink or a toner. Or, the dispersoid particles s may be made of an electrode material such as carbon or tungsten oxide. Alternatively, the dispersoid particles s may be made of a food material such as whipped cream, starch, or sucrose. Or, the dispersoid particles s may be droplets of hexane, benzene, toluene, olive oil, or the like.
Description will be made below with reference to FIGS. 1 and 2 about a method for obtaining a dispersoid volume susceptibility χs by magnetophoresis. FIG. 1 is a schematic diagram illustrating an analyzing apparatus 10 according to the present embodiment. The analyzing apparatus 10 is used in the dispersoid particle analyzing method according to the present embodiment.
The analyzing apparatus 10 incudes a magnetic field generating section 20, a measurement section 30, and an operation section 40. A disperse system D that is the dispersion medium m in which the dispersoid particles s are dispersed is disposed in the vicinity of the magnetic field generating section 20. The disperse system D is put into a tubular member, for example. Specifically, a capillary C into which the disperse system D is put is disposed in the vicinity of the magnetic field generating section 20. The capillary C is made of glass, for example. Furthermore, the capillary C may have a substantially square shape that measures about 100 μm square in section perpendicular to an axial direction thereof. The dispersoid particles s in a state of being dispersed in the dispersion medium m are introduced into the capillary C by the capillary action or a pump. However, the capillary C is not limited to a glass-made capillary having a square section. The capillary C may have any shape as long as magnetic migration of the dispersoid particles s in the capillary C is observable. The capillary C may be made of any material as long as magnetic migration of the dispersoid particles s in the capillary C is observable.
The magnetic field generating section 20 includes a superconducting magnet, a magnetic circuit, a permanent magnet, or the like. For example, the magnetic field generating section 20 preferably generates a strong magnetic field having a large magnetic field gradient using pole pieces. Note that although a single dispersoid particle s is illustrated in FIG. 1, a plurality of dispersoid particles s may be present in the dispersion medium m.
Once the magnetic field generating section 20 generates a magnetic field in the disperse system D, the dispersoid particles s perform magnetic migration in the dispersion medium m. The measurement section 30 measures movement (magnetic migration) of a dispersoid particle s in the dispersion medium m (disperse system D) while the magnetic field generating section 20 generates the magnetic field.
The operation section 40 is a personal computer, for example. The operation section 40 obtains a magnetic migration speed v of the dispersoid particle s from a measurement result by the measurement section 30. For example, the operation section 40 may obtain the magnetic migration speed v from time-varying positional change of the dispersoid particle s measured by the measurement section 30. Specifically, it is possible that the measurement section 30 images the dispersoid particle s at predetermined time intervals and the operation section 40 obtains the magnetic migration speed v from results of the imaging.
The operation section 40 obtains a dispersoid volume susceptibility χs from the magnetic migration speed v. Specifically, the operation section 40 calculates the dispersoid volume susceptibility χs by referencing the following equation (1).
v=2(χs−χm)r2( 1/9ημ0)B(dB/dx) (1)
In equation (1): r represents a radius of the dispersoid particle s; η represents a viscosity coefficient of the dispersion medium m: to represents a vacuum magnetic permeability; and B(dB/dx) represents a magnetic field gradient.
A literature value can be used as the radius r of the dispersoid particle s. Alternatively, the radius r of the dispersoid particle s may be obtained through measurement. For example, the radius r of the dispersoid particle s can be measured from an image of the dispersoid particle s imaged by the measurement section 30. The viscosity coefficient η of the dispersion medium m and the vacuum magnetic permeability μo each are a constant, and a literature value can be used as the dispersion medium volume susceptibility χm. Alternatively, the dispersion medium volume susceptibility χm may be measured using a superconducting quantum interference device (SQUID) element or a magnetic balance. The magnetic field gradient B(dB/dx) is an apparatus constant and measurable.
Description will be made next about configuration of the measurement section 30 with reference to FIG. 2. FIG. 2 is a schematic diagram illustrating the configuration of the measurement section 30. As illustrated in FIG. 2, the measurement section 30 includes a zooming section 32 and an imaging section 34. The dispersoid particles s introduced into the capillary C are zoomed up to an appropriate magnification by the zooming section 32 and imaged by the imaging section 34. For example, the zooming section 32 includes an objective lens and the imaging section 34 includes a charge coupled device (CCD). Note that provision of the imaging section 34 in the measurement section 30 enables measurement of not only the position but also the particle diameter of the dispersoid particle s. In a configuration in which the radius r of the dispersoid particle s is measured using the measurement section 30, the analyzing apparatus 10 preferably includes a light source 50 that irradiates the capillary C. The light source 50 is not particularly limited and may be a laser light source, for example. Use of a laser light source as the light source 50 can enable analysis of a magnetic migration speed v of the dispersoid particle s by the Laser Doppler method. In a configuration in which the magnetic migration speed v is analyzed by the Laser Doppler method, the imaging section 34 includes a photo multiplier tube. Furthermore, use of a laser light source as the light source 50 can enable analysis of the particle diameter of the dispersoid particle s by a dynamic light scattering method. In a configuration in which the particle size of the dispersoid particle s is analyzed by the dynamic light scattering method, the imaging section 34 includes a photo multiplier tube.
Description will be made next with reference to FIGS. 3-5 about a method for analyzing affinity of the dispersoid particles s for the dispersion medium m through comparison between the dispersoid volume susceptibility χs and the dispersion medium volume susceptibility χm.
FIG. 3 is a graph representation indicating a first distribution (broken line) and a second distribution (solid line) of dispersoid volume susceptibilities χs. Specifically, the first distribution (broken line) of the dispersoid volume susceptibilities χs is obtained in a situation in which octadecyl group bonded silica gel (ODS) particles that are dispersoid particles s are dispersed in acetone that is a dispersion medium m. By contrast, the second distribution (solid line) of the dispersoid volume susceptibilities χs is obtained in a situation in which octadecyl group bonded silica gel (ODS) particles subjected to end capping (dispersoid particles s) are dispersed in acetone (a dispersion medium m).
In FIG. 3, the horizontal axis represents the dispersoid volume susceptibility χs and the vertical axis represents a rate of the number of particles. The operation section 40 described with reference to FIG. 1 generates image data of the graphs indicated in FIG. 3 through obtaining information on the volume susceptibilities χs of the respective particles as the dispersoid particles s in the disperse system D (dispersion medium m). The image based on the image data generated by the operation section 40 is output through an output device such as a display or a printer.
The ODS particles are produced by causing a silanol group present on the surfaces of porous silica gel particles to react with an octadecylsilane compound. The silanol group includes a hydroxyl group (OH), and reaction of the silanol group with the octadecylsilane compound makes the porous silica gel particles hydrophobic. However, not all part of the silanol group on the surfaces of the porous silica gel particles can react with the octadecylsilane compound. For the reason as above, end capping is performed in a situation in which it is necessary to make the porous silica gel particles more hydrophobic. The end capping is a treatment by which a silane compound such as trimethyl monochlorosilane is caused to react with a remaining part of the silanol group. Note that it is difficult to thoroughly remove the remaining part of the silanol group even by end capping.
As indicated in FIG. 3, comparison of the first distribution (broken line) and the second distribution (solid line) of the dispersoid volume susceptibilities χs with the volume susceptibility χm of acetone (−5.77×10−6) can find that the second distribution (solid line) is closer to the volume susceptibility χm of acetone than the first distribution (broken line). That is, the volume susceptibilities χs (sloid line) of the ODS particles subjected to end capping is closer to the volume susceptibility χm of acetone than the volume susceptibilities χs (broken line) of the ODS particles not subjected to end capping. In other words, when the ODS particles are subjected to end capping to be more hydrophobic, the dispersoid volume susceptibilities χs thereof become close to the volume susceptibility χm of acetone. This indicates that end capping increases the affinity of the ODS particles (dispersoid particles s) for acetone (dispersion medium m).
That is, the dispersoid volume susceptibility χs being close to the dispersion medium volume susceptibility χm indicates that a large amount of the dispersion medium m is adsorbed to the surfaces of the dispersoid particles s. A large amount of the dispersion medium m being adsorbed to the surfaces of the dispersoid particles s indicates strong affinity of the dispersoid particles s for the dispersion medium m.
Note that the dispersoid volume susceptibility χs is close to the dispersion medium volume susceptibility χm as the amount of the dispersion medium m adsorbed to the surfaces of the dispersoid particles s is increased since the additivity property is true for the volume susceptibility. For example, the volume susceptibility χs of a porous material (dispersoid particle s) having a surface that is modified with modifying molecules, such as an ODS particle is represented by the following equation (2).
χs=χB(VB/Vs)+χM(VM/Vs)+χm(Vm/Vs) (2)
In equation (2): Vs represents a volume of the dispersoid particle s; VB represents a volume of a skeletal portion of the dispersoid particle s; VM represents a volume occupied by modifying molecules that modify the surface of the dispersoid particle s; and Vm represents a volume occupied by the dispersion medium m adsorbed to the dispersoid particle s. Furthermore, χB represents a volume susceptibility of the skeletal portion of the dispersoid particle s; χM represents a volume susceptibility of the modifying molecules that modify the surface of the dispersoid particle s; and χm represents a volume susceptibility of the dispersion medium m adsorbed to the dispersoid particle s.
As is clear from equation (2), the volume susceptibility χs of the dispersoid particle s is close to the volume susceptibility χm of the dispersion medium m as the ratio of the volume Vm of the dispersion medium m that occupies the volume Vs of the dispersoid particle s is increased, in other words, as the amount of the dispersion medium m adsorbed to the dispersoid particle s is increased.
As such, it can be evaluated that the ODS particles subjected to end capping display stronger affinity for the dispersion medium m than the ODS particles not subjected to end capping in a situation in which the dispersion medium m is acetone.
Note that the operation section 40 may analyze the affinity of the dispersoid particles s for the dispersion medium m through analysis of the distribution of the volume susceptibilities of the respective dispersoid particles s. For example, the operation section 40 may obtain a value (parameter) indicating the affinity of the dispersoid particles s for the dispersion medium m by calculation (numerical analysis) based on the volume susceptibilities χs of the respective dispersoid particles s in the disperse system D (dispersion medium m) and the volume susceptibility χm of the dispersion medium m.
FIG. 4 is a graph representation (histogram) indicating third and fourth distributions of dispersoid volume susceptibilities χs. Specifically, the third distribution of the dispersoid volume susceptibilities χs is obtained in a situation in which ODS particles are dispersed in acetone. By contrast, the fourth distribution of the dispersoid volume susceptibilities χs is obtained in a situation in which ODS particles are dispersed in a solution of acetone with which 0.1% by mass of a surfactant TritonX-100 is mixed. In the third distribution, the dispersion medium m is acetone and the dispersoid particles s are the ODS particles. When the ODS particles are dispersed in the acetone with which the surfactant TritonX-100 is mixed, the surfactant TritonX-100 is adsorbed to the surfaces of the ODS particles. Accordingly, in the fourth distribution, the dispersion medium m is acetone and the dispersoid particles s are the ODS particles each having a surface to which the surfactant TritonX-100 is adsorbed.
In FIG. 4, the horizontal axis represents the dispersoid volume susceptibility χs and the vertical axis represents the number of particles. The operation section 40 described with reference to FIG. 1 generates image data of the graphs indicated in FIG. 4 through obtaining information on the volume susceptibilities χs of the respective particles as the dispersoid particles s in the disperse system D (dispersion medium m). The image based on the image data generated by the operation section 40 is output through an output device such as a display or a printer.
As indicated in FIG. 4, comparison of the third and fourth distributions of the dispersoid volume susceptibilities χs with the volume susceptibility χm of acetone (−5.77×10−6) can find that the fourth distribution is closer to the volume susceptibility χm of acetone than the third distribution. That is, the volume susceptibilities χs of the respective ODS particles each having a surface to which the surfactant TritonX-100 is adsorbed are closer to the volume susceptibility χm of acetone than the volume susceptibilities χs of the respective ODS particles. In other words, adsorption of the surfactant TritonX-100 to the surfaces of the ODS particles makes the dispersoid volume susceptibility χs close to the dispersion medium volume susceptibility χm. This indicates that adsorption of the surfactant TritonX-100 to the surfaces of the ODS particles (dispersoid particles s) increases the affinity of the ODS particles (dispersoid particles s) for acetone (dispersion medium m).
As such, it can be evaluated that the ODS particles each having a surface to which the surfactant TritonX-100 is adsorbed display stronger affinity for the dispersion medium m than the ODS particles each having a surface to which the surfactant TritonX-100 is not adsorbed in a situation in which the dispersion medium m is acetone.
FIG. 5 is a graph representation (scatter diagram) indicating fifth and sixth distributions of dispersoid volume susceptibilities χs. Specifically, FIG. 5 indicates two distributions of dispersoid volume susceptibilities χs each plotted for corresponding one of particle diameters. In FIG. 5, the horizontal axis represents the particle diameter and the vertical axis represents the dispersoid volume susceptibility χs. The operation section 40 described with reference to FIG. 1 generates image data of the graphs indicated in FIG. 5 through obtaining information on the volume susceptibilities χs of the respective dispersoid particles s and information on the particle diameters of the respective dispersoid particles s in the disperse system D (dispersion medium m). That is, the operation section 40 generates image data indicating a distribution of the volume susceptibilities χs of the dispersoid particles s each plotted for corresponding one of particle diameters. The image based on the image data generated by the operation section 40 is output through an output device such as a display or a printer.
Specifically, the fifth distribution of the dispersoid volume susceptibilities χs indicates a relationship between dispersoid volume susceptibilities χs and particle diameters of particles obtained through dispersion of an anticonvulsant, carbamazepine I (dispersoid particles s) in water (dispersion medium m). By contrast, the sixth distribution of the dispersoid volume susceptibilities χs indicates a relationship between dispersoid volume susceptibilities χs and particle diameters of particles obtained through dispersion of an anticonvulsant, carbamazepine IV (dispersoid particles s) in water (dispersion medium m).
As indicated in FIG. 5, comparison between the volume susceptibilities χs of the fifth distribution (I) and the volume susceptibilities χs of the sixth distribution (IV) with the volume susceptibility χm (−9.01×10−6) of water can find that the volume susceptibilities χs of the sixth distribution (IV) are closer to the volume susceptibility χm of water than those of the fifth distribution (I). That is, the volume susceptibility χs of the anticonvulsant, carbamazepine IV is closer to the volume susceptibility χm of water than that χs of the anticonvulsant, carbamazepine I. As such, it can be evaluated that the anticonvulsant, carbamazepine IV has stronger affinity for water than the anticonvulsant, carbamazepine I.
Description will be made next with reference to FIGS. 6 and 7 about a method for analyzing affinity of the dispersoid particles s for the dispersion medium m using a difference between the dispersoid volume susceptibility χs and the dispersion medium volume susceptibility χm.
FIG. 6 is a graph representation (histogram) indicating seventh and eighth distributions of dispersoid volume susceptibilities χs. Specifically, FIG. 6 indicates two distributions of differences between the dispersion medium volume susceptibility χm and the dispersoid volume susceptibility χs (also referred to below as volume susceptibility differences). In FIG. 6, the horizontal axis represents the volume susceptibility difference and the vertical axis represents a rate of the number of particles. The operation section 40 described with reference to FIG. 1 generates image data of the graphs indicated in FIG. 6 through obtaining information on the volume susceptibility χm of the dispersion medium m and information on the volume susceptibilities χs of the respective dispersoid particles s in the disperse system D (dispersion medium m). That is, the operation section 40 generates image data indicating a volume susceptibility difference. The image based on the image data generated by the operation section 40 is output through an output device such as a display or a printer.
Specifically, FIG. 6 indicates a distribution (seventh distribution) of differences between the volume susceptibility χm (−6.65×10−6) of methanol that is a dispersion medium m and dispersoid volume susceptibilities χs of porous silica gel particles that are dispersoid particles s dispersed in the methanol (the dispersion medium m). FIG. 6 also indicates a distribution (eighth distribution) of differences between the volume susceptibility χm of acetone that is a dispersion medium m and dispersoid volume susceptibilities χs of porous silica gel particles that are dispersoid particles s dispersed in the acetone (dispersion medium m).
As indicated in FIG. 6, the volume susceptibility differences are closer to zero in a situation in which the porous silica gel particles are dispersed in methanol (seventh distribution) than in a situation in which the porous silica gel particles are dispersed in acetone (eighth distribution). This indicates that the volume susceptibilities χs of the porous silica gel particles are closer to the volume susceptibility χm of methanol than to the volume susceptibility χm of acetone. It can be evaluated accordingly that the porous silica gel particles have stronger affinity for methanol than for acetone.
Note that the operation section 40 may obtain differences between the volume susceptibility χm of the dispersion medium m and the volume susceptibilities χs of the respective dispersoid particles s in the disperse system D (dispersion medium m), analyze a distribution of the obtained differences (distribution of volume susceptibility differences), and obtain a value (parameter) indicating affinity of the dispersoid particles s for the dispersion medium m by calculation (numerical analysis).
FIG. 7 is a graph representation (histogram) indicating ninth and tenth distributions of dispersoid volume susceptibilities χs. Specifically, FIG. 7 indicates two distributions of volume susceptibility differences. In FIG. 7, the horizontal axis represents volume susceptibility difference and the vertical axis represents a rate of the number of particles. The operation section 40 described with reference to FIG. 1 generates image data of the graphs indicated in FIG. 7 through obtaining information on the volume susceptibilities χs of the respective dispersoid particles s in the disperse system D (dispersion medium m) and information on the volume susceptibility χm of the dispersion medium m. That is, the operation section 40 generates image data indicating a volume susceptibility difference. The image based on the image data generated by the operation section 40 is output through an output device such as a display or a printer.
Specifically, FIG. 7 indicates a distribution (ninth distribution) of differences between the volume susceptibility χm of methanol that is a dispersion medium m and dispersoid volume susceptibilities χs of respective porous silica gel particles that are dispersoid particles s dispersed in the methanol. FIG. 7 also indicates a distribution (tenth distribution) of differences between the volume susceptibility χm (−7.48×10−6) of 1-propanol that is a dispersion medium m and dispersoid volume susceptibilities χs of respective porous silica gel particles that are dispersoid particles s dispersed in the 1-propanol.
As indicated in FIG. 7, difference is small between the distribution (ninth distribution) of the volume susceptibility differences obtained in a situation in which the porous silica gel particles are dispersed in methanol and the distribution (tenth distribution) of the volume susceptibility differences obtained in a situation in which the porous silica gel particles are dispersed in 1-propanol. This indicates that difference in affinity of the porous silica gel particles is small between for methanol and for 1-propanole.
As described above, the affinity of the dispersoid particles s for the dispersion medium m can be evaluated in a quantitative manner using the volume susceptibility χm of the dispersion medium m and the volume susceptibilities χs of the dispersoid particles s in the dispersion medium m in the first embodiment. The stronger the affinity of the dispersoid particles s for the dispersion medium m is, the higher the dispersibility of the dispersoid particles s in the dispersion medium m is. As such, the first embodiment can enable quantitative evaluation of the dispersibility of the dispersoid particles s.
Second Embodiment
Description will be made next about a dispersoid particle analyzing method according to a second embodiment with reference to FIGS. 8-15. The focus will be placed on matter different from the first embodiment, and some explanations overlapping with those explained in the first embodiment may be appropriately omitted. The dispersoid particle analyzing method according to the second embodiment is different from that according to the first embodiment in the process of analyzing affinity of dispersoid particles s for a dispersion medium m. Specifically, the dispersoid particle analyzing method according to the second embodiment includes a process of obtaining particle diameters of respective dispersoid particles s in the dispersion medium m. The dispersoid particle analyzing method according to the second embodiment further includes a process of obtaining volume susceptibilities χs of the respective dispersoid particles s in the dispersion medium m by magnetophoresis. The dispersoid particle analyzing method according to the second embodiment still includes a process of analyzing affinity of the dispersoid particles s for the dispersion medium m based on the particle diameters, a distribution of the volume susceptibilities χs of the respective dispersoid particles s, a width of the distribution, and the volume susceptibility χm of the dispersion medium m. In the process of analyzing affinity of the dispersoid particles s for the dispersion medium m in the second embodiment, a regression line is obtained that indicates a relationship between the particle diameters and the distribution of the volume susceptibilities χs of the respective dispersoid particles s. The affinity of the dispersoid particles s for the dispersion medium m is then analyzed based on the width of the distribution of the volume susceptibilities χs of the respective dispersoid particles s around the regression line. Alternatively, in the process of analyzing affinity of the dispersoid particles s for the dispersion medium m, the affinity of the dispersoid particles s for the dispersion medium m is analyzed based on a width of a distribution of the particle diameters of the dispersoid particles s.
FIGS. 8-11 are graph representations (scatter diagrams) indicating eleventh to fourteenth distributions of dispersoid volume susceptibilities χs, respectively. Specifically, FIGS. 8-11 each indicate a distribution of dispersoid volume susceptibilities χs each plotted for corresponding one of particle diameters. In FIGS. 8-11, the horizontal axis represents the particle diameter and the vertical axis represents the dispersoid volume susceptibility χs. FIGS. 8-11 each indicate a regression line and an equation (approximate function) thereof. The approximate function (equation expressing the regression line) can be obtained by the least squares method, for example. The operation section 40 described with reference to FIG. 1 generates image data of the graphs and the regression lines indicated in FIGS. 8-11 through obtaining information on the volume susceptibilities χs of the respective dispersoid particles s and information on the particle diameters of the respective dispersoid particles s in the disperse system D (dispersion medium m). That is, the operation section 40 obtains an approximate function (regression line) indicating the relationship between the particle diameters and the distribution of the volume susceptibilities χs of the respective dispersoid particles s by calculation. Furthermore, the operation section 40 generates image data indicating a regression line and a distribution of the volume susceptibilities χs of the respective dispersoid particles s each plotted for corresponding one of particle diameters. The image based on the image data generated by the operation section 40 is output through an output device such as a display or a printer.
Specifically, FIGS. 8-11 each indicate a relationship between particle diameters of porous silica gel particles that are dispersoid particles s and volume susceptibilities χs of the porous silica gel particles s in a situation in which the porous silica gel particles are dispersed in a corresponding one of dispersion mediums m. That is, FIG. 8 indicates a relationship (eleventh distribution) between the particle diameters of the respective porous silica gel particles and the dispersoid volume susceptibilities χs in a situation in which the porous silica gel particles are dispersed in methanol (dispersion medium m). FIG. 9 indicates a relationship (twelfth distribution) between the particle diameters of the respective porous silica gel particles and the dispersoid volume susceptibilities χs in a situation in which the porous silica gel particles are dispersed in ethanol (dispersion medium m). FIG. 10 indicates a relationship (thirteenth distribution) between particle diameters of the respective porous silica gel particles and the dispersoid volume susceptibilities χs in a situation in which the porous silica gel particles are dispersed in acetonitrile (dispersion medium m). FIG. 11 indicates a relationship (fourteenth distribution) between particle diameters of the respective porous silica gel particles and the dispersoid volume susceptibilities χs in a situation in which the porous silica gel particles are dispersed in acetone (dispersion medium m).
As indicated in FIGS. 8-11, the larger the particle diameter is, the closer the dispersoid volume susceptibility χs is to the dispersion medium volume susceptibility χm in a situation in which the dispersoid particles s are porous particles. The reason thereof is that a total volume of pores formed in the dispersoid particle s increases as the particle diameter is increased. As such, an increase in total volume of the pores increases the amount of dispersion medium m adsorbed to the dispersoid particle s. Note that the volume susceptibility χm of methanol is −6.65×10−6; the volume susceptibility χm of ethanol is −7.11×10−6; the volume susceptibility χm of acetonitrile is −6.74×10−6; and the volume susceptibility χm of acetone is −5.77×10−6.
By contrast, the width of the distribution of the dispersoid volume susceptibilities χs around the regression line differed due to difference in dispersion medium m. Specifically, the width (dispersion) of the distribution of the dispersoid volume susceptibilities χs around the regression line is larger in a situation in which the dispersion medium m is acetone than in a situation in which the dispersion medium m is methanol, ethanol, or acetonitrile. This indicates that acetone is more hardly adsorbed to the surfaces of the porous silica gel particles than methanol, ethanol, and acetonitrile. In other words, the respective affinities of the porous silica gel particles for methanol, ethanol, and acetonitrile are stronger than that for acetone. That is, it indicates that the porous silica gel particles tend to be dispersed more in methanol, ethanol, and acetonitrile than in acetone.
FIG. 12 is a graph representation (scatter diagram) indicating a fifteenth distribution of dispersoid volume susceptibilities χs. Specifically, FIG. 12 indicates a distribution of dispersoid volume susceptibilities χs each plotted for corresponding one of particle diameters. In FIG. 12, the horizontal axis represents the particle diameter and the vertical axis represents the dispersoid volume susceptibility χs. Furthermore, FIG. 12 indicates a regression line and an equation thereof (approximate function). The approximate function (equation expressing the regression line) can be obtained by the least squares method, for example. The operation section 40 described with reference to FIG. 1 generates image data of the graph and the regression line indicated in FIG. 12 through obtaining information on the volume susceptibilities χs of respective dispersoid particles s and information on the particle diameters of thereof in the disperse system D (dispersion medium m). The image based on the image data generated by the operation section 40 is output through an output device such as a display or a printer.
Specifically, the fifteenth distribution of the dispersoid volume susceptibilities χs indicates a relationship between the dispersoid volume susceptibilities χs and the particle diameters of respective porous silica gel particles in a situation in which the porous silica gel particles are dispersed in a solution of acetone with which 0.1% by mass of a surfactant TritonX-100 is mixed. As indicated in FIGS. 11 and 12, mixing the surfactant TritonX-100 with acetone reduces the width of the distribution of the dispersoid volume susceptibilities χs around the regression line. This indicates that the surfactant TritonX-100 is adsorbed to the surfaces of the porous silica gel particles to increase the affinity of the porous silica gel particles for acetone.
FIG. 13 is a graph representation (scatter diagram) indicating a sixteenth distribution of the dispersoid volume susceptibilities χs. Specifically, FIG. 13 indicates a distribution of the dispersoid volume susceptibilities χs each plotted for corresponding one of particle diameters. In FIG. 13, the horizontal axis represents the particle diameter and the vertical axis represents the dispersoid volume susceptibility χs. FIG. 13 further indicates a regression line and an equation (approximate function) thereof. The approximate function (equation expressing the regression line) can be obtained by the least squares method, for example. The operation section 40 described with reference to FIG. 1 generates image data of the graph and the regression line indicated in FIG. 13 through obtaining information on the dispersoid volume susceptibilities χs and information on the particle diameters of the respective dispersoid particles s in the disperse system D (dispersion medium m). The image based on the image data generated by the operation section 40 is output through an output device such as a display or a printer.
Specifically, the sixteenth distribution of the dispersoid volume susceptibilities χs indicates a relationship between the dispersoid volume susceptibilities χs and particle diameters of ODS particles (dispersoid particles s) obtained through dispersion of the ODS particles in acetone (a dispersion medium m). As indicated in FIGS. 11 and 13, the distribution of the volume susceptibilities χs of the ODS particles that are hydrophobized porous silica gel particles is narrower than that of the porous silica gel particles even in a situation in which the dispersion medium m is the same, acetone. This indicates that hydrophobization of the surfaces of the porous silica gel particles increases the affinity of the porous silica gel particles for acetone.
FIGS. 14 and 15 are graph representations (scatter diagrams) of seventeenth and eighteenth distributions of dispersoid volume susceptibilities χs, respectively. Specifically, FIGS. 14 and 15 indicate two distributions of dispersoid volume susceptibilities χs each plotted for corresponding one of particle diameters. In FIGS. 14 and 15, the horizontal axis represents the particle diameter and the vertical axis represents the dispersoid volume susceptibility χs. Furthermore, FIGS. 14 and 15 each indicate a regression line and an equation (approximate function) thereof. The approximate function (equation expressing the regression line) can be obtained by the least squares method, for example. The operation section 40 described with reference to FIG. 1 generates image data of the graphs and the regression lines indicated in FIGS. 14 and 15 through obtaining information on the volume susceptibilities χs of respective dispersoid particles s and information on the particle diameters thereof in the disperse system D (dispersion medium m). The image based on the image data generated by the operation section 40 is output through an output device such as a display or a printer.
Specifically, the seventeenth distribution of the dispersoid volume susceptibilities χs indicates a relationship between the dispersoid volume susceptibilities χs and particle diameters of polyethylene particles (dispersoid particles s) obtained through dispersion of the polyethylene particles in methanol (a dispersion medium m). By contrast, the eighteenth distribution of the dispersoid volume susceptibilities χs indicates a relationship between the dispersoid volume susceptibilities χs and particle diameters of polyethylene particles (dispersoid particles s) obtained through dispersion of the polyethylene particles in acetone (a dispersion medium m).
As indicated in FIGS. 14 and 15, the larger the particle diameter of the polyethylene particle, which is porous, is, the closer the dispersoid volume susceptibility χs is to the dispersion medium volume susceptibility χm. By contrast, the width of the distribution of the particle diameters differed due to difference in dispersion medium m. Specifically, the distribution of the particle diameters is wider when the polyethylene particles are dispersed in acetone than when the polyethylene particles are dispersed in methanol. The reason thereof is that the polyethylene particles are swelled in the acetone. As such, the measurement results indicated in FIGS. 14 and 15 indicate that acetone tends to enter inside the polyethylene particle when compared with methanol. That is, the measurement results indicate that the affinity of the polyethylene particles for acetone is stronger than that for methanol.
Note that the operation section 40 may analyze the affinity of the dispersoid particles s for the dispersion medium m through analysis of the distribution of the volume susceptibilities χs versus the particle diameters of the respective dispersoid particles s. For example, the operation section 40 may analyze the distribution of the volume susceptibilities χs versus the particle diameters of the respective dispersoid particles s using the approximate function (equation expressing the regression line) and obtain a value (parameter) indicating the affinity of the dispersoid particles s for the dispersion medium m by calculation (numeric analysis). More specifically, for example, the operation section 40 may perform numeric analysis of the width of the distribution of the dispersoid volume susceptibilities χs around the regression line and obtain a value (parameter) indicating the affinity of the dispersoid particles s for the dispersion medium m. Alternatively, for example, the operation section 40 may perform numeric analysis of the width of the distribution of the particle diameters of the respective dispersoid particles s and obtain a value (parameter) indicating the affinity of the dispersoid particles s for the dispersion medium m.
As described above, the affinity of the dispersoid particles s for the dispersion medium m can be evaluated in a quantitative manner using the volume susceptibility χm of the dispersion medium m and the volume susceptibilities χs of the dispersoid particles s in the dispersion medium m likewise in the first embodiment. Furthermore, quantitative evaluation of dispersibility of the dispersoid particles s can be enabled likewise in the first embodiment.
INDUSTRIAL APPLICABILITY
The present invention is applicable to analysis of for example a particle, a crystal, and a droplet.
REFERENCE SIGNS LIST
10 analyzing apparatus
20 magnetic field generating section
30 measurement section
40 operation section
50 light source
- m dispersion medium
- s dispersoid particle
- C capillary
- D disperse system