AU2007203132B2

AU2007203132B2 - Production and use of polysilicate particulate materials

Info

Publication number: AU2007203132B2
Application number: AU2007203132A
Authority: AU
Inventors: Francois Batlo; Brian T. Holland; John M. Krasniewski; Kim M. Long; Michael A. Romba; Sascha Welz; David P. Workman
Original assignee: Nalco Co LLC
Current assignee: ChampionX LLC
Priority date: 2007-07-05
Filing date: 2007-07-05
Publication date: 2013-05-02
Anticipated expiration: 2027-07-05
Also published as: AU2007203132A1

Abstract

A method of preparing a particulate material comprising the steps of adding silicic acid solution, optionally doped with aluminum, optionally added to a slurry of pre-existing nanoparticles at a neutral to slightly acidic pH1 of no more than seven, and at 5 a temperature of about 200 to 30*C. This yields a polysilicate particulate dispersion. Then, the pH of the dispersion is raised to greater than seven, to stabilize/reinforce particles of the particulate dispersion. Optionally, the particles may be dried, and have increased porosity and surface area.

Description

AUSTRALIA PATENTS ACT 1990 COMPLETE SPECIFICATION FOR A STANDARD PATENT ORIGINAL Name of Applicant/s: Nalco Company Actual Inventor/s: Francois Batilo and Brian T. Holland and John M. Krasniewski and Kim M. Long and Michael A. Romba and Sascha Welz and David P. Workman Address for Service is: SHELSTON IP 60 Margaret Street Telephone No: (02) 9777 1111 SYDNEY NSW 2000 Facsimile No. (02) 9241 4666 CCN: 3710000352 Attorney Code: SW Invention Title: PRODUCTION AND USE OF POLYSILICATE PARTICULATE MATERIALS The following statement Is a full description of this invention, including the best method of performing it known to me/us: File: 54815AUPOO 501 flZSt.DCCJO44 -2 PRODUCTION AND USE OF POLYSILICATE PARTICULATE MATERIALS BACKGROUND OF THE INVENTION Any discussion of the prior art throughout the specification should in no way be considered as an admission that such prior art is widely known or forms part of common 5 general knowledge in the field. Finely divided silica is used as a catalyst support, as a binder, or as a catalyst itself, especially when "doped" with aluminum or another metal, as an ink-receptive coating on paper or the like, as a filter material for wine or juice clarification, or the like. However, improvements could be obtained if the agglomerated silicate particles could io have a greater porosity than can be obtained using standard colloidal silica. Also, when colloidal silica or other silicates are modified by the incorporation of aluminum into the silicate framework, known benefits are achieved such as increased acidity, but such materials have a strong tendency to form a gel, which is disadvantageous. If a physically stable, silica-alumina (alumino-silicate) material could be 15 provided, improvements can be obtained in a number of markets including catalysts, refractories, separation materials such as filters, abrasives, and coatings. The present materials used are not as homogeneous or amorphous as might be desired. By this invention, a high surface area, high porosity, particulate material is provided, having promising characteristics for uses as described above, and exhibiting 20 improved physical stability. Specifically, the finely dispersed alumino-silicate materials of this invention can have high natural acidity coupled with good physical stability to avoid gelling, providing particular promise for use as a catalyst per se, or as a catalyst support upon which a metal or metal oxide catalyst may be placed, for example, platinum, palladium, nickel, copper oxide, or other materials.

-3 DESCRIPTION OF THE INVENTION According to a first aspect the present invention provides a method of preparing a particulate material comprising the steps of: mixing aluminum-doped silicic acid solution, with preexisting nanoparticles 5 having a pH of no more than essentially 7, at a temperature of about 20' to 130* C, to produce polyaluminosilicate linkages to form between the preexisting nanoparticles, yielding a particulate dispersion; and raising the pH of the dispersion to greater than 7 to stabilize/reinforce particles of the particulate dispersion. 10 According to a second aspect the present invention provides a method of preparing a particulate material comprising the steps of: adding a silicic acid solution, with mixing, to a slurry of pre-existing nanoparticles having a neutral to slightly acidic pH, at a temperature of about 20" to 130*C, to produce polysilicate linkages to form between the pre-existing nanoparticles, 15 yielding a dispersion having a solids content of at least about 5% SiO 2 by weight; and adjusting the pH of the dispersion to achieve a pH of greater than 7, to stabilize/reinforce the particulate material; and drying the particulate material. According to a third aspect the present invention provides a method of preparing 20 a particulate material comprising the steps of: providing an aluminum-containing silicic acid solution having a neutral to slightly acidic pH, at a temperature of about 200 to 1304C, to produce polyaluminosilicate linkages formed in said material to yield a particulate dispersion; and raising the pH of the dispersion to greater than 7 to stabilize/reinforce particles of 25 the particulate dispersion.

-4 Unless the context clearly requires otherwise, throughout the description and the claims, the words "comprise", "comprising", and the like are to be construed in an inclusive sense as opposed to an exclusive or exhaustive sense; that is to say, in the sense of "including, but not limited to". 5 In some embodiments, the silicic acid solution may be substantially free of aluminum and other metals which are not alkali metals. If desired, a small amount of alkali metal such as sodium or potassium may be initially present, but not enough in the first stage of treatment as described above to cause the mixture to have a pH of greater than seven. 10 The finished product may, as a further step, have a metal or metal oxide coating applied to the product by a conventional technique, to provide a catalyst. The product may be used as a catalyst, as a binder, or a catalyst support, in a chemical reaction such as a hydroprocessing reaction or the like. In some embodiments, a method may be provided for preparing a particulate 15 material which comprises the steps of mixing an aluminum-doped silicic acid solution with a slurry of pre-existing nanoparticles having a neutral to slightly acidic pH of no more than seven, at a temperature of about 200 to 130*C, to produce polyaluminosilicate linkages to form between the pre-existing nanoparticles, yielding a particulate dispersion. Then, the pH of the dispersion is raised to greater than seven, to 20 stabilize/reinforce particles of the particulate dispersion. The silicic acid solution may be added to the slurry of pre-existing nanoparticles, for example in the "heel" (original liquid volume) of the reaction mixture. Alternatively, the nanoparticles may be added to the silicic acid solution. In some embodiments, a method may be provided for preparing a particulate 25 material which comprises the steps of subjecting an aluminum-doped silicic acid -5 solution to a neutral or slightly acidic pH of no more than seven, at a temperature of about 20* to 130 C, without pre-existing nanoparticles, to produce a polyalumino silicate product as a particulate dispersion. Then, as before, the pH of the dispersion is raised to greater than seven, to stabilize/reinforce the particles that have formed in the 5 dispersion. In the above cases, the silicic acid solution, whether by itself or mixed with a slurry of pre-existing nanoparticles, and at neutral to slightly acidic pH (i.e. no more than seven) will undergo chemical condensation forming silicate linkages, incorporating the pre-existing nanoparticles if present, yielding a dispersion of particles which are 10 weblike in characteristic and growing in number, with the pre-existing nanoparticles, when present, being incorporated into the web-like, particulate material. Then, upon raising of the pH to greater than seven, i.e. alkaline conditions, the condensation process shifts to primarily cause growth of the individual, web network without the fonnation of new web particles, so that the particles present in the web-like, 15 particulate dispersion are stabilized/reinforced by growing in bulk, rather than significantly in number. In some embodiments, the aluminum, when present, can be present within a range of about 10 to about 60 weight percent of total solids, the aluminum being calculated as A1 2 0 3 . 20 The pre-existing nanoparticles, if present, may comprise silica, titanium oxides, aluminum oxides, iron oxides, zinc oxides, clays, zirconium oxides, tin oxides, cerium oxides, and mixtures thereof, as well as other metal oxides and the like as may be desired. As stated, this invention, these discrete nanoparticles are linked together in web-like structures which have high surface area, high porosity, and capability to -6 absorb, adsorb or chemisorb appropriate materials, because of the high internal and external surface areas, porosity, and chemical reactivity. In some embodiments, the pre-existing nanoparticles may range in size from about 3 nm to about 300 nm, particularly about 15 nm to about 250 un in presently 5 preferred embodiments. In certain embodiments, the solids content of the agglomerated material in a liquid carrier, after the particles have been stabilized/reinforced as described above, is within the range of about three percent to about 25 percent by weight In the second pH adjustment step, in some embodiments of the method, the p14 is 10 raised to about 7.5 to 10. The alkali compound used to raise the pH is not critical in nature, and may typically comprise sodium hydroxide, potassium hydroxide, lithium hydroxide, ammonium hydroxide, various amines, mixtures thereof, and the like. As previously described, a metal or metal oxide coating may be added by known means to the particle agglomerate of this invention, in liquid or vapor phase, particularly 15 for use as a catalyst or catalyst support. The pre-existing nanoparticles may comprise colloidal silica if desired, for example colloidal silica types such as uncoated silica; aluminum oxide-coated silica; and cerium oxide-coated silica. and silica coated or doped with other metals and the like. Control of particle parameters (particle size, porosity and surface area) can be 20 achieved through manipulation of at least three synthetic factors. These factors are (1) size and concentration of pre-existing particles, (2) time of growth at pH <7 and (3) time of growth at pH >7. Adjustment of the relative ratio of each factor allows for production of "tunable properties".

-7 During the low p14 growth phase, extensive nucleation is occurring in the silica polymerization creating the web-like structure. This web like structure provides high surface area and high porosity. In contrast, high pH conditions favor growth on existing surfaces, and not further 5 nucleation. Subsequent growth on existing surfaces strengthens and reinforces the network. As a result, the strengthened linkages are less prone to collapse during drying, and retain their open structure (and high surface area and porosity). The synthetic process can be monitored using particle-sizing techniques. The measured particle size growth is fast during the low pH stage. However, after the pH 10 adjustment to pH >7 the particle size growth is much slower. Basically, by this invention, the second, pH adjustment step may be delayed, while nucleation and multiplication of silica particles proceeds to any desired degree short of gelation, which will usually eventually take place under the acidic conditions. Then, at some time before gelation, the second, pH adjustment step may take place in 15 which the pH is raised above seven, so that, by this invention, subsequent growth on existing surfaces strengthens and reinforces the network. DESCRIPTION OF SPECIFIC EMBODIMENTS The nanoparticles may comprise stable particles of a size of, typically, about 3 to about 300 rn diameter, being substantially round in shape in some embodiments (i.e. 20 pebble like). However, plate-like nanoparticles may be used, having a comparable major dimension to the diameters of the round nanoparticles, i.e. about 3- 300 nm. Also, string-like nanoparticles, typically of comparable size to the previous nanoparticles, may be used. As stated, nanoparticles of clay such as laponite may be used. An example of a 25 flat particle material would be an alumina such as boehmite. Thus, it can be seen that the nanoparticles can be of any shape, being generally of a dimension of no more than about 300 nn., typically no more than 250 nm. By this invention, a particulate dispersion of particles, each representing a stable network is provided, being useable in a number of desirable uses as described above. 5 For example, the particles of the particulate material prepared in accordance with this invention may comprise a catalyst, a binder, or a catalyst support, having improved surface area, porosity, and stability. Particularly, the aluminum-doped particulate material may be desirable for this purpose, having a natural acidity. Additionally, a particle agglomerate of this invention in a generally conventional 10 liquid carrier may be conventionally applied to a substrate such as paper or the like for use in an ink printing device such as an ink jet printer. The paper substrate may be provided with one or more particle agglomerates of this invention thus prepared and placed in a conventional liquid carrier, being applied to the surface of the paper and dried, to provide a paper which is desirably usable in such an ink printing device. Thus, 15 the material of this invention may be formed into an ink-receptive coating for application to such a substrate, by coating it onto at least a portion of the substrate, such as paper or cardboard. Similarly, In another type of use, wine or juice may be clarified by a method comprising the steps of: providing a liquid to be clarified, preparing a particle 20 agglomerate according to a method like that described herein, bringing into contact the wine or juice and the agglomerate, and thereafter separating the agglomerate from the wine orjuice. As is known, undesirable components of the wine or juice which reduce clarity may thus be removed. The particle agglomerate may be held in a chamber such as a filter, and the wine and juice passed through it, with improved results.

-9 In some embodiments, a method may be provided of preparing a particulate material comprising the steps of: providing an aluminum-containing silicic acid solution having a neutral to slightly acidic pH, at a temperature of about 20* to 130* Centigrade, to produce polyaluminosilicate linkages formed in the material, to yield a particulate 5 dispersion. It is optional whether or not nanoparticles, as described above, are present. Whether nanoparticles are present or not, the aluminum-containing silicic acid solution will condense to form particles in which the particles are in a network form. Then, the pH is raised to greater than 7, to stabilize/reinforce these network particles of the particulate dispersion. 10 It should be noted that particulate dispersions can be prepared with only the first step of condensation at slightly acidic pH, without a step of raising the pH of the dispersion to greater than 7. However, especially in the case of aluminum-containing silicic acid solutions, such materials are physically unstable in the absence of the stabilizing/reinforcing step at a pH of greater than 7. The particulate dispersion, in the 15 absence of such a stabilizing/reinforcing step, will generally form a gel, which is viscous and difficult to handle, being undesirable to obtain the advantages of this invention. In some embodiments of the inventions described above, the aluminum may be present in a mole ratio of about 1:1 to 1:200 of the silica present, calculated respectively as A1 2 0 3 and SiO 2 . Such a material may comprise a catalyst, a binder or a catalyst 20 support. Specifically, the pre-existing nanoparticles described above may in some desired embodiments comprise substantially solid spheres of silica. The term "spheres" is intended as a general term to describe pebble-like particles that are of approximately similar dimension in all directions.

- 10 The nanoparticles can be added at any point during the synthesis process, typically to the acid sol or to the "heel" of the reaction mixture. It should be understood that the aluminum incorporated in the material of this invention may be so incorporated as A10 4 . The material of this invention may be 5 formed from different sources of aluminum such as aluminum nitrate, aluminum chloride, aluminum phosphate, aluminum chlorohydrate, or the like, with resulting changes in composition and properties of the fmal product. Thus, by this invention, sub-micron sized, network materials of a highly homogenous alumino-silicate composition are disclosed, being formed by a new route 10 that results in stabilized particles that do not deteriorate into a gel. These materials may be made with or without pre-existing nanoparticles, thus providing a way to vary the properties of the product of this invention. The process can utilize current manufacturing capabilities, both in terms of raw materials and equipment, and the product may be dried. Surface acidity of the alumino-silicate product can be modified 15 by adjusting the silica to alumina ratio in the silicic acid solution, Porosity and surface area of the material formed by the processes of this invention can be controlled by adjustments in the concentration of the pre-existing nanoparticles, as well as the amount of alumino-silicate or pure silicate particulate material. The above disclosure and the examples below have been offered for illustrative 20 purposes only, and are not intended to limit the scope of the invention, which is as defined in the claims below. In various experimental runs shown below, aluminum doped silicic acid was prepared by cationic exchange of approximately six weight percent solution of chilled sodium silicate, prepared by diluting 600 ml of sodium silicate solution to 3 liters with 25 deionized water.

The dilute sodium silicate solution was deionized with Dowex Monosphere 650-H resin of acid form into a 1:2 ratio of resin: solution ratio in a column. The resin in the column was first flushed with deionized water, and the dilute sodium silicate solution was then passed through the column. When the effluent became acidic, signifying the presence of 5 silicic acid sol, the effluent was collected. The resulting acid sols had specific gravities in the range of 1.0362-1.0380, corresponding to SiO2 concentrations of 5.84%-6.23%. The aluminum salt used for the aluminum doping was then added either in the form of aluminum chlorohydrate or aluminum nitrate, being added to the acid sol at various concentrations, based on SiO2 present. 10 The laboratory reactors used were I or 5 liter, 3-neck, round bottom flasks. The reactors were first soaked in 0.5 Normal Caustic Soda to remove any SiO 2 residue, and then rinsed to neutrality with deionized water. These flasks were stirred with standard, uncalibrated lightening mixers. A thermocouple was passed through one side neck, while the opposing neck housed the addition hose for the acid sol. The addition of the 15 aluminum-doped acid sol was performed with a peristaltic pump at a predefined rate from a chilled reservoir. Example 1 In this particular example, the aluminum-doped silicic acid was prepared using 88.6 grams of aluminum chlorohydrate, added to 1160 grams of 7% silicic acid sol, 20 made as above. There was added to a reaction flask 1000 ml of deionized water, which was heated to 90*C. The aluminum-doped acid sol was added via a peristaltic pump at the rate of 4.6 ml/minute for two hours and the pumping was suspended for 15 minutes. After the 15 minutes, the pH of the reaction mixture was raised to about pH 9, with the 25 addition of 50 ml of concentrated ammonium hydroxide. Addition of the aluminum- - 12 doped silicic acid feed was resumed, until 130 grams of added aluminum-doped silicic acid was fed into the system. During this time, the pH was periodically monitored, and an additional amount of 20% ammonium hydroxide was added to maintain the pH of the material above 9.5. The total addition time was approximately three hours. 5 The reaction was heated at 90 0 C for an additional hour, after completing the aluminum-doped silicic acid feed, to ensure a complete reaction. The reaction mixture was then allowed to cool, with continuous stirring. The resulting product was detennined to contain 25 wt. percent of A123, based on the silica (SiO 2 ) present, corresponding to a mole ratio of SiO 2 : A1 2 0 3 of 7 to 1. 10 Nitrogen sorption measurements to determine surface area and porosity were performed with an Autosorb- 1 C unit from Quantachrome. Each sample was calcined after drying and then degassed for three hours at 300 0 C. Each sample was characterized by a multi-point BET surface area, total pore volume, and BJH adsorption pore size distribution. Chemisorption via NH 3 temperature programmed sorption was also run on 15 select samples using the same instrument. Transmission electron microscopy was performed to determine microtexture and particle shape. The samples were characterized by powder x-ray diffraction and x-ray energy dispersive spectroscopy, Z-contrast imagining, and electron energy-loss spectroscopy in a field emission gun scanning transmission electron microscope. 20 Physical data from these and other tests indicated a surface area of 359 square meters per gram; a pore volume of 0.87 cc/gm; and a pore diameter of 97.8 angstroms. Example 2 The experiment of Example 1 was repeated, in which a polyaluminosilicate was prepared in a manner similar to Example 1, but containing 34 weight percent of A1 2 0 3 , 25 based on the silica present, and a SiO 2 : A1 2 0 3 mol ratio of 4.99.

-13 In this embodiment, similar tests to Example 1 indicated a surface area of 238 square meters per gram, a pore volume of 0.95 cc/gm, and a pore diameter of 160 angstroms. Comparative Example 3 5 The experiment of Example I was repeated, the aluminum-doped acid sol being prepared with 100.28 grams of aluminum chlorohydrate, added to 1,286 grams of 4.9% acid sol, prepared as previously described. A "heel" was prepared by adding 750 ml of deionized water into a reaction flask, and heated to 90*C. The aluminum-doped acid sol was added via peristaltic pump at a rate of 5.0 ml per minute, until the entire amount of 10 acid sol was fed. No pH adjustment was made during the reaction, so that conditions remained on the acid side. The reaction mixture became very viscous during sol addition, indicating gelling. It was allowed to cool after addition of all of the acid sol, with continuous stirring. No alkali was added to bring the pH to the alkali side during the process. 15 In this system, the percentage of A1 2 0 3 , based on the silica present, was 37.7 weight percent. The mol ratio of SiO 2 : A12O 3 was 4.5. The surface area was calculated to be 177 M 2 /g, which is well below the surface areas of the previous two examples; a pore volume of 0.14 cc/gm, which is also well below the previous examples, and a pore diameter of 32.5 angstroms, also well below the first two examples. 20 We believe that the difference in results is a result of the lack of a "flip" of the process to alkali conditions, as was performed in the previous two examples. Example 4 Another experiment similar to Example 1 was performed, except that the percent of Al2 3 to silicate present was 10%, and the Si02: A12O 3 mol ratio was 16.97.

- 14 The particles of the resulting particulate material were measured with a surface area of 537.7 M 2 /g; a pore volume of 0.84 cc/gm, and a pore diameter of 62.6 angstroms. Example 5 The procedure of Example 1 was performed, but using proportions so that the 5 percentage of A1 2 0 3 , based on the silica present, was 8.76%, with a SiO 2 : A1 2 0 3 mol ratio of 19.37. The particulate material thus formed was measured to have a surface area of 560.6 M 2 /g; a pore volume of 0.96 cc/gm, and a pore diameter of 68.7 angstroms. Example 6 The process of Example 1 was repeated, but using reaction conditions so that the 10 percentage of A1 2 0 3 , based on the silica present, was 6.35 weight percent and the SiO 2 : A1 2 0 3 mol ratio was 26.73. In this circumstance, the surface area was calculated as 533.4 M 2 /g; a pore volume of 1.07 cc/gm; and the pore diameter of 79.9 angstroms. Example 7 The process of Example 1 was repeated, but under circumstances so that the 15 percentage of A1 2 0 3 , based on the silica present, was 2.35 with an SiO 2 : A120 3 mol ratio of 72.22. In this circumstance, the surface area of the particulate product was calculated to be 581.1 M 2 /g, with a pore volume of 0.46 cc/gm, and a pore diameter of 31.9 angstroms. 20 Example 8 The process of Example 1 was repeated, but without the addition of any aluminum, so that the particulate product was pure silica. The resulting product had a surface area calculated at 230 M 2 /g, with a pore volume of 0.94 cc/gM, and a pore diameter of 169 angstroms.

-15 It can be seen that superior results are obtained with all of the examples above, when compared with Comparative Example 3, which is the only example where there is no "flip" to alkaline conditions during the particulate growth process. Example 9 5 This Example illustrates the incorporation of substantially two dimensional nanoparticles into a three dimensional network. 150 ml of deionized water were placed in a reaction vessel and heated to 600 C. Then, 180 grams of silicic acid containing 22 grams of preexisting aluminum oxide nanoparticles comprising boehmite nanoparticles (being substantially two dimensional). 10 The nanoparticles were added gradually to the water with stirring. After this addition, 20 wt. percent of sodium hydroxide, based on the silicic acid, was added to bring the pH to the alkali side. Thereafter, another 180 grams of silicic acid containing 22 grams of the aluminum oxide (boebmite) were added. The reaction mixture was maintained at 60"C for four hours, with stirring 15 continued. The final product was filtered, and provided a high surface area, high pore volume, particulate material. The surface area was 258 m 2 /gm and the pore volume was 0.43 cc/gm. The pore diameter was 67.4 angstroms. The material is particularly suited for formulation into a paper coating material. 20 It can be seen that the boebmite nanoparticles used in this example are doped into the silicic acid reactant. In some embodiments, desirable products can be made with a later addition of nanoparticles. Example 10 In this particular example, the silicic acid is not doped with aluminum. The 25 silicic acid was prepared by cationic exchange of approximately 4.5 weight percent -16 solution of chilled sodium silicate, prepared by diluting 600 ml of sodium silicate solution to 4 liters with deionized water. The diluted sodium silicate was deionized with. Dowex Monosphere 650-H resin of acid form into a 1:2 ratio of resin: solution ratio in a column. The resin in the column was first flushed with deionized water, and the diluted 5 sodium silicate solution was then passed through the column. When the effluent became acidic, signifying the presence of silicic acid, the effluent was collected. There was added to a reaction flask 171 ml of deionized water and 28.9 g of a 34.5% deionized solution of preexisting silica nanoparticles of about 20 nm in diameter. This solution was heated to 90*C. The silicic acid was then added via a peristaltic pump 10 at the rate of 0.8 nil/minute for about 3.5 hours. The pumping was suspended for 15 minutes. After the 15 minutes, the pH of the reaction mixture was adjusted to above 7, with the addition of 2ml of concentrated ammonium hydroxide. Addition of the silicic acid feed was resumed until a total of about 350 grams of added silicic acid was fed into the system. The total addition time was approximately 7.5 hours. 15 The reaction was heated at 90 0 C for an additional hour, after completing the silicic acid feed, to ensure a complete reaction. The reaction mixture was then allowed to cool, with continuous stirring. Physical data from these and other tests indicated a surface area of 185 square meters per gram; a pore volume of 0.58cc/g; and a pore diameter of 125 angstroms. 20 For materials such as Example 10, experiments were conducted varying the relative percentages of silica present as pre-existing nanoparticles, the amount of silicic acid added at low (acid) pH, and the amount of silicic acid added under alkaline conditions. The surface area and pore volumes were found to correlate with the percentage of silica added as silicic acid during the low pH phase. For example keeping 25 the fraction of silica for pre-existing nanoparticles constant (77%) while increasing the -17 fraction of silicic acid fed at low pH-from_8.8% to 15.7%, this increased the surface area from 150 to 190 m 2 /g, with a corresponding increase in pore volume from 0.31 -cc/g to 0.42 cc/g. Example 11 5 In this particular example, the final agglomerated material from Example 10 is coated with boric acid stabilized basic aluminum acetate. The agglomerated material was first concentrated to a sol of approximately 15 wt. percent solids. The sol was then deionized with Dowex Monosphere 650-H resin of. acid form with a 1:2 ratio of resin: solution ratio in a column. When the effluent became 10 acidic, signifying the presence of deionized agglomerate, the effluent was collected. The Zeta potential of this material is approximately -10 MV at pH 4. To 100 g of the effluent was added about 3 g concentrated acetic acid solution to stabilize the material at pH 3. This effluent was added to a reaction flask 85 g of a 25 wt. percent freshly 15 prepared solution of basic aluminum acetate. The deionized solution was added to the flask via a peristaltic pump at the rate of 4.0 ml/minute. The zeta potential of the resulting solution was found to be about +30 mV at a pH of 4. Example 12 20 In this particular example, the silicic acid is doped with aluminum, and the preexisting particles in the heel are also doped with aluminum. The doped silicic acid is prepared per the process of Example 1, but under circumstances such that the percentage of A1 2 0 3 , based on the silica.present, was 10 wt. percent, with an SiO 2 : A1 2 0 3 mol ratio of 17.0.

There was added to a reaction flask of 914 ml of deionized water and 286 g of a 21 wt. % deionized solution of preexisting silica nanoparticles of about 8 nm in diameter. These were grown such that the percentage of A1 2 0 3 , based on the silica present in the particles, was 2, with an SiO 2 : A1 2 0 3 mol ratio of 84.8. 5 - This solution was heated to 90 0 C. The doped silicie acid was then added via a peristaltic pump at the rate of 10 ml/minute for about 1.0 hour. The pumping was suspended for 15 minutes. After the 15 minutes, the pH of the reaction mixture was adjusted to above 9, with the addition of 30 ml of concentrated ammonium hydroxide. Addition of the doped silicic acid feed was resumed until a total of about 1543 grams of 10 doped silicic acid was fed into the system.- The total addition time was approximately 2.5 hours. The reaction was heated at 90*C for an additional hour, after completing the doped silicic acid feed, to ensure a complete reaction. The reaction mixture was then allowed to cool, with continuous stirring. 15 Physical data indicated a surface area of 650 square meters per gram; a pore volume of 0.59 cc/g; and a pore diameter of 36 angstroms

Claims

1. A method of preparing a particulate material comprising the steps of: mixing an aluminum-doped silicic acid solution comprising preexisting nanoparticles having a pH of no more than essentially 7, at a temperature of about 200 to 1300 C, to produce polyaluminosilicate linkages to form between the preexisting nanoparticles, yielding a particulate dispersion; and raising the pH of the dispersion to greater than 7 to stabilize/reinforce particles of the particulate dispersion, wherein the particulate dispersion has a mole ratio of Si0 2 to A1 2 0 3 in a range of I to 11.

2. The method of Claim 1, wherein the aluminum is present within the range of about 10 to about 60 wt. percent of total solids, calculated as A1 2 0 3 .

3. The method of Claim 1, wherein the preexisting nanoparticles comprise silica.

4. The method of Claim 1, wherein the preexisting nanoparticles are selected from the group consisting of silica, titanium oxides aluminum oxides, iron oxides, zinc oxides, zirconium oxides, tin oxides, cerium oxides, and mixtures thereof.

5. The method of Claim 1, wherein the preexisting nanoparticles range in size from about 3 nm to about 300 nm, optionally wherein the preexisting nanoparticles range in size from about 15 nm to about 250 nm.

6. The method of Claim 1, wherein the solids content of the particulate material is, after the particles are stabilized/reinforced, within the range of from about 3% to about 25% by weight.

7. The method of Claim 1, wherein the pH is raised to about 7.5 to 10.

8. The method of Claim 7, wherein the pH is raised using an alkalicompound selected from the group consisting of sodium hydroxide, potassium hydroxide, lithum hydroxide, ammonium hydroxide, amines, and mixtures thereof -20

9. The method of Claim 1, further comprising applying a metal oxide coating to the particle agglomerate.

10. The method of Claim 1, wherein the nanoparticles comprise colloidal silica.

11. The method of Claim 10, wherein the colloidal silica is selected from the group consisting of uncoated silica, aluminum oxide-coated silica, aluminum-doped silica and cerium oxide-coated silica, optionally wherein the colloidal silica particles have a particle size in the range of from about 3 nm to about 150 nm.

12. A paper for use in an ink printing device comprising a paper substrate and one or more particle agglomerates prepared according to the method of Claim 1 and applied to the surface of the paper.

13. A method of preparing a particulate material comprising the steps of: adding a silicic acid solution, with mixing, to a slurry of pre-existing nanoparticles having a neutral to slightly acidic pH, at a temperature of about 200 to 130'C, to produce polysilicate linkages to form between the pre-existing nanoparticles, yielding a dispersion having a solids content of at least about 5% SiO 2 by weight, wherein the dispersion has a mole ratio of SiO 2 to A1 2 0 3 in a range of I to 11; and adjusting the pH of the dispersion to achieve a pH of greater than 7, to stabilize/reinforce the particulate material; and drying the particulate material.

14. The method of claim 13 in which said silicic acid solution is substantially free of aluminum and other metals which are not alkali metals.

15. The method of claim 14, further comprising applying a metal oxide coating to the product.

16. A method of preparing a particulate material comprising the steps of: providing an aluminum-containing silicic acid solution having a neutral to slightly acidic pH, -21 at a temperature of about 200 to 130'C, to produce polyaluminosilicate linkages formed in said material to yield a particulate dispersion, wherein the particulate dispersion has a mole ratio of SiO 2 to A1 2 0 3 in a range of I to 11; and raising the pH of the dispersion to greater than 7 to stabilize/reinforce particles of the particulate dispersion.

17. The method of claim 16 in which the silicic acid is free of added, preexisting nanoparticles.

18. The method of claim 1 in which said preexisting nanoparticles comprise substantially solid pebbles of silica.

19. The method of claim 1 in which the silicic acid solution is added to the slurry of preexisting nanoparticles.

20. The method of claim 1 in which the nanoparticles are added to the silicic acid solution.