Patent application title: Solutions of Silicon Metal and Methods of Making and Using Same
Ben Elledge (Sugar Land, TX, US)
Richard Okun (Fayetteville, NY, US)
Robert Kulperger (New York, NY, US)
SILICON SOLUTIONS LLC
IPC8 Class: AC10G104FI
Class name: Mineral oils: processes and products tar sand treatment with liquid inorganic (only) liquid
Publication date: 2012-02-16
Patent application number: 20120037543
The present invention generally relates to a formulation created by
reacting sodium hydroxide, water, and silicon metal which has unique
properties and many uses. The instant invention is further directed to
methods of producing and using such formulations.
1. A method for extracting oil from tar sands comprising: contacting said
tar sands with an aqueous silicon solution, separating the sand from the
solution, and recovering the oil from the solution.
2. The method of claim 2, wherein the aqueous silicon solution comprises SiO2 and Na2O, in a ratio of SiO2 to Na2O, by mass, of at least 3.8:1.
3. The method of claim 3, wherein the aqueous silicon solution has a pH of greater than 8.5.
4. The method of claim 1, wherein the aqueous silicon solution can be re-used after being used for extracting oil from tar sands.
 This application is a continuation of U.S. patent application Ser. No. 12/638,116 filed on Dec. 15, 2009 which is a continuation of Ser. No. 11/979,997 filed on Nov. 13, 2007 which is a continuation-in-part of U.S. patent application Ser. No. 11/001,308, filed Dec. 2, 2004, now U.S. Pat. No. 7,293,568 issued Nov. 13, 2007, which claims priority to Provisional/Application No. 60/526,140, filed Dec. 2, 2003. This application also claims priority to U.S. patent application Ser. No. 10/913,483, now abandoned, which is hereby incorporated by reference in its entirety.
FIELD OF THE INVENTION
 The present invention generally relates to a formulation created by reacting sodium hydroxide, water, and silicon metal which has unique properties and many uses. The present invention further relates to methods of washing metal parts and cleaning using formulations comprising aqueous solutions of silicon. The present solution further relates to oil recovery using formulations comprising aqueous solutions of silicon.
BACKGROUND OF THE INVENTION
 Silicon is well known in the art for providing an effective coating for use with a variety of applications. For example, silicon is often used to coat metals, thereby reducing corrosion of the metal. One of the disadvantages associated with the use of silicon as a coating has been the difficulty of providing silicon in an aqueous medium. This is in part due to silicon being insoluble in water. Many attempts have been made to combine silicon or other metals in an aqueous solution. For example, U.S. Pat. No. 4,571,328 to Rice relates to one such combination. The aqueous electro-deposition baths produced in accordance with U.S. Pat. No. 4,571,328 addresses some of the problems associated with prior art techniques of making silicon solutions. The patent describes the formation of an aqueous silicon solution from the combination of silicon, sodium hydroxide and water in the molar ratio of 6:1:10, respectively. While the resulting solutions may be useful, the manufacturing process disclosed is complex and dangerous and results in solutions that are unstable and inferior in quality and character to the solutions of the instant invention. As such, these solutions are not suited to the methods of the present invention.
 U.S. Pat. No. 4,570,713, also to Rice, relates to aqueous silicon compounds for use with oil recovery methods. As with U.S. Pat. No. 4,571,328, this patent teaches the formation of a metal hydride from reacting a non-alkaline metal with an alkaline metal hydroxide in water. The metal hydride is water-soluble and may be diluted to a solution with specific gravity of 1.3. As in the '713 patent, the manufacturing process disclosed is complex and dangerous and results in solutions that are unstable.
 Thus, it would therefore be desirable to provide a safe and effective method of manufacturing stable, aqueous solutions of silicon. The present invention solves the above problem by providing a safer, more effective method of reacting sodium hydroxide, water, and silicon metal to produce an aqueous solution of silicon which is more stable and has more useful properties than any known aqueous solution of silicon. The solutions of the instant invention have a myriad of uses as a result of this improved stability and its unique properties.
 Washing hydrocarbons from metal parts has long been a tedious and inefficient means of cleaning tools, parts, and/or metal components. Hundreds of thousands of dollars are spent every month on cleaning solutions for use in parts washing machines around the country, and many of these solutions clean parts only marginally at best and leave unacceptable "dirty" parts at the end of the so-called cleaning cycle. The combination of these cleaning solutions and their by-products create serious waste water and effluent problems. Most cleaning products, e.g., petroleum based solvents, high pH industrial cleaners, etc., are (i) difficult to handle, (ii) highly volatile, and (iii) inherently toxic to our environment. Moreover, petroleum products that are recovered from parts washing machines are contaminated and are not re-usable or re-cyclable. And finally, many companies are forced to treat environmental effluent from the parts washing process to meet environmental standards, resulting in increased cost of business.
 It is thus apparent that there still remains a long-felt, but unfulfilled need to provide an environmentally safe, simple wash capable of cleaning tools, parts, and/or metal components. The present invention solves the above stated problems through the use of a revolutionary formulation created by reacting sodium hydroxide, water, and silicon metal which has unique properties and many uses beyond that of a cleaning solution.
 It becomes more apparent everyday that the production of oil in the United States and throughout the world is very important. Since oil is obviously a limited resource, it is imperative that we develop processes that will more efficiently extract oil from the earth. In the past, it was relatively easy to find new oil reserves when a field was depleted or became unprofitable. In many fields only 15-25% of the oil in place was actually recovered before reservoir pressure or drive was depleted or other factors made it uneconomical to continue to produce the field. As long as new reserves were readily available, old fields were abandoned. However, since most of the existing on-shore oil in the United States has already been discovered, it is obvious that such known reserves must be efficiently and economically produced.
 It has been estimated that at least 50% of the known oil reserves of the United States cannot be recovered using conventional pumping methods. A substantial amount of this oil is of an abnormally low gravity, and/or high viscosity, often coupled with the fact that there is little or no pressure in the oil-bearing formation. In the absence of formation pressure, even oil of average viscosity and gravity is difficult to produce without adding external energy to the formation to move the oil into a producing borehole. Accordingly, a great deal of attention has recently been given to various methods of secondary recovery. Water flooding has been utilized with mixed results to attempt to increase the natural reservoir pressure hydraulically. Thermal flooding techniques, such as fire flooding, steam injection and hot water flooding have been utilized to alter the viscosity of the oil and hence, enhance its flow characteristics.
 In those cases where the natural energy of the reservoir is insufficient to overcome the resistive forces such as the forces of viscous resistance and the forces of capillary action, external energy must be applied. To illustrate such cases, this phenomenon is typically encountered in shallow formations containing high viscosity oil that has little or no reservoir energy or formation pressure available, and in those oil-producing formations in which the reservoir energy has been depleted or dissipated. In this discussion, we have been referring to "mechanical" forces acting within the producing formation. In a formation in which the natural energy of the reservoir has been depleted, the mechanical forces in the formation have reached near equilibrium and no pressure differential is available to drive the oil from the formation into the well bore. In all of the cases where reservoir energy was depleted by conventional primary production, or non-existent in the first instance, the chemical balance of the producing formation remains undisturbed and in virtual equilibrium.
 Artificial forces introduced into the reservoir such as water or gas through various "pressuring" or "flood" techniques of secondary recovery can effect a mechanical change in the formation by way of pressure. Steam pressure is likewise effective, with some side benefits from heat. Combustion of some of the oil in the formation through "fire-flooding" and heating a well bore serve to reduce the viscosity of the oil in place and enhance flow characteristics but lack a drive to force the oil through the formation and into a producing well bore. However, these are primarily mechanical forces applied and operating only on an exposed face or surface of the formation, and if some chemical or molecular change is accomplished in the fluids in the formation, it is limited to a localized phenomenon. The instant invention will enhance the flow characteristics of the oil in the formation.
 Water flooding has a number of economic advantages as an oil recovery process. Although over half of the original oil in place can remain after water flooding, there are many factors which favor its use. Water of sufficient volume and quality for flooding is generally available. Because of its hydrostatic head, it is readily injected at sufficient rates in most reservoirs and spread well throughout the formation.
 The investments usually required for initiating a water flood project include water supply wells, water treating facilities, pump stations, flow lines from the central plant to the injection wells, and the injection wells themselves. Depending upon the deliverability of the water supply wells and treating chemical costs, the cost can range from a few mills to as much as five cents or more per barrel of injected water.
 Production costs have a similarly wide range. These can depend upon the type of lift equipment needed and whether any unusual treating is required to separate the produced oil and water. Where particularly troublesome oil-water emulsions exist, treatment and chemical costs can escalate rapidly.
 In summary, however, through the use of available technology and equipment, water flooding is for a large number of reservoirs an economically attractive oil recovery method. Its limitation is that significant quantities of the oil, initially in place are left unrecovered after water flooding.
 Thus, there remains a long-felt and unfulfilled need for a method of improved oil recovery. The present invention greatly improves the process known as water flooding by substituting the silicon solutions of the present invention for water. The unique properties of the silicon solutions substantially increase the percentage of oil that can be collected in secondary recovery of oil fields and reservoirs.
 Tar sands are another source of oil that are currently subject to current oil recovery techniques. "Tar sands" is a common name of what are more accurately called bituminous sands. Tar sands are also referred to as oil sands or extra-heavy oil. Tar sands are a mixture of sand or clay, water, and extremely heavy crude oil.
 In current oil recovery methods, tar sand deposits are strip mined or made to flow into producing wells by in situ techniques which reduce the oil's viscosity using steam and/or solvents. These processes use a great deal of water, require large amounts of energy, and produce large amounts of hazardous waste.
 The crude oil or crude bitumen extracted from tar sand deposits is a viscous, solid or semisolid form of oil. It does not easily flow at normal ambient temperatures and pressures, making it difficult and expensive to process into gasoline, diesel fuel, and other products. Despite the difficulty and cost, tar sands are now being mined on a vast scale to extract the oil, which is then converted into synthetic oil by oil upgraders, or refined directly into petroleum products by specialized refineries.
 Many countries in the world have large deposits of tar sands, including the United States, Russia, and various countries in the Middle East. However, the world's largest deposits occur in two countries: Canada and Venezuela, both of which have tar sands reserves approximately equal to the world's total reserves of conventional crude oil. As a result of the development of these reserves, most Canadian oil production in the 21st century is from oil sands or heavy oil deposits, and Canada is now the largest single supplier of oil and refined products to the United States.
 Current methods of extracting oil from tar sands are costly and environmentally unfriendly. The current methods rely on vast quantities of water that then becomes contaminated. Where particularly troublesome oil-water emulsions exist, treatment and chemical costs can escalate rapidly. As such, there is a need for methods and compositions that will reduce both the environmental and financial costs of extracting oil from tar sands. The present invention provides compositions and methods that do just that.
SUMMARY OF THE INVENTION
 The present invention contemplates a stable complex of silicon metal in an aqueous solution.
 One embodiment of the invention encompasses a stable, aqueous solution comprising SiO2 and Na2O, wherein the ratio of SiO2 to Na2O, by mass, is at least 3.8.
 Another embodiment of the invention encompasses a stable, aqueous solution comprising SiO2 and Na2O, wherein the ratio of SiO2 to Na2O, by mass, is at least 3.8 and wherein the solution has a pH of at least 11, has low reactivity and/or corrosivity, and is reusable in oil extraction methods.
 It is also an object of the present invention to provide methods of making stable, aqueous silicon solutions.
 The present invention also embodies method of extracting oil from tar sands comprising contacting tar sands with stable, aqueous silicon solutions.
 The present invention further embodies methods of washing hydrocarbons from metal parts.
 The present invention also contemplates methods of using stable, aqueous, silicon solutions in the following cleaning methods:
 Cleaning aromatic sludge tanks--specifically benzene, but also applicable to toluene, xylene, and other type tanks; pits, oil and sludge and other wastes clean up: barges, railcars, rig wash slop oil recovery: coal slurry pond clean up, gun barrel separator clean up; pipeline cleaning ("Pig" operations); pipeline "Sock type" filter cleaners; pipeline right of way clean up; site, pad, and staging area clean up and remediation; parts washing; computer circuit board washing; steam cleaning; soil washing; carpet cleaning; carpet cleaning and flea treatment; upholstery cleaning; and cleaning concrete.
 Another embodiment of the present invention is a method for improved oil recovery using silicon solutions. The silicon solutions can be used to flood an oil bearing material such as an oil well. The flooding increases the amount of oil that can be extracted from the oil bearing material.
 The present invention also contemplates the following uses for liquid silicon solutions and products based on the solutions: Carrier for other chemicals; Additive for lubricant and engine oil enhancement; Additive to water base paint for fire suppressant; Wetting water for fire penetration and suppression; Oxide and rust; removal; Fertilizer; Carrier of fertilizers; Direct additive for growth enhancement of fruits, vegetables, and grasses; Additive for fire proofing wood and other cellulose source materials for construction industry; Fireproof wood shingles; Wetting agent for fire fighting . . . fire penetration; Fireproof drop cloth for welders and metal workers; Electrolyte electroplating of zinc and silicon material for anti-galling and anti-corrosion use as a de-oxidizer of old paints (especially on automobiles) restorative characteristics; Replacement for meta-silicates; Treatment for carbonaceous build up in heat exchangers (O2 scavenging property); Additive to any number of cellulose sources for production of fire proof particle board (saw dust, potato peals, old news paper, corn husks, cotton linters, and many others. Dried, ground to small particle size and then saturated with the concentrate and then heated and compressed.); USDA multi-cleaner for large food chains that is able to cut grease from the floor of the food preparation area, clean the grease in the grease trap/sewer outlet, and can be used on cleaning food preparation surfaces and food eating-surfaces; and Plastic-like, non-petroleum based, biodegradable materials with high strength to weight ratio.
 Another embodiment of the present invention is for methods of making stable silicon foam materials.
 The present invention also contemplates the use of a stable foam for fire and insulation applications including: Fire doors; Fire proof weight to strength ratio products for food galleys on commercial aircraft; Insulation applications where both extreme high and low temperatures are present; Fire walls in high rise construction; Steel insulation on high rise buildings; Home construction materials; Insulation, fire proofing and sound proofing all in one material; Fire proof packaging materials; Fire proof pads for carpets; Fireproof mattresses; and Fire proof motor homes.
 Another embodiment of the present invention is insect resistant particle boards.
 Another embodiment of the present invention is for methods of producing a silicon materials with glass-like properties.
 The invention also contemplates the following uses for the glass phase silicon material: Gems for laser applications; Encapsulation of nuclear and hazardous biological wastes; Spun into fine glass fibers it can be a new non-flammable insulation material; New fiber optics can use the unusual optical properties; Special glass applications where high strength glass is required; and Applications for cut and colored glass with properties similar to stained glass windows. Other developments based on the silicon solutions include: Production of high quality gemstones; Electrodeposition of silicon; Development of a new form of energy; and Means and methods for extraction, collection, refinement, and development of Orbitally Realigned Mono-atomic Elements.
BRIEF DESCRIPTION OF THE FIGURES
 FIG. 1 shows the bitumen recovery using Symcrude style BEU with four solutions in accordance with the instant invention.
 FIG. 2 shows the bitumen froth quality as defined by bitumen/solids ratio in the froth
 FIG. 3 shows a of sand impregnated with dyed oil. Individual samples of sand were then washed with ERA-3.
 FIG. 4 shows sand that has been washed with a solution in accordance with the instant invention.
 FIG. 5 shows a second sample of dyed oil.
 FIG. 6 shows a sample of sand substantially free of oil after washing with a recycled solution in accordance with the instant invention.
 FIG. 7 shows a comparison of samples of dye impregnated sand, both pre and post washing with a solution in accordance with the instant invention.
DETAILED DESCRIPTION OF THE INVENTION
 For simplicity and illustrative purposes, the principles of the present invention are described by referring to various exemplary embodiments thereof. Although the preferred embodiments of the invention are particularly disclosed herein, one of ordinary skill in the art will readily recognize that the same principles are equally applicable to, and can be implicated in other compositions and methods, and that any such variation would be within such modifications that do not part from the scope of the present invention. Before explaining the disclosed embodiments of the present invention in detail, it is to be understood that the invention is not limited in its application to the details of any particular embodiment shown, since of course the invention is capable of other embodiments. The terminology used herein is for the purpose of description and not of limitation. Further, although certain methods are described with reference to certain steps that are presented herein in certain order, in many instances, these steps may be performed in any order as may be appreciated by one skilled in the art, and the methods are not limited to the particular arrangement of steps disclosed herein.
 The composition of the instant invention is a stable complex of silicon metal in an aqueous solution. It has been discovered that the composition is more stable than previously described solutions of silicon and has a myriad of heretofore undisclosed uses. The instant invention provides a safe method of manufacturing aqueous solutions of silicon. This method requires an appropriate reaction vessel, silicon metal, and NaOH.
 The first thing required is a suitable vessel to contain the reaction. While a single reaction, or in some cases several-reactions can be run in any number of vessels the reaction will, in time, destroy just about any container from glass to steel. The reaction eventually causes "hydrogen embrittlement" and vessels can burst open spontaneously and if a reaction is underway this can be very hazardous. As such, the choice of reaction vessel is critical.
 It has been determined that high percentage nickel materials are best suited to the task of resisting the problems associated with running the reaction but solid vessels of such material are not known nor used due to excessive costs. Lined or clad vessels are currently available in the market. The current preferred vessel is a reactor with a single bottom valve in the coned bottom and an open top. It is a nickel welded overlay design and the main structure is 1'' thick 4140 steel.
 The cone shaped bottom is critical as it has been found that using flat bottomed tanks and or beakers from a lab had the effect of exaggerating the "up the side rise" of the reaction and thus vessels had to have a higher side wall to "hold" the reaction in the rising or balloon stage. Without a coned bottom the reaction vessel typically needed to be sized six to eight times the volume of the base rock load to keep the reaction from boiling over the top. In some cases the ratio was even greater. With the coned bottom the load is easier to hold and the reaction has the noticeable "FIG. 8" rotation during the early reaction and the ratio is about 3.5 to one. The current vessel also has a reduced height to width ratio. The current vessel has a width of eight feet. The straight side is also eight feet and the distance from the coned bottom to the bottom of the valve is an additional five feet (5'). It is important that; vessel have no crevices because crevice eddying will have a negative effect on the results. The reaction generates a significant amount of energy and substantial heat is produced, a heavy vessel can help in dissipating this heat and is also useful in holding initial heat in the course of the continued reaction.
 During the reaction significant hydrogen is produced and the potential for explosion always exists where free hydrogen is present. Thus, care should be exercised while running the reaction regardless of the construction of the vessel.
The Silicon Metal
 Upon procurement of a suitable vessel the reagents that are particular to the reaction are required. The silicon metal is in the form of rock.
 Using commercially available Si (approximately 97-99% pure) will produce product with the needed efficacy. If lower grades are used, the resulting solution may be contaminated to a point where efficacy of the resulting solution may be affected.
 It is important to note that the level of impurities in the rock are important to the reaction. If the rock does not contain impurities, as with reagent grade material, the reaction will not start without addition of external heat. When it does start it will react too vigorously unless water cooled. The "start" may take several hours of near boiling heat to cause the reaction to begin actual reaction and it will run only a short while when it does. Sometimes additional external heat is needed to have it be completed. The resultant material will be high purity and will be very clear to just slightly opaque and will never turn the "yellowish" color common to the desired material when it is exposed to sun light.
 In a preferred embodiment of the instant invention the composition of the base rock is: 97-99% silicon by weight Currently such rock is available commercially in the U.S., Canada, and China.
 In order to properly perform the reaction, it is necessary to develop the "base rock" for the reactions and this takes time and understanding of the process. For the reactor described above, the silicon metal should be in chunks from 2'' (two inches) minimum to 4'' (four inches) in diameter or square maximum. Some very small particle size material is unavoidable but should be discouraged from the supplier. It will quickly convert into "fines" and will ride the top of the reaction and become a general nuisance as well as very damaging to pumps and mechanical seals in the process. If the particle size of the reaction is too small the reaction will over react and many times rush up the side of the reactor and spill onto the floor.
 When starting the very first reaction one should know that in the early stages of the base rock development great accuracy is required. After a few reactions the base rock will begin to show reactivity signs that may look like saw cuts across the face of the rock and or worm hole type configurations that make a surface much like sea coral. This is called the "etching" process and until we have a base of rock that is over 4000 pounds or almost half of the gross maximum reaction weight, every portion of the 1-6-10 molar ratio must be managed with great care.
 In a desired vessel we estimate by geometry what the maximum reaction possible will be from that vessel. In the case of our current vessel we determined that at somewhere around 8000 pounds we would reach the maximum amount of the desired product the vessel will hold.
 Making the height greater and increasing the base has been tried and the extended "dome" portion of the reaction can and often does collapse into an improper reaction or "middle collapse" that can make the reaction products turn white . . . a common indicator of failure. In such a case the new load material is lost and the old material must be significantly cleaned if not removed and re-started, or a blue collapse where the material stops mid-reaction and returns to a blue rock like state can occur and this must be removed by hand from the reactor and in such cases if it is allowed to fully dry it must be removed by jack hammers. Thus, it is necessary to stay within the known parameters.
 In the current example, one begins with one hundred pounds and work up 25% at a time until we get to 1000 pounds. We then double the base and run the reaction with and additional 12.6758% of the total base rock. The reaction was then doubled to 2000 pounds and three reactions run with the 253.52 pounds of fresh material. This resulted in 4 drums of 1.25 specific gravity material for six more reactions with the same replacement material. We then went to 4000 pounds and doubled the values and the percent yield was as expected based on the scale up ratio. We then went to 6000 pounds and finally 8000 pounds but the reaction was getting within a couple of feet of the top so we ran subsequent reactions 20 pounds at a time until we reached 8800 pounds and the reaction was one foot from the top.
 Sodium hydroxide is dangerous to handle and is temperature sensitive. The process can be run with powdered material but it has been found that top loading of dry sodium hydroxide makes for poor base rock and eventual failure of the process. Loading the NaOH from the bottom is critical to a successful reaction.
 The rock and water are loaded onto the base rock. Enough water is kept back to purge the load lines of the NaOH after it is loaded from the bottom. The NaOH is loaded and then the remainder of the water. One to two hundred gallons of water is enough to purge the lines and load the last of the NaOH into the reactor. The reaction will commence immediately with a bubbling and release of hydrogen.
 As a rule a good middle ratio reaction will yield 1.4 gravity material. The blend down to 1.25 gravity should increase the volume by a third.
 It should be mentioned that this is the 1-6-10 ratio. The "window" is believed to be from 1 to 5.75 to 9 to 1 to 7.75 to 12. This is a restrictive "window" but it does leave some leeway for error. As can be seen, this formulation will allow the computation of any amount of silicon to the specified ratio. A spread sheet reflecting twenty pound increments up to four thousand pounds of base may be useful in building base reactions and the compensation for water and such could be pre-calculated. Using such a spreadsheet it could determined how much can be added to the batch each time to work up to the maximum "safe" volume that the reactor will hold during reaction without boiling over. This will also allow for the cross sectional area of the Si rock to be better treated as we expand the reactions, due to graduated increases. Large volume increases above the recommended increase is not recommended. The rock will over react or under react and the resulting "cross-sectional" areas of the rock will become imbalanced. Once they are radically out of balance the only means to get them back in balance is to start the "base building" process from the beginning. Taking care to scatter the reacted rock into the reactor gradually or wait until the 4000 pound base has been established to introduce the "damaged" rock.
 After extensive experimentation, correct post reaction values and a theoretic use for predicting reactions was developed. The correct number is 12.6758% of the remaining base rock where all other variables have been made constant (heat temperature, pressure, time in reaction, size of rock, and application and mixture procedure for all reagents).
 When preparing the start up rock for a reactor it becomes necessary to weigh after each reaction for the first four reactions to be assured that the weight to add is correct and in the "window". In the early reactions the margin for error is almost nil.
 Initial reactions were performed with 100 pounds in the bottom of the reactor. The NaOH was carried inside the vessel by hand. By trial and error it was learned that in successive reactions one can only increase the amount of base by a maximum of 25.3516 percent of the original weight of the start up base or in this case the next reaction would be for 138.0274 pounds of Si rock or an addition of 50.7032 pounds of rock. The base reaction will yield about one drum of 1.3 gravity material per each sixty two pounds of reacted silicon rock. The 138.0274 reaction would yield 17.4960 reacted pounds or less than 1/3 of a drum of material.
 The next reaction would be 173.0196 pounds. The subsequent ones would reflect a gradual growth of the base.
 Accuracy is critical in all phases until the base rock is over 4000 pounds or until the rock has reached its own "balance" and the "sawed" surface or "worm hole" effect; can be seen easily.
 Past 4000 pounds the weight can be determined at 12.6 pounds without fear of "falling" from the window. The other ratios are still carefully controlled to the fourth decimal place.
 At 6000 pounds of base rock the "window" seems to "stabilize" and amounts as high as 14% and as low as 11% percent by weight seem to find a correct "window". The finished material is simply a little more silicon rich. The weight of Si (silicon) can vary from 60 pounds per 55 gallon drum to 68 pounds per 55 gallon drum at 1.3 gravity. Below sixty pounds is always sodium silicate or sodium silicate and unstable, inferior silicon solution. Above 68 pounds is a ceramic like material that is very dense and friable and is very unstable. Using up 50% of the existing rock in an reaction is impossible. Further prolonged use of too much silicon will build large amounts of residual NaOH on the rock and a "blue" or super hot reaction can occur which leaves a very blue colored solution that will dry to a ceramic consistence if left in the air to dry.
 The broader "window" allows for a circumstance where a less-than full compliment of Si could be used as long as the variance is noted and compensation is done on the next reaction to re-stabilize the base. The last of a batch of silicon or a shutdown circumstance might require such a decision.
 Regular and sustained use of the base rock seems to show that only the "new rock" or added rock, gets reacted and the base rock seems to be unchanged except for the "saw" effect and some "worm hole" effects. This is usually easily seen on the level of the rock in the vessel. When running standard reactions the volumes will soon all look very much the same.
 At 8000 pounds the "freedom" window is expanded and the full "window" of the reaction can be run and there seems to be no ill effect of additional water except to prolong the time of the reaction start up. This explains why heavy rains destroyed earlier reactions but have almost no effect on the current ones. One thousand and eight pounds of "new" Si rock added to this base yields 16.25 barrels of 1.3 gravity concentrate.
 Clearly this method requires a lot of work and care to get to the base state. However this does not explain why a diligent person weighing each load and gradually adding "empirical" amounts will not eventually get to this "stable" state. There are several reasons for this but the most glaring is the temperature of the reaction at initial reaction.
 A correct reaction started after a off load cool down will always start too fast if the presentation of the chemicals is done in the wrong order. Also, it was long believed that the base rock could not be fully covered with water for a "proper" reaction to occur. In fact, the opposite is true. The rock must be fully covered with water before any new base (NaOH) is induced.
 Since the rock is often moved around and stacked by the preceding reaction the adding of the initial water should be over the top of the vessel and done by hand to fully wash down the base rock and wash off the dust from the new rock. The NaOH should be added from the bottom of the vessel through the primary drain valve. Then the last of the water should be added from the bottom through the same hoses to purge all the NaOH and clear the bottom of the NaOH (this is critical). Very soon a distinctive figure eight movement of the water and NaOH can be seen in a "rolling" motion in the bottom of the vessel.
 Top loads or loads in different order do not produce the distinctive figure eight reaction and often result in low stability, inferior silicon solutions or worse. The three most important parameters of the method are: 1. The preparation of the rock.] 2. Scrupulous attention to the 12.657% reaction maximum (especially in the beginning of base rock preparation) 3. Loading parameters (load it in the wrong sequence and it will fail) The following parameters are also relevant.
 There is no definitive mechanism for knowing the reaction is complete except to let it go to term. This is the state where either "blobs" or "lily pads" of very thick material appear on the surface or when the top is covered with a soft looking silver cover of very thick material. This occurs in a normal reaction in about 14 hours.
 Reactions have been off loaded at 10 hours with success and reactions have been off loaded at 12 hours and failed. These disparities might be due to a late starting reaction. The use of hot water in the winter helps but is unnecessary in temperatures above 50 degrees. A good rule of thumb is the condition of the 50% by volume NaOH. If it is frozen, about 48 degrees F., it is a good time to use hot water or allow more time for reaction. At times it may take as much as two additional hours.
 One should use about ten barrels of fresh water to circulate out of the bottom of the vessel and over the top. Again this should be done by hand and the "lily pads" should be targeted. The tank should not be off loaded until there is a homogenous material at around 1.35 gravity at near room temperature. Too much water will drop the material below the commercial level of 1.25 specific gravity. This material can be used as blend stock on the next reaction.
 The material should not be off loaded directly to barrels for shipment or into light resistant tanks. It will remove the lining of even chemical lined barrels. It will hydrogen im-brittle plastic barrels and have the same effect on a long term basis on metal ones. Allow the Si solution to settle and cool and get some sun or UV rays to improve its stability characteristics. The amber color of the material comes from the exposure to light. It may be related to the iron residual in the silicon metal since it doesn't occur in the high purity material.
 Plastic storage tanks are light and easy to move and handle and allow the sun to access the material. Fines or other sediments will accumulate in these tanks. A 1% additional correction for a standard reaction of the new silicon metal on every fifth reaction compensates for the fines that are lost. One should never add fines to the reaction to try to "start it". This starts a vertical or non-figure eight, reaction and as such it will fail, if not that time it will fail in subsequent reactions.
 After about every fifty reactions the reactor should be cleared of all base rock and the remainder of the rock allowed one day to dry. It may turn white, this is of no consequence. It should then be weighed and returned to the reactor. Any maintenance to the tank or valves and such should be done at this time. There may be significant iron or black looking material in the bottom of the tank. It is of no use and should be removed. It is iron silicate and is land fill allowed. It would not be more than ten of twenty pounds but it can cause reaction troubles and is unsightly at best.
 The size of the rock is important. When building the base of a new reactor the early reactions should be limited to material no greater in diameter than one inch. As the base is built the size can increase to two inches for 1000 pounds of base up to two thousand pounds. From two to four use a maximum of four inch. For four and above the six inch maximum rocks, which is the optimum price, is ok to use. However, a good mixture of smaller sizes is advisable until the base has had at least three reactions.
 The reactions will reaction differently under different barometric and weather conditions. In wet low pressure conditions the risk of boil over is greater. In dry cold and high pressure conditions the risk is less great.
 Expect the boiling volume to be from three to five times the level of the mixture at pre-reaction. If you react the material over night there will be a ring around the top of the vessel indicating how high the reaction reached in the vessel. The use of a top is dangerous since it could cause an explosion or pressure valves to blow off.
 The pH of the as reacted material is 13-14. However, this pH is not truly indicative of the reactivity of the material. Ordinarily, 13+pH material would be radically corrosive and extremely dangerous to have come in contact with your skin. The stable material is neither. The stability is also reflected in more than shelf life. Of course shelf life is important, but stability with reactions with other chemicals is important also.
 Some anionic materials with very low pH such as acids will react violently with the material. Of course the material has a very valuable use for neutralizing acids in spills and industrial processes. Sodium hydroxide is commonly used in these cases and is very dangerous to handle, ship, and store. Hydroxide burns are far worse to treat and recover from than acid and temperature induced burns. The silicon material is only dangerous during the first two hours of the reaction. During that time it will burn you from the near 400 degree temperature and from the highly reactive and caustic base that is part of the early and intermediate stages. This is the time of the reaction that care should be exercised the most.
 When the material settles down and just slowly bubbles and or "rolls" it becomes progressively less and less dangerous. At the end it is just hot to the touch and until it; is diluted it should be avoided. It is over 180 degrees F. and it holds the temperature for an inordinately long time. Left un-diluted the reactor can be hot for several days.
 When the reactor is to be shut down, water should be put on top of the silicon rock to assure no exposure to the air. Leaving the rock covered for several days is not harmful to the base. The water should be drained off and used as dilution material. It is not recommended to use it as start up water for the type one reaction since it will likely over react.
 With new base or rock and a new vessel and a first reaction it will go pretty much as follows.
 The start is as described before. It will get progressively more violent and begin to turn the effluent in an up the side back to the middle and then repeat the process very rapidly that we call "FIG. 8". In a very stable reaction this may take no longer than a couple of hours to begin to foam on the top with some blue-fines in the foam and the gradual building of a "dome" or bubble dome as it is called by some.
 If this "dome" makes it over the top of the vessel the reaction will shoot up the side and then collapse and fail to a "white or a "blue" reaction. Both are bad and to be avoided.
 In the passage of a couple of hours the reaction will begin to subside and the dome will collapse to a boiling and turning reaction that is center specific. The outsides will begin to "crust up" or form fine and bubble barriers that may grow to cover the entire reaction. This is a sure sign of a very heavy and excellent reaction. This process may splinter and form what we call "lily pads" which are named because that is what they look like on top of the reactor. They are also a good sign but neither is necessary for a successful reaction but time is.
 Allow the reaction the full 12.5 hours required. The errors are not always obvious and as a result we advise to err to the secure. Run, the full time. The preferred reaction time is 14 hours with the only ill effects being a loss of water and difficulty extracting the material. The phase one material may also be used to dilute the hot material for extraction.
 The off load is important and failure to off load can lead to the material drying into the rock and it takes days to get it out with endless washing and circulation. The material must be removed hot and quickly.
 The settling process begins in the first storage tank and it is designed to allow fines to settle out and commencement to proper dilution from the 1.3 to 1.35 gravity down to 1.25, the commercial goal. Gravity and time do the work with water as the diluents and the tank quickly settles and in 2 to four days should be moved to the next tank.
 We often circulate this tank and it is located where it is exposed to sun light. The sun is part of the equation. Move the phase one material to a dark tank and it will never change color and will continue to bubble hydrogen that can cause vessels to swell or burst. Settling tanks are always open topped.
 Ten days in the settling tank or sun tank and the material is ready to go to the bulk tank and can be stored indefinitely and or put into drums. We have stored material in the bulk tank a year and had no change in pH, gravity or color. The preferred material for bulk tanks is plastic. Over a period of time the fines from the settling process will accumulate in the tanks. The fines should be removed periodically and they make good road grade material.
 After the reaction process, water is used to wash the rock clear and put that water back into a smaller holding tank after a couple of hours of circulation and cooling the rock. This water may be used to dilute heavy reaction material when "Phase I" material is not readily available. It works almost as well but care needs to be exercised to not over dilute. Material dropped to 1.15 can be very hard to raise back to 1.25 gravity even with new heavy reacted material. It happens but slowly and with much circulation required.
 In summary, the process of producing the silicon material involves a group of variables that all must be completed in a timed and often sequential order to produce stable silicon material.
 First, the vessel must be of a size, design, material, and of construction suitable for proper exothermic reactions. That means a vessel that will withstand the heat generated by the reaction and the potential for hydrogen embrittlement. Nickel and nickel alloys have proven satisfactory. The vessel needs to have a coned bottom to assist in avoidance of "offset" or "crevice" related reactions that can become too hot or too reactive. The rolling reaction that is seen in start up and during successful reactions that we call "figure eight" will often not occur in flat bottomed vessels or vessels with areas where crevices can cause different reactions characteristics.
 The vessel must be open at the top and valved at the bottom for water and chemical introduction into the vessel and for the off load mechanism after the finished reaction.
 The base rock, or the amount of rock that is in the vessel prior to an initial reaction is a critical variable. When first beginning to "build" this "base" of silicon metal extreme care must be exercised to be exactly in the 1-6-10 molar calculation window, however one should note that this early reaction product may not be the "stable" material that will result once the "base" metal (rock) has been fully established. Removal of all the product of the first few reactions is advised if there is no "base" or catalyst rock available as would be the case in a new start up reactor. The base rock will get a "worm hole" or sawed appearance as if the surface of the lump of metal or rock had been first sawed a few millimeters deep with a band saw. This is a good sign and the "rock" will often be white from excess sodium and this is an expected condition also.
 When the gradual reaction and removal rates increase as described above have been done and the base rock reaches 4,000 pounds, then the very tight restrictions (done to the gram) on the control of the rock added is less needed. What has to be determined is how much rock can be reacted and still have the reaction not go over the top of the open topped vessel. The preferred method is increase the base rock gradually, realizing that the actual proper reaction will be in the 12.6758% window, and a residual weight can be calculated for the proper addition for the next reaction.
 Any new amount may be added to the base to establish a new base number but the resulting ratio and molar calculation of water and NaOH may yield a reaction that may not stay in the vessel. So raising the total base gradually from reaction to reaction is empirical and based on how high the reaction mixture expands during the reaction and still stays in the vessel. Totals that allow for a growth of the reaction to within one foot of the top of the vessel at maximum reaction is desired. Any more risks over flow and loss of the reaction and damage to the vessel.
 The next parts of the process are equally critical. The loading of the chemical and the new rock for the next reaction. Loading the chemical over the top of the vessel will cause what we call an inverted reaction and can and often does fail. Thus, loading the NaOH from the bottom is critical to our method. Using the last of the water to purge the process and loading lines also forces the heavier NaOH into the center of the catalyst rock base and the reaction starts in the middle of the vessel and rolls figure eight outward.
 The reaction will be very violent for the first four hours with rolling and boiling and production of "very wet" steam that is hydrogen rich. The last eight hours the dome of the reaction will subside and the material may cover with a dark shell or have a floating material that is mostly silicon metal fines that we call lily pads.
 If the reaction is not blended with other material and water before these lily pads and of the cover material becomes very dry, the removal of the finished product is very difficult. We use previously produced material to unstop the valves and to circulate the material in a cooling process before we off load the material for blending with water or other lower than 1.25 material. We circulate the mixtures bottom to top over the sides of the vessel and add water and take specific gravity readings until we are at 1.35-1.38 specific gravity at the current temperature. That varies with the seasons but in the summer that is about 135 degrees F. We circulate the mixture to around 90 degrees F. and the off load it into the primary blending tank.
 The blending tanks allow light to pass into them readily since exposure to light and or sunlight is part of the final process for a stable material. When the product is not exposed to light the product stays a blue color and often continues to react, sometimes expanding and damaging the tank.
 From the primary blend tank the material is circulated and blended with water for a minimum of two hours and then allowed to settle for two days. We then move all the material into the secondary tank less 800 gallons that we retain for off loading assistance and stabilizing of the next reaction.
 In tanks two and three we circulate the materials from subsequent reactions and allow the material to gradually change color to a light amber. This is a product of settling out of silicon fines from the process but is also a product of exposure to the sun.
 Final water is added and circulated extensively to make the material exactly 1.25 gravity.
The Chemical Composition of the Silicon Solution
 The formula of the silicon solution appears to be as follows: Na══O══[Si+O+H]6+H2O This formula suggests a large degree of potential at the double bonded oxygen. It seems likely that thiophene, formulin, and several other chemicals and compounds may have a strong tendency to attach to the strong double oxygen bond. Numerous new structures may be created in this manner. These materials may have plastic like properties but would be non-petroleum based. These materials may exhibit extremely high strength to weight ratios and be biodegradable. Production of Silicon Foam
 The silicon solutions of the present invention can be heated to produce a silicon foam. We have found that heating the solutions to about 500° F. creates a very white foam. The resultant foam material is stable and has properties that make it ideal for many fire resistant and insulation applications.
 The foam exhibits high strength to weight ratio and fire proofing properties that makes it ideal for use in food galleys on commercial aircraft. The foam also exhibits excellent insulation properties at both extreme high and low temperatures that make it ideal for applications such as in process plants where the pipes transfer very hot and very cold effluents. The foam can also be used for steel insulation on high rise buildings. The foam can also be used as an insulation, fire proofing, and sound proofing all-in-one material. This will offer a huge reduction in construction and energy costs as well as greatly increase the amount of floor space available through space savings of using one material to do the job of three materials. Other applications include fire proof and fire resistant materials such as the following: doors, walls for high rise constructions, home construction materials, packaging materials, pads for carpets, mattresses, and motor homes.
Production of Silicon Glass
 The silicon foam can be further heated to produce a silicon glass. We have found that heating the foam to its melting point of about 1065° C. creates a silicon glass. Upon cooling, the glass forms into an amorphous state: but with addition of select ions it will crystallize into an octahedral quartz-like material that has gemstone qualities. The silicon glass is very stable and does not hydrolyze like common sodium silicate "water glass". The resultant glass has unique properties that make it ideal for uses in laser gems and encapsulation of nuclear and hazardous biological wastes. The glass also exhibits a high strength to weight ratio that makes it ideal for high strength glass applications. Other applications include the following: fine glass fiber non-flammable insulation material, fiber optics with unique optical properties, and cut and colored glass.
 One special type of glass can be made by performing the above process using a starting material of very low iron content. The resultant solution formed by the above process is what we call "high purity." The addition of metalized ions to the solution before it is heated to a foam and then a glass, causes color changes similar to that of common glass but unique. In most glass, copper for example makes a blue-green color. In our high purity glass, copper makes a reddish purple color. The addition of gold makes a bright pink color. Gold makes no known color in common glass.
 We have performed extensive tests with the high purity material and cerium oxide. Through these tests, we have formed beautiful green stones. We had the stones tested by a gemologist in a light refractory machine. The stone was very bright and lustrous, the machine said it should be a dark opal or about "4" on the scale of 1 to 10 with a diamond being a 10. The stones also exhibited a hardness of 8.5. The stones were easily cut and polished to high luster and was much less dense compared to heavier zirconium stones.
Properties of the Silicon Solutions
 The silicon solutions of the present invention are stable, aqueous high ratio SiO2:Na2O solutions that effect separation of many organic contaminates from most surfaces. Since the ratio is high (3.4-3.8:1), very little emulsification takes place. Most "cleaning" is due to a separation of grease and grime from its attached surface.
 We believe the excellent cleaning ability of the silicates is due to their ability to pass their negative charge to all entities they contact. Since like negative charges repel one another, the contamination will be repelled from whatever surface it is attached.
 The presence of the silicates will also aid in the prevention of the contaminate from re-depositing on a surface. This is an advantage over common sodium metasilicates which tend to emulsify rather than separate and have minimal re-deposition prevention properties.
Applications of Silicon Solutions
 The liquid material is ready for use when the manufacturing is complete. For most uses, simply dilute the aqueous silicon solution with water and use.
 The liquid solution in ready-to-use form has a high pH yet does not have the typical harmful effects or risks associated with higher pH cleaning compounds. The aqueous solutions of silicon in accordance with the present invention are very safe, non-volatile, and easy to handle. Moreover, the solutions of the instant invention separate petroleum compounds from parts being cleaned to a recoverable and reusable product, essentially restoring its value as "waste oil". Further, the solutions of the instant invention have a far longer life cycle due to totally separating and isolating waste products from not only the parts being cleaned but also itself, enabling continued usage. Because of this separating and isolating, the solutions of the present invention have no negative environmental impact, and no waste-water/effluent issues. Additionally, most known cleaning solutions near the end of their life cycle clean only marginally, leaving unacceptable dirty parts. The solutions of the present invention do not experience this performance drop-off.
 Cleaning method using solutions in accordance with the instant invention include, but are not limited to the following: cleaning aromatic sludge tanks (specifically benzene, but also applicable to toluene, xylene, and other type tanks), pits (oil and sludge) and other waste clean up including barges, railcars, rig wash, slop oil recovery including coal slurry pond clean up, gun barrel separator clean up, pipeline cleaning ("Pig" operations) including pipeline "Sock type" filter cleaners, pipeline right of way clean up, site, pad, and staging area clean up and remediation, parts washing, computer circuit board washing, steam cleaning, soil washing, carpet cleaning, carpet cleaning and flea treatment, upholstery cleaning, and cleaning concrete. Typically, for cleaning and washing applications the stable, aqueous silicon solution of the present invention should be diluted with water to provide a cleaning solution that is 1-2% Si solution.
 The solutions of the instant invention can by used in accordance with known methods of washing and cleaning. For example, highly aromatic solvents often are absorbed into the matrix of carbon steel tanks. A tank containing such a solvent can be emptied and repeatedly washed with soap and common detergents and then allowed to air dry for weeks or even months. The so called clean tank is still a danger for possible explosions and many have been killed in such accidents. Take the tank and heat it with the lid on with a torch and it will explode as soon as the torch cuts into the tank. Wash the tank with the silicon material of the instant invention and all the solvent will be removed and the risk of explosion is gone.
 The solutions of the instant invention will clean surfaces that have been contaminated with hydrocarbons. For example, metal parts used in conjunction with oil drilling and pumping are often coated with oil as they are being used. Such parts can be rinsed or washed with the solutions of the instant invention which will remove the oil contamination. These parts may also be submerged in solutions of the instant invention to achieve a similar effect. Moreover, the solution will separate the hydrocarbon from the parts which can then be recovered restoring its value as waste oil.
 The solutions of the instant invention are also useful in methods of cleaning metal surfaces. Simply use the solution as you would any other soap or detergent for superior cleaning results. For example, fast food restaurants use grease in the production or cooking of many of their products. The solutions of the instant invention can be used to clean any of the metal surfaces that get coated or contaminate with this grease. The solutions of the instant invention offer a superior alternative to the cleaning products that are currently available as they are more effective and economical.
 Generally, any product or method that is currently using a water soluble base to do a job can likely do the same job cheaper and without the adverse environmental impact using the solutions of the instant invention.
 For example, sodium hydroxide is currently used by airlines to treat their process water at airports because the water is highly acidic and cannot be put into common sewers. Sodium hydroxide is costly and dangerous to use handle and store. A solution in accordance with the instant invention is much less dangerous to handle and use, is significantly cheaper and is equally effective in such treatment methods.
 Energy companies have the same problem caused by the acid they use to clean their primary burners at lignite coal plants. They use sodium hydroxide in their treatment methods. A solution in accordance with the instant invention is much less dangerous to handle and use, is significantly cheaper and is equally effective in such treatment methods document after the trip.
 Another embodiment of the present invention is for improved methods of oil recovery. The solutions of the present invention can be substituted for water in the process of water flooding oil reserves. The solutions should generally be between about 0.5% and about 5% aqueous stable silicon solutions made by the process of the present invention. The unique properties of the silicon solutions cause a greater amount of oil to be dislodged by the solutions compared to water. In this manner, the percentage of oil that can be recovered from known oil wells is greatly increased.
The Preparation of the Stable, Aqueous Silicon Solution ERA-3
 The stable, aqueous silicon solution ERA-3 was produced as follows:
 a vessel having cone shaped bottom and containing commercially available base rock (approximately 97% pure) was provided;
 water was place into the tank in such a manner as to provide intimate contact with the rock; NaOH solution was gradually added to the rock and water through the bottom of the vessel, thereby forming a reaction mixture; the reaction was allowed to run; the still hot solution was offloaded to a settling tank and the solution was allowed to settle; the solution was moved to a second settling tank for clays and then moved the to a bulk storage tank, which was open to sun light. The ratio of NaOH to silicon to water was 1:6:10. The resulting solution stable, aqueous, silicon solution, ERA-3, has been shown to have a SiO2:Na2O ratio of 3.94:1. ERA-3 has also been shown to be significantly less corrosive than silicon solutions made by other known methods.
Comparison of Oil and Sand Separation Properties of ERA-3 to Another Commercially Available Product
 ERA-3, a stable, aqueous silicon solution produced in accordance with the instant invention and having a SiO2:Na2O ratio of 3.94:1 was compared to the commercially available solution sodium disilicate solution PQ "N", which has a SiO2:Na2O ratio of 3.33:1.
 Equipment and materials used were as follows:
 Syracuse tap water at 55° C.
 Disposable 800 ml polypropylene sample beakers
 A 1500 ml container set on a hot plate, for use as a constant temperature water bath.
 An adjustable ring clamp
 A Gerald Heller Co. type 150, 1/60 horsepower DC motor with variable speed control fitted with two mixing blades.
 Kolorscope white playsand
 SAE ND 30 motor oil
 PQ "N"
 Analyses were performed by Environmental Lab Services, North Syracuse, a New York State Department of Health certified analytical laboratory, according to the current EPA procedure for oil and grease analyses, solvent extraction technique.
 The procedure was as follows:
 1. 188 grams of sand were weighed into an 800 ml beaker, 15 grams of oil were added and mixed well with a stainless steel spatula to a uniform appearance.
 2. 600 ml of water at 55° C. were placed in the 1500 mil water bath.
 3. 455 grams of tap water at 55° C. were placed in an 800 ml polypropylene beaker, the beaker was clamped and immersed in the 1500 ml container, cocked as much as possible for adequate mixing, by means of the clamp fastened to the ringstand.
 4. The mixer was lowered into the water and adjusted such that the blades did not quite touch the bottom or sides of the beaker.
 5. The sand-oil mixture was added over the course of 1-2 minutes and mixing was continued for 25 additional minutes.
 6. The mixer was then stopped and lifted out of the sample beaker.
 7. The sample beaker was removed from the water bath container. Three layers quickly formed: sand on the bottom, oil on the top, and an intermediate layer consisting mostly of water and what appeared to be very finely dispersed solids.
 8. The oil layer was decanted and discarded. The intermediate layer was poured off into a separatory funnel and allowed to stand for 30 minutes.
 9. The remaining sand layer was jolted gently several times to free up more liquid, decanted and sampled for analysis. A sample was taken from the interior of the sand mass so as to avoid including oil that was clinging to the sides of the beaker.
 10. After 30 minutes of standing, the solids that had settled to the bottom of the separatory funnel were discarded, the water layer portion was collected as a sample for analysis and the floating oil layer was also discarded.
 Using the above procedure, a test was run using sand, oil and tap water. Analyses showed 5600 mg/Kg residual oil in the sand and 830 mg/L oil in the intermediate layer. The test was repeated using 1% by weight ERA-3 solution in tap water. Analysis showed 330 mg/Kg residual oil in the sand and 260 mg/L oil in the intermediate layer.
 The oil-sand quantities were now increased to allow for sampling so that analysis could confirm the oil content of the initial oil-sand mixture prior to treatment. Thus, 231.8 grams of sand were blended with 20.2 grams of oil and 50 grams of the resulting mixture were taken for a "blank" analysis.
 Again using the above procedure, test were run using tap water and the solutions PQ "N" and ERA-3, both at 1% by weight. Results are shown in TABLE 1.
TABLE-US-00001 TABLE 1 Water PQ"N" ERA-3 Residual oil in sand, 3400 3800 2300 mg/Kg Residual oil in liquid, 570 90 320 mg/L
 Given the above results, ERA-3 has been shown to be superior to PQ''N'' in terms of recovering oil form sand. This Example further evidences the usefulness of the solutions of the instant invention for extracting oil from tar sands.
Oil Recovery Potential
 Tests were performed to determine the oil recovery potential of the silicon solutions of the present invention. The tests were carried out in a flotation cell in a process modeled after actual water flooding used for bitumen recovery from the Athabaska tar sands. The tests were carried out in a 1-liter Denver flotation cell. 300 g of Aurora transition oil sand ore* was dispersed with 950 ml of 1.5% aqueous silicon solution at 50° C. under agitation of 1500 rpm. After slurry was conditioned for 5 minutes, the aeration was started. The bitumen froth was then collected for 15 minutes. The collected sample was then assayed. For the purpose of comparison, the same procedure was taken for a flotation using de-ionized (DI) water and tap water. TABLE 2 shows the results of the test.
TABLE-US-00002 TABLE 2 Tests Recovery Grade Bitumen/Solid 1.5% Silicon solution 78 21 2.1 DI water 92 8 0.5 Tap water 93 6.6 0.6 Tests Recovery Grade Bitumen/Solid 1.5% Silicon solution 78 21 2.1 DI water 92 8 0.5 Tap water 93 6.6 0.6 *Grade of Aurora transition oil sand ore is 9.2%.
 The results clearly show that the ratio of bitumen to solid was between three to four times higher with the silicon solution of the present invention compared to water. Accordingly, the use of the silicon solutions causes improved separation between the bitumen and tar sands. Thus, the quality of the bitumen recovered from the tar sands is much higher than that recovered by traditional water flooding.
Paraffin Removal and Reuse to Simulate Oil Well Fracture
 A 1.5% silicon solution in accordance with the instant invention is heated to 180° F. is circulated within an oil well bore. The solution flow is a closed loop system consisting of the heated fluid, storage/separation tank, circulating pumps, and necessary piping to well head connections. Individual oil well design, including tubing, pump and packer arrangement will determine fluid flow path configuration. Circulating heated solutions in accordance with the instant invention will cause separation of paraffin for the interior surfaces of the well bore and tubing. The removed paraffin within the flow stream will be deposited in the heated separation tank by physical separation and float to the water surface for collection. The circulation process should be continued until the return fluid runs clear denoting that there is no longer paraffin present in the flow stream. With the circulation pump off, the paraffin can be removed from the separation tank for disposal leaving only the ERA-3 solution. This solution is then pumped with return line closed, down the well bore forcing it into the fracture simulating the loosening of debris that may be inhibiting the crude oil from flowing into the well bore for collection and pumping to the surface. The well is shut for 24 hours. The well is then placed back into operation and pumped continuously to remove water, oil, and debris that are liberated by the solution of the instant invention.
Bitumen Extraction from Oil Sands
 Solutions in accordance with the instant invention were tested and evaluated for their performance on bitumen extraction from low grade (8.2% bitumen) oil sands using the Syncrude style BEU. The tests showed a marked improvement on bitumen recovery and bitumen froth quality, as compared with blank tests without process aids. All additives increased the total recovery.
 4 solutions in accordance with the instant invention were evaluated for the surface extraction of bitumen from an oil sand that did not achieve predicted recovery. The solutions, labeled 1:1, 2:1, 3:1, and 4:1 were produced by methods as disclosed herein. The oil sand was from a mine in Fort McMurray, with an ore grade of 8.2% bitumen. The amount of solution added was kept at a level of 1% in the process water.
 Lab scale assessment of oil sands processability is generally dependent on methodology, the type and size of apparatuses used. With the evolution of oil sands extraction technologies, different lab scale testing techniques have also been created in the Alberta oil sands industry, in an attempt to select one which is sensitive enough to detect small changes in operation variables. It has been recognized that for a specific oil sand the extraction variables could fall within an appropriate four-dimensional space of chemistry, mechanical energy, hydrodynamics, and temperature. To evaluate the solutions in accordance with the instant invention, testing was done using the standard Syncrude style Batch Extraction Unit (BEU) with testing temperature controlled at 55° C.
 Syncrude style BEU tests were performed as follows:
 1. Remove homogenized oil sand from freezer and allow to thaw and reach room temperature.
 2. Set heating bath to 50° C. and circulate through BEU heating jacket.
 3. Prepare a 4 liter mixture of 85% toluene/15% IPA (toluene/IPA mix).
 4. Heat approximately 2000 ml Edmonton tap water to ˜58° C.
 5. Transfer 110 ml-heated water to the BEU unit.
 6. Weigh 500 g of oil sand to nearest 0.1 g and add to water in BEU.
 7. Turn motor on to 600 rpm, raising and lowering motor and impeller assembly to break any lumps if necessary, leaving impeller at the set position (20 mm for the bottom of the pot).
 8. Turn on air to 420 ml/min.
 9. Start timer for 10 minutes.
 10. When complete turn off air and flood the mixture with 800 ml of heated water.
 11. Mix for 10 minutes at 600 rpm--no air.
 12. When complete skim off primary froth into a pre-weighed bottle using a flat edged spatula, cleaning the spatula and BEU surface with a pre-weighed tissue, which is placed in the froth bottle and weighed. Submit froth sample for Dean Stark Analysis (include tissue weight to be removed from solids weight).
 13. Mix the remaining material for 5 minutes at 780 rpm with air addition of 234 ml/min.
 14. When complete, skim off secondary froth in the same manner as the primary froth and submit sample for Dean Stark analysis.
 15. Place pre-weighed 2-liter jar under BEU and turn impeller on. Take out bottom-plug of BEU, turn impeller off and allow mixture to drain into jar (occasionally starting and stopping the impeller during this procedure allows the solids to mix better and flow out). Raise impeller and scrape as much sample as possible into the jar. Remove jar and retain for analysis if required.
 16. Place a pre-weighed 250 ml jar under the BEU.
 17. Lower the impeller and slowly stir.
 18. While washing with toluene/IPA mix slowly raise the impeller to just below the top of BEU and stop motor.
 19. Raise the motor and impeller.
 20. Wash pot and impeller with toluene/IPA mix, collecting residuals in jar. Wipe with a pre-weighed tissue and place in jar. Submit toluene wash for analysis (bitumen weight to be combined with primary froth weight).
 21. Put bottom plug back in place.
 22. Turn off air and heating bath.
The Results were as Follows:
 BEU Recovery Calculations are as Follows:
Primary recovery: ((wt of bitumen in primary froth+wt of bitumen in toluene wash)/(wt of oil and sand used*% bitumen in oil and sand*0.01))*100
Secondary recovery: (wt of bitumen in secondary froth/(wt of oil and sand used*(% bitumen in oil sand*0.01))*100
Total recovery: primary recovery+secondary recovery
Scavenging efficiency: (secondary recovery*100)/(100-primary recovery)
Primary froth quality: % bitumen in primary froth
Secondary froth quality: % bitumen in secondary froth
Total froth quality: (wt of bitumen in primary froth+wt of bitumen in secondary froth)*100/(wt of primary froth+wt of secondary froth)
 Froth quality can also be calculated as bitumen/solids ratio
TABLE 3 Shows the Batch Extraction Recovery Data.
TABLE-US-00003  TABLE 3 Sample ID Control 2 3 5 (H2O) Run 55 55 55 55 temperature, C. Primary 77.49 73.02 72.99 24.27 Recovery % PF Quality, % 63.91 60.66 58.00 26.56 Bitumen PF Quality, % 10.74 11.95 12.33 10.44 Solids PF Quality, % 23.62 25.40 27.76 63.76 Water Secondary 3.42 7.33 8.48 31.07 Recovery % SF Quality, % 20.06 41.78 38.09 24.05 Bitumen SF Quality, % 8.60 16.30 13.83 27.84 Solids SF Quality, % 73.07 43.45 49.73 47.43 Water Scavenging 15.20 27.18 31.41 41.03 Efficiency % Total Bitumen 80.91 80.35 81.47 55.34 Recovery % Bit/Solids PF 5.95 5.08 4.70 2.54 Bit/Solids SF 2.33 2.56 2.75 0.86 Chemical 2:1 3:1 4:1 0 Added (1% in water) Oil Sand Analysis Bitumen % 8.18 8.18 8.18 8.18 Solids % 84.57 84.57 84.57 84.57 Water % 7.26 7.26 7.26 7.26 Wt. Bitumen 40.91 40.91 40.91 40.91 in 500 g ore
 FIG. 1 shows the bitumen recovery using Syncrude style BEU with four solutions in accordance with the instant invention. For all solutions, a significant increase in bitumen recovery was achieved as compared with no chemical addition. As such, the solutions in accordance with the instant invention can function to enhance bitumen liberation from sand grains; reduce multivalent cations in slurry; reduce slurry viscosity; enhance bitumen-bubble attachment from increased total ia/liquid interfacial area.
 FIG. 2 shows the bitumen froth quality as defined by bitumen/solids ratio in the froth. A higher bitumen/solids ratio generally gives a better bitumen froth quality. For these BEU tests, adding solutions in accordance with the instant invention dramatically increased the bitumen/solids ratio for both primary and secondary froths. Improved bitumen froth quality using BEU with solutions in accordance with the instant invention indicates that the solutions enhanced liberation of bitumen from sand grains.
 A 2% solution of ERA-3 was contacted with metal parts that were contaminated with oil. The ERA-3 and parts were agitated, thereby removing the oil. The ERA-3 solution was then used in subsequent parts washing procedures without loss of its effectiveness as a cleaning agent.
 A quantity of sand was impregnated with dyed oil. FIG. 3 shows Sample 1, comprising sand impregnated with dyed oil. Sample 1 was then washed with ERA-3. FIG. 4 shows Sample 1 after it has been washed with ERA-3. Note that the sand appears substantially free of oil. A second sample of sand impregnated with dyed oil, Sample 2, was then provided, as shown in FIG. 5. Sample 2 was then washed with the same ERA-3 that was used to wash Sample 1. FIG. 6 shows that Sample 2 is substantially free of oil after washing with the recycled ERA-3. FIG. 7 shows a comparison of each of Samples 1 and 2, both pre and post washing with ERA-3. Given these results, it is clear that solutions in accordance with the instant invention are reusable.
 ERA-3 was used in a method of removing oil from samples of tar sands. The results illustrate the usefulness solutions of the instant invention in methods of removing oil from tar sands as well as the reusability of silicon solutions of the present invention. The concentration of bitumen in the first tar sand sample was 95000 mg/kg. The first tar sand sample was washed with a 1% solution of ERA-3. The concentration of bitumen in the tar sand sample after the wash was 67000 mg/kg. A second sample of tar sand having a bitumen concentration of 9500 mg/kg was then washed with the same ERA-3 solution that was used to wash the first sample. The concentration of bitumen in the second tar sand sample after washing with the same solution used to wash the first sample was 50000 mg/kg. These results show that solutions in accordance with the instant invention can be re-used in methods of extracting oil from tar sands.
 We are in the process of several developments based on the silicon solutions that may become the subject matter of future related patent applications, these developments include the following:
 1. Development of Gemstone Technology
 We have made, cut, and polished very attractive stones from heating the silicon solution. However, larger and more powerful furnaces are needed to further develop this work. Most of the "stones" we are interested in are in the melting range of around 1300+° C. We estimate that temperatures as high as 1500° C. will be needed to produce emeralds. We are especially interested in using beryl and beryllium because aluminum beryllosilicate (A12[Be3Si6O18]) is the chemical structure for the primary structure in emeralds, and beryl and certain forms of beryllium are very useful in suppressing the movements of neutrons and as such are integral within the nuclear energy business. Beryllium based shields are used as "deflectors" when neutron bombardment would be detrimental or even dangerous. This may be particularly useful in space based weaponry.
 Similarly, beryllium is one third the weight of aluminum and has enormous strength to weight ratios. Beryl, which is somewhat common, might also be converted to beryllium by a high temperature reduction mechanism. This would provide a readily available form of beryllium that is as rare as arsenic, in nature. We also contemplate making a beryllium and silicon coating by electrodeposition that might eliminate corrosion. We have strong reason to believe that we can reduce the beryl crystals and make beryllium and during that process there would be a "solution" phase that if we could stabilize it in that "state" we could use the silicon material as a carrier and make electrodepositions.
 We have made stable hexagonal crystals of the silicon material. We have made various other types of "gem" stones. We introduced sub-bituminous coal into the matrix at 1200° C., and produced a green "gem" stone that was very much like an emerald except it had no beryl (or in fact just the aluminum in beryl, in it.
 2. Encapsulation of Nuclear Waste
 Encapsulation of low level nuclear waste is an important problem. Low level nuclear waste is routinely encapsulated in a product developed by Dow Chemical called BORO-SILICATE. It is a boron and glass mixture and they melt it and pour over containers full of low level nuclear wastes. The original test for qualifying for the government's Savannah River Project contract was to take a specimen of cerium oxide and encapsulate it in a vitreous glass material and then subject it to the 30 day ionized water test. The original test was to allow only 3 parts per billion.
 We passed this original test while Dow's BORO-SILICATE failed. We believe that we extracted all the outer ring oxygen electrons off the cerium oxide and made either a stable water-insoluble material of unknown nature or reduced the oxygen completely, and the result was pure cerium metal, which is also insoluble in water. This same encapsulation ability could be used for biological and other very serious hazards that now have very poor remediation methods.
 3. Electrodeposition of Silicon
 This could revolutionize the computer chip business and the photo-voltaic cell business. Very long lasting light-weight batteries could also be made this way. We have not only made depositions of silicon using highly pure silicon solutions of the present invention on small scale but also have made depositions of non-amorphous carbon or diamond. We have also electroplated cobalt, gold, zinc/silicon, and many other materials to form ultra thin-film depositions.
 4. Development of a New and Previously Unknown Form of Energy
 We believe that we have found an unlimited, non-radioactive power to end all energy worries forever. We have observed the results of what we call "plasma energy". We are developing ways to harness it.
 With unlimited power we could use electrolysis and extract hydrogen from the sea and then reform any hydrocarbons we might need. Hydrogen fueled cars with no emissions except water vapor could be easily developed with an unlimited source of hydrogen. Heated and cooled houses with no emissions and at almost no or very low costs would also be possible. The sea also has all the rare earth and other precious metals we would ever need. Mining for minerals would become obsolete. We would get them all from the sea. As a by-product of our electrolysis we would extract all of them. The offshore electrolysis plants would have as the by-product of the hydrogen development and metals extraction, an almost unlimited supply of oxygen. This could lead to the end of the Greenhouse Effect.
 5. Means and Methods for Extraction, Collection, Refinement and Development of Orbitally Realigned Mono-Atomic Elements Often Called ORMEs
 This material which is in its "very green" development stage suggests all manner of things across science, religion, philosophy and things esoteric. It is associated with recovery of less than 150 micron size gold and the associated "slime" material which we have found to have unique properties. These materials are believed to hold the very essence of life powers including curative as well as other paranormal potentials. Things like ultra-conductivity, levitation, energy amelioration are all believed attainable.
 While the invention has been described with reference to certain exemplary embodiments thereof, those skilled in the art may make various modifications to the described embodiments of the invention without departing from the scope of the invention. The terms and descriptions used herein are set forth by way of illustration only and are not meant as limitations. In particular, although the present invention has been described by way of examples, a variety of compositions and methods would practice the inventive concepts described herein. Although the invention has been described and disclosed in various terms and certain embodiments, the scope of the invention is not intended to be, nor should it be deemed to be, limited thereby and such other modifications or embodiments as may be suggested by the teachings herein are particularly reserved, especially as they fall within the breadth and scope of the claims here appended. Those skilled in the art will recognize that these and other variations are possible within the scope of the invention as defined in the following claims and their equivalents.
Patent applications by Ben Elledge, Sugar Land, TX US
Patent applications by Richard Okun, Fayetteville, NY US
Patent applications by Robert Kulperger, New York, NY US
Patent applications by SILICON SOLUTIONS LLC
Patent applications in class Inorganic (only) liquid
Patent applications in all subclasses Inorganic (only) liquid