Aluminum oxide, properties, preparation, chemical reactions


Brief characteristics of aluminum oxide:

Aluminum oxide is an inorganic substance that has no color.

Aluminum oxide contains three oxygen atoms and two aluminum atoms.

Chemical formula of aluminum oxide Al2O3.

It occurs in nature in the form of alumina and corundum.

Does not dissolve in water.

Amphoteric oxide. Depending on the conditions, it exhibits either basic or acidic properties. It exhibits its chemical properties when heated to high temperatures - about 1000 oC.

Use of aluminum nitric acid salt

The substance is used in textile factories to etch fabrics before dyeing, plays an important role in tanning leather, and is used to make filaments. Catalytic properties are used to purify oil from various harmful impurities, and can also remove corrosion from metals and some alloys. Included in some antiperspirants.

The danger of the substance to humans is low or absent at all. Solid elements can be handled without protective gloves, and the material can be sniffed without any fear of getting a burn to the respiratory tract. Cases of aluminum nitrate entering the human digestive system have not been recorded, so it is difficult to say about the danger.

When testing on rats, half of the test group died after internal use. So there is certainly a danger, but in any case, no chemical substance should be consumed until its properties have been studied and its benefits to the body have been proven.

Physical properties of aluminum oxide*:

Parameter name:Meaning:
Chemical formulaAl2O3
Synonyms and names in a foreign languagealuminum oxide α-form
corundum (English)

aluminum oxide α-form (Russian)

corundum (Russian)

Type of substanceinorganic
Appearancecolorless trigonal crystals
ColorDue to impurities, aluminum oxide, as a mineral, can be colored in different colors
Taste—**
Smell
Physical state (at 20 °C and atmospheric pressure 1 atm.)solid
Density (state of matter – solid, at 20 °C), kg/m33990
Density (state of matter – solid, at 20 °C), g/cm33,99
Boiling point, °C3530
Melting point, °C2050
Molar mass, g/mol101,96
Mohs hardness9

Note:

* α-form aluminum oxide.

** - no data.

Chemical properties of aluminum oxide. Chemical reactions of aluminum oxide:

Aluminum oxide is an amphoteric oxide.

The chemical properties of aluminum oxide are similar to those of amphoteric oxides of other metals. Therefore, it is characterized by the following chemical reactions:

1. reaction of aluminum oxide with aluminum:

4Al + Al2O3 ⇄ Al2O (t = 1450 °C).

As a result of the reaction, aluminum oxide is formed.

2. reaction of aluminum oxide with carbon:

2Al2O3 + 9C → 2Al4C3 + 6CO (t = 1800 °C).

As a result of the reaction, a salt is formed - aluminum carbide and carbon monoxide.

3. reaction of aluminum oxide, carbon and nitrogen:

Al2O3 + 3C + N2 → 2AlN + 3CO (t = 1600-1800 °C).

As a result of the reaction, a salt is formed - aluminum nitride and carbon monoxide.

4. reaction of aluminum oxide with sodium oxide:

Na2O + Al2O3 → 2NaAlO2 (t = 2000 °C).

As a result of the reaction, a salt is formed - sodium aluminate.

5. reaction of aluminum oxide with potassium oxide:

K2O + Al2O3 → 2KAlО2 (t = 1000 °C).

As a result of the reaction, a salt is formed - potassium aluminate.

6. reaction of aluminum oxide with magnesium oxide:

MgO + Al2O3 → MgAl2O4 (t = 1600 °C).

As a result of the reaction, a salt is formed - magnesium aluminate (spinel).

7. reaction of aluminum oxide with calcium oxide:

CaO + Al2O3 → Ca(AlO2)2 (t = 1200-1300 °C).

As a result of the reaction, a salt is formed - calcium aluminate.

8. reaction of aluminum oxide with nitric :

Al2O3 + 3N2O5 → 2Al(NO3)3 (t = 35-40 °C).

As a result of the reaction, a salt is formed - aluminum nitrate.

9. reaction of aluminum oxide with silicon oxide:

Al2O3 + SiO2 → Al2SiO5.

As a result of the reaction, a salt is formed - aluminum silicate. The reaction occurs by sintering the reaction mixture.

10. reaction of aluminum oxide with sodium hydroxide:

Al2O3 + 2NaOH → 2NaAlO2 + H2O (t = 900-1100 oC).

Fusion of aluminum oxide with dry sodium hydroxide. As a result of the reaction, a salt is formed - sodium aluminate and water.

11. reaction of aluminum oxide with potassium hydroxide:

Al2O3 + 2KOH → 2KAlO2 + H2O (t = 900-1100 oC).

Fusion of aluminum oxide with dry potassium hydroxide. As a result of the reaction, a salt is formed - potassium aluminate and water.

12. reaction of aluminum oxide with sodium carbonate:

Al2O3 + Na2СO3 → 2NaAlO2 + CO2 (t = 1000-1200 oC).

As a result of the reaction, a salt is formed - sodium aluminate and carbon monoxide.

13. reaction of aluminum oxide with hydrofluoric acid:

Al2O3 + 6HF → 2AlF3 + 3H2O (t = 450-600 oC).

As a result of a chemical reaction, a salt is obtained - aluminum fluoride and water.

14. reaction of aluminum oxide with nitric acid:

Al2O3 + 6HNO3 → 2Al(NO3)2 + 3H2O.

As a result of a chemical reaction, salt is obtained - aluminum nitrate and water.

The reactions of aluminum oxide with other acids proceed similarly.

15. reaction of aluminum oxide with hydrogen bromide (hydrogen bromide):

Al2O3 + 6HBr → 2AlBr3 + 3H2O.

As a result of a chemical reaction, a salt is obtained - aluminum bromide and water.

16. reaction of aluminum oxide with hydrogen iodide:

Al2O3 + 6HI → 2AlI3 + 3H2O.

As a result of a chemical reaction, salt is obtained - aluminum iodide and water.

17. reaction of aluminum oxide with ammonia:

Al2O3 + 2NH3 → 2AlN + 3H2O (t = 1000 oC).

As a result of a chemical reaction, salt is obtained - aluminum nitride and water.

18. aluminum oxide electrolysis reaction:

2Al2O3 → 4Al + 3O2 (t = 900 oC).

Electrolysis is carried out in a melt. The chemical reaction produces aluminum and oxygen.

Metal passivation

One of the effective methods of protecting the metal surface from corrosion is surface treatment using special chemical solutions.

When they interact with metal, a chemical reaction occurs, as a result of which a neutral (passive) compound is formed on the surface that can resist the occurrence of corrosive processes. This treatment is called metal passivation.

After this process is completed, an oxide film forms on the surface. It has the chemical properties not to enter into an oxidation reaction and thereby prevents the destruction of not only the surface layer, but also the entire part.

This type of processing is most common for steel, aluminum, nickel, copper and their alloys. In addition to the tasks of protection against corrosion, passivation is used to carry out decorative treatment of the surface of the finished product and reduce the resistivity of contacts in electrical connections.

Description of technology

Passivation is based on the principles of chemical interaction of the surface layer of a metal with various solutions of other metals, as a result of which a surface layer with new physical and chemical properties is formed on the surface. The passivation process involves the creation of absorption (phase) layers that change the structure of the original metal. The passivation layer creates a reliable barrier that prevents the oxidation process and serves as reliable protection against corrosion.

To carry out such chemical reactions, various metals are used. This depends on the composition of the original metal from which the part is made. To give it specific properties, the following can be used: chromium, nickel, cobalt, manganese, molybdenum and other rare earth metals. Depending on their percentage, a passivation solution is prepared and the necessary equipment is selected.

When passivating stainless steel during its production, various alloying metals are added to its composition. They provide better interaction with the chemical elements included in the passivation solution.

For example, chromium oxide is used to create a reliable anti-corrosion film on the surface of steel. A chrome plating operation is performed. It completely changes the physical and chemical properties of the surface layer.

When the processing is carried out correctly, an even layer of equal density is obtained. Various acids are used to carry out passivation. Most often, a solution is created based on nitric acid.

It is the created salts based on this acid that create a protective film on the surface of the steel with high protective characteristics.

After completion of the technological process, the quality of the resulting layer is checked. This is necessary to evaluate the surface of the machined part. In practice, various verification methods are used. For example, a chemical method is used: the surface is treated with a solution of potassium ferrocyanide in nitric acid.

This impact allows you to visually identify areas of poor quality processing. In places where the layer is thin enough or absent, that is, there is a large amount of free iron, a characteristic blue color will appear. This method is used in factory laboratories.

They check selected parts from the finished batch.

A simpler, but more time-consuming method is to place the finished product in ordinary water. After a long stay in water, poorly treated areas become covered with rust.

The technology for passivation of non-ferrous metals is practically no different from the technology for processing steel. The main difference is the composition of the solutions used. For example, potassium and sodium chromates or chromic anhydride are used to process aluminum, copper, and nickel.

The processing process is accelerated by adding various salts and acids to the solution.

Passivation of copper is carried out in solutions of sulfuric acid, surface treatment of copper is carried out in a solution of phosphoric acid, zinc and cadmium in solutions of hydrochloric and nitric acid.

In some cases, the process of interaction of a solution with metal is used to solve other important technical problems. The process of metal decomposition under the influence of oxides is used for the manufacture of printed circuit boards in radio engineering. This procedure is called etching.

In this case, a pattern of future conductive strips and locations for placement of radio components is applied to the surface of the metallized textolite plate using paint.

Then the plate with the applied pattern is lowered into a bath of solution, under the influence of which the metal layer is chemically removed from the surface of the PCB. As a result of passivation, only metal protected by paint remains on the surface.

After this, the plate is washed in running water and the applied paint layer is removed using solvents. The result of such passivation (etching) is a finished printed circuit board for a specific radio-electronic device.

The technology of applying a decorative layer to the main layer of the product does not differ from the general passivation process. When creating jewelry, a thin layer of gold film is applied to the surface of a silver blank. It is formed in a similar way. Thus, a product with a characteristic golden color is obtained.

An important point in obtaining a high-quality film during passivation is finishing processing. In all cases, after removing the part from the solution bath, it is necessary to rinse it thoroughly. This is necessary in order to stop the passivation process.

If you leave part of the active solution or even its diluted components, the technology will be disrupted and the quality of the resulting film will be significantly reduced. After thorough washing, it is recommended to dry the finished part.

This can be done by natural drying or using special hair dryers. In production, drying chambers are used that provide a uniform flow of warm air.

High-quality surface preparation, compliance with all processing modes, observance of passivation time, high-quality washing and drying make it possible to obtain a high-quality, uniform protective layer that can last quite a long time.

Application of passivation

The main objectives of passivation include:

  • prevention of corrosion processes occurring in the upper layers of metal;
  • protection from destruction of newly created connections, for example, at the site of a weld (passivation of welds);
  • increased electrical conductivity at the point of electrical contact;
  • creation of printed circuit boards using prepared templates (etching);
  • processing of the finished product in order to impart new decorative and consumer properties.

The first problem is solved for a large number of metals and their alloys. One option for such protection is bluing. In the second case, to create a strong welded joint, passivation of the anodes and final processing of the resulting joint after welding are used. Carrying out passivation can significantly increase the tightness of the resulting connections.

This is especially important when laying pipelines. This treatment is very useful when welding difficult-to-weld metals such as aluminum. Passivation of copper or brass is carried out to create temporary protection against tarnishing of the surface of the product for a certain period of time (usually about a month).

Sometimes it is used as a temporary preservation of prepared parts for storage between further processing or assembly operations.

This type of processing is necessary when using metal products in the following cases:

  • the use of fasteners, especially in aggressive environments and high mechanical loads;
  • when assembling pipelines, especially in places of welds;
  • to protect boiler equipment;
  • machine parts and mechanisms in contact with sea water;
  • structural elements operating under changing temperature conditions;
  • individual elements of hand and mechanical tools;
  • finished products used in everyday life (door handles, furniture fittings, etc.);
  • decorative crafts for the interior;
  • in radio electronics to improve the quality of contacts;
  • Jewelry.

The problem of increasing electrical conductivity is solved by applying a thin layer of metal with increased electrical conductivity, such as gold or silver, to the surface of the manufactured contacts.

Types of passivation

The main and most well-developed types of passivation are:

  • chemical;
  • electrochemical.

Chemical

Chemical passivation involves the use of solutions of salts of various metals. The most effective passivation is carried out with nitric acid. In addition, sulfuric acid or citric acid is used to form a solution.

To improve the quality of the process, a small amount of sodium bichromate is added to the solution. Its amount does not exceed 6% of the total mass. The composition of the solution is selected individually and largely depends on the type of metal being processed.

For example, to passivate iron, metal salts dissolved in high concentration sulfuric acid are used.

The essence of chemical passivation is the active attraction of negative ions that are present in the solution to metal atoms. This occurs due to the presence of a positive charge. As a result of such diffusion, a surface layer is formed.

For passivation, it is necessary to carry out preliminary preparation of the surface of the product. It is thoroughly cleaned using mechanical and chemical methods. The final result and the reliability of the formed film depend on the quality of this procedure. This is of great importance when passivating non-ferrous metals: brass, copper, bronze.

Electrochemical

This type of passivation is based on the principles laid down in the technique of galvanic processing of products. Acceleration of processing is carried out due to the influence of direct current, which flows through the solution, accelerating the chemical reaction. This passivation is called electrochemical.

In addition to the bath in which the electrolyte is placed, such an installation uses a direct current source, connecting wires and one electrode. The second electrode is the part itself.

Another option for contacts is one electrode and a bath body (it must be made of metal that is resistant to electrolyte and electric current).

In practice, electrical installations with a relatively low voltage level are used. Its value does not exceed 12V.

In both cases, when the installation is turned on, an electric current is passed through the solution. It stimulates the passivation process on the surface of the workpiece. In practice, I distinguish between anodic and cathodic passivation.

With this passivation, a positive potential is applied to the workpiece, and a negative potential is applied to the bath body. When using the electrochemical method, the protective film is formed faster and is more even. But this technology is more expensive than chemical passivation, because

it uses more complex equipment and consumes electricity. Under its action, the protective film is uniform. This is how a film is formed on the surface of copper blanks. Current is passed through solutions with chromium salts dissolved in them.

It is in them that copper acquires the greatest resistance to corrosion.

Important parameters in this process are the passivation time, the density and composition of the electrolyte, and the critical value of the passivation current. These parameters are calculated for various metals and are given in special tables. Based on these data, the allowable processing time is calculated.

Properties of metal after processing

The main objective of passivation is to improve the physicochemical and mechanical characteristics of the surface layer of the material from which the part is made. The remaining characteristics of the deeper layers remain unchanged. Therefore, after passivation is completed, the following properties and characteristics change in the surface layer:

  • a layer with a new chemical composition appears;
  • anti-corrosion activity changes (it slows down significantly);
  • the physical characteristics of the material are improved (only the surface layer);
  • in some cases, the mechanical strength of the product increases;
  • the color of the part changes (it takes on a more aesthetic shape);
  • consumer properties increase and presentation improves.

Passivation of stainless steel can significantly improve anti-corrosion properties and give the finished part a completely different color. The use of chromium or nickel in the passivation solution produces a shiny metallic color.

Passivation of iron with chemical elements close to it makes it possible to create an outer layer that is sufficiently resistant to corrosion. In this way, the scope of application of such products expands. They can be used even in active and aggressive environments. In addition to various grades of steel, cast iron is subjected to passivation.

The main task is to create a protective film against corrosion. In some cases, when thickened sodium nitrate is used, the surface layer acquires some elasticity. In this case, the fragility of the entire part is reduced. One type of steel is the so-called blued finish.

The result of processing is a reliable outer layer of black color.

The properties of the surface layer of non-ferrous metals change in a similar way. As a result of passivation, adsorption or phase layers of a certain thickness are formed. Placing an aluminum workpiece stimulates the process of natural passivation of the surface layer of this metal. When exposed to acidic solutions, the protective properties of the surface layer of aluminum increase.

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Passivation of stainless steel to protect it

When stainless steel products are made, they are typically immersed in a nitric acid bath at the end of the manufacturing process to remove contaminants.

The acid also activates the oxidation process of chromium in the air called passivation, where a protective layer of chromium oxide is formed when oxygen reacts with chromium.

Passivation occurs very quickly - usually within 20 minutes.

Now some stainless brewing equipment, particularly lower cost stainless materials, were likely machined, stamped, pickled, polished and welded only after the stainless steel had been fabricated and acid washed.
As a result, it may contain oils, polishes, welding compounds and other contaminants that protect the steel but should be washed away the first time you clean your parts. Plus, you probably don't want to find these oils and compounds in your beer.

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