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Characteristics of a Chemical Reaction
Types of Chemical Reactions
List of Common Chemical Reactions

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According to the modern view of chemical reactions, bonds between atoms in the reactants must be broken, and the atoms or pieces of molecules are reassembled into products by forming new bonds. Energy is absorbed to break bonds, and energy is evolved as bonds are made. In some reactions the energy required to break bonds is larger than the energy evolved in making new bonds, and the net result is the absorption of energy. Hence, different types of bonds may be formed in a reaction. A Lewis acid-base reaction, for example, involves the formation of a covalent bond between a Lewis base, a species that supplies an electron pair, and a Lewis acid, a species that can accept an electron pair. Ammonia is an example of a Lewis base. A pair of electrons located on a nitrogen atom may be used to form a chemical bond to a Lewis acid.

Learn about the different types of chemical bonds.

Chemists classify chemical reactions in a number of ways: by type of product, by types of reactants, by reaction outcome, and by reaction mechanism. Often a given reaction can be placed in two or even three categories, including gas-forming and precipitation reactions. Many reactions produce a gas such as carbon dioxide, hydrogen sulfide, ammonia, or sulfur dioxide. Cake batter rising is caused by a gas-forming reaction between an acid and baking soda (sodium hydrogen carbonate). Classification by types of reactants include acid-base reactions and oxidation-reduction reactions, which involve the transfer of one or more electrons from a reducing agent to an oxidizing agent. Examples of classification by reaction outcome include decomposition, polymerization, substitution, and elimination and addition reactions. Chain reactions and photolysis reactions are examples of classification by reaction mechanism, which provides details on how atoms are shuffled and reassembled in the formation of products.

Read more below: Classifying chemical reactions

Learn about acid-base reactions.

Learn about chain, or self-sustaining, reactions.

chemical reaction, a process in which one or more substances, the reactants, are converted to one or more different substances, the products. Substances are either chemical elements or compounds. A chemical reaction rearranges the constituent atoms of the reactants to create different substances as products.

Chemical reactions are an integral part of technology, of culture, and indeed of life itself. Burning fuels, smelting iron, making glass and pottery, brewing beer, and making wine and cheese are among many examples of activities incorporating chemical reactions that have been known and used for thousands of years. Chemical reactions abound in the geology of Earth, in the atmosphere and oceans, and in a vast array of complicated processes that occur in all living systems.

melting ice

Chemical reactions must be distinguished from physical changes. Physical changes include changes of state, such as ice melting to water and water evaporating to vapour. If a physical change occurs, the physical properties of a substance will change, but its chemical identity will remain the same. No matter what its physical state, water (H2O) is the same compound, with each molecule composed of two atoms of hydrogen and one atom of oxygen. However, if water, as ice, liquid, or vapour, encounters sodium metal (Na), the atoms will be redistributed to give the new substances molecular hydrogen (H2) and sodium hydroxide (NaOH). By this, we know that a chemical change or reaction has occurred.

The concept of a chemical reaction dates back about 250 years. It had its origins in early experiments that classified substances as elements and compounds and in theories that explained these processes. Development of the concept of a chemical reaction had a primary role in defining the science of chemistry as it is known today.

The first substantive studies in this area were on gases. The identification of oxygen in the 18th century by Swedish chemist Carl Wilhelm Scheele and English clergyman Joseph Priestley had particular significance. The influence of French chemist Antoine-Laurent Lavoisier was especially notable, in that his insights confirmed the importance of quantitative measurements of chemical processes. In his book Traité élémentaire de chimie (1789; Elementary Treatise on Chemistry), Lavoisier identified 33 “elements”—substances not broken down into simpler entities. Among his many discoveries, Lavoisier accurately measured the weight gained when elements were oxidized, and he ascribed the result to the combining of the element with oxygen. The concept of chemical reactions involving the combination of elements clearly emerged from his writing, and his approach led others to pursue experimental chemistry as a quantitative science.

The other occurrence of historical significance concerning chemical reactions was the development of atomic theory. For this, much credit goes to English chemist John Dalton, who postulated his atomic theory early in the 19th century. Dalton maintained that matter is composed of small, indivisible particles, that the particles, or atoms, of each element were unique, and that chemical reactions were involved in rearranging atoms to form new substances. This view of chemical reactions accurately defines the current subject. Dalton’s theory provided a basis for understanding the results of earlier experimentalists, including the law of conservation of matter (matter is neither created nor destroyed) and the law of constant composition (all samples of a substance have identical elemental compositions).

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Thus, experiment and theory, the two cornerstones of chemical science in the modern world, together defined the concept of chemical reactions. Today experimental chemistry provides innumerable examples, and theoretical chemistry allows an understanding of their meaning.

When making a new substance from other substances, chemists say either that they carry out a synthesis or that they synthesize the new material. Reactants are converted to products, and the process is symbolized by a chemical equation. For example, iron (Fe) and sulfur (S) combine to form iron sulfide (FeS). Fe(s) + S(s) → FeS(s) The plus sign indicates that iron reacts with sulfur. The arrow signifies that the reaction “forms” or “yields” iron sulfide, the product. The state of matter of reactants and products is designated with the symbols (s) for solids, (l) for liquids, and (g) for gases.

A chemical reaction is a process in which reactants react chemically and convert into products by chemical transformation. For example, Respiration – we inhale oxygen which reacts with glucose and produces carbon dioxide, water and energy. The reaction is given below.

C6H12O6 + 6O2 → 6CO2 + 6H2O + Energy

Characteristics of a Chemical Reaction

Chemical reactions show one or more than one of the following characteristics.

Evolution of gas
Change in colour
Change in temperature
Change in energy
Formation of precipitate
Change in state

Now understand these characteristics in detail.

Evolution of Gas – Some chemical reactions take place with the evolution of gas. For example, when zinc reacts with hydrochloric acid, hydrogen gas is evolved with the formation of zinc chloride.

Reaction - Zn + 2HCl → ZnCl2 + H2

Change in Colour – Some chemical reactions are accompanied by a change in colour. For example, when colourless lead nitrate reacts with potassium iodide, it forms a yellow precipitate of lead iodide and colourless potassium nitrate.

Reaction – Pb(NO3)2 + 2KI → PbI2 + 2KNO3

Colourless Colourless Yellow ppt colourless

Change in Temperature – Some chemical reactions are accompanied by a change in temperature. For example, some reactions are exothermic in nature, while some are endothermic.
Change in Energy – Chemical reactions often involve a change in energy. During a chemical reaction, energy can be evolved or be absorbed. For example, in combustion reactions, energy is released, such as the burning of a fuel.
Formation of Precipitate – Some chemical reactions are accompanied by the formation of the precipitate. For example, barium chloride reacts with sodium sulphate and forms sodium chloride and precipitate of barium sulfate.

Reaction – BaCl2 + Na2SO4 —> BaSO4 + NaCl

Precipitate

Change in State – Some chemical reactions are accompanied by a change in state. For example, ammonia gas reacts with hydrogen chloride gas and forms solid ammonium chloride crystals.

Reaction – NH3(g) + HCl(g) —-> NH4Cl(s)

Types of Chemical Reactions

Chemical reactions are of many types. Here, we are covering the most common eight types of chemical reactions, which are part of the class X chemistry syllabus as well.

Decomposition reaction
Combination reaction
Combustion reaction
Neutralization reaction
Single displacement reaction
Double displacement reaction
Precipitation reaction
Redox reaction
Decomposition Reaction – In a decomposition reaction, molecules or compounds break down into two or more than two simpler chemically new substances. For example, electrolysis of water. In the electrolysis of water, water breaks down into hydrogen and oxygen, which show completely different properties than water.

Reaction - 2H2O electricity → 2H2 + O2

Combination Reaction – In a combination reaction, two or more molecules are combined together chemically to form a new substance (compound). Combination and decomposition reactions are opposite of each other. For example, when we burn magnesium ribbon (or magnesium), it gives grey-black ash of magnesium oxide.

Reaction – Mg + O2 → MgO

Combustion Reaction – It is an exothermic reaction that releases energy, generally in the form of heat. It is a reaction between fuel and an oxidant (generally atmospheric oxygen) that produces smoke, water and heat generally. For example, when we burn methane, it gives carbon dioxide and water.

Reaction – CH4 + 2O2 → CO2 + 2H2O

Neutralization Reaction – In these reactions, acid and base react with each other and form salt and water. For example, hydrochloric acid reacts with sodium hydroxide (base) and forms sodium chloride (salt) and water.
Single Displacement Reaction – In these reactions, more reactive metal displaces less reactive metal from its salt. In these reactions, products can be determined through reactivity series. Reactivity series is a series in which elements are arranged in decreasing order of their reactivity. It means the elements present at the top of this reactivity series are more reactive than the elements present at the bottom.

The reaction of potassium with magnesium chloride is an example of a single displacement reaction. In this reaction, potassium displaces magnesium from its salt because potassium is more reactive than magnesium. Potassium is present at the top of the reactivity series and is the most reactive element.

Reaction – 2K + MgCl2 → 2KCl + Mg

Double displacement reaction – In these reactions, two aqueous ionic compounds exchange their ions (mostly cations) and produce two new compounds. For example, potassium nitrate reacts with aluminium chloride and forms aluminium nitrate and potassium chloride.

Reaction – KNO3 + AlCl3 ↔️ Al(NO3)3 + KCl

Precipitation Reaction – In these reactions, an insoluble precipitate is formed. In precipitation reactions, two soluble salts in aqueous solutions are combined and form an insoluble precipitate.

Reaction – AgNO3(aq) + KCl(aq) ↔️ AgCl + KNO3(aq)

Redox Reaction – Those chemical reactions in which oxidation and reduction take place simultaneously are called redox reactions. Oxidation is the addition of oxygen, while reduction is the addition of hydrogen (or removal of oxygen). We have already discussed oxidation and reduction in a separate article with the title ‘Oxidation and Reduction’. You can refer to this article for a detailed explanation of oxidation and reduction.

The reaction of copper oxide with hydrogen is an example of a redox reaction. In this reaction, hydrogen has undergone oxidation by gaining oxygen atoms while copper oxide has undergone reduction by removing oxygen.

List of Common Chemical Reactions

We are giving here a general list of common chemical reactions.

S.No.	Chemical reaction	Equation
	Electrolysis of water	2H2O electricity→ 2H2 + O2
	Rusting of iron	4Fe + 3O2 →2Fe2O3
	The reaction of quicklime (CaO) with water	CaO + H2O → Ca(OH)2 Ca(OH)2 is known as slaked lime.
	Photosynthesis	6CO2 + 6H2O → C6H12O6 + 6O2 (reaction takes place in the presence of sunlight and chlorophyll)
	Respiration	C6H12O6 + 6O2 → 6CO2 + 6H2O
	Combustion of hydrogen – Reaction of hydrogen gas with pure hydrogen. This is an exothermic reaction.	2H2 + O2 → 2H2O + energy
	Decomposition of FeSO4	2FeSO4 +heat → Fe2O3(s) + SO2(g) + SO3(g) (Fe2O3(s) is green in color)
	Decomposition of lead nitrate – In this reaction, brown fumes of nitrogen dioxide gas are formed with the yellow coloured residue of lead oxide.	2Pb(NO3)2 → 2PbO + 4NO2 + O2
	Displacement reaction of iron and copper sulfate – Iron is more reactive than copper, so it displaces copper from its salt and produces iron sulfate.	Fe + CuSO4 →FeSO4 + Cu

This ends our coverage on a list of Various Types of Chemical Reactions. We hope you enjoyed learning and were able to grasp the concepts. We hope after reading this article you will be able to differentiate various reactions easily and it will help you in experiments as well because we have covered almost all-important chemical reactions of Class X Chemistry Experiments.