HYDROCARBONS at a glance

HYDROCARBONS AND BASIC TERMINOLOGIES IN ORGANIC CHEMISTRY

Introduction

Organic chemistry is the branch of chemistry that deals with carbon-containing compounds, particularly those containing carbon-hydrogen (C-H) bonds. The vast majority of organic compounds are derived from hydrocarbons, making them the foundation of organic chemistry.

Hydrocarbons are important sources of fuel, raw materials for industries, and building blocks for numerous synthetic products such as plastics, pharmaceuticals, detergents, dyes, and fertilizers.

Basic Terminologies in Organic Chemistry

Before studying hydrocarbons, it is important to understand some common terms used in organic chemistry.

1. Organic Compounds

Organic compounds are compounds that contain carbon atoms bonded to hydrogen atoms and may also contain oxygen, nitrogen, sulfur, phosphorus, or halogens.

Examples:

i. Methane (CH₄)

ii. Ethanol (C₂H₅OH)

iii. Acetic acid (CH₃COOH)

2. Hydrocarbons

Hydrocarbons are organic compounds made up of only two elements, carbon and hydrogen.

Examples:

i. Methane (CH₄)

ii. Ethane (C₂H₆)

iii. Benzene (C₆H₆)

Hydrocarbons are classified into:

1. Aliphatic hydrocarbons

2. Aromatic hydrocarbons

3. Homologous Series

A homologous series is a family of organic compounds having the same functional group and general formula, with successive members differing by a CH₂ group

Examples:

Compound	Molecular Formula
Methane	CH₄
Ethane	C₂H₆
Propane	C₃H₈
Butane	C₄H₁₀

Characteristics:

i. Similar chemical properties

ii. Gradual change in physical properties

iii. Same functional group

iv. Successive members differs by a CH₂

4. Functional Group

A functional group is an atom or group of atoms responsible for the characteristic chemical reactions of an organic compound.

Examples:

Functional Group	Name
–OH	Alcohol
–COOH	Carboxylic Acid
–CHO	Aldehyde
–NH₂	Amine

5. Isomerism

Isomerism is the phenomenon where compounds have the same molecular formula but different structural arrangements.

Example:

C₄H₁₀ exists as:

i. n-Butane

ii. Isobutane

6. Saturated and Unsaturated Compounds

Saturated Compounds

Contain only single carbon-carbon bonds.

Example:

i.Ethane (C₂H₆)

Unsaturated Compounds

Contain at least one double or triple bond.

Examples:

i. Ethene (C₂H₄)

ii. Ethyne (C₂H₂)

7. Molecular Formula

Shows the actual number of atoms present in a molecule.

Example:

i. Ethane = C₂H₆

8. Structural Formula

Shows how atoms are connected within a molecule.

Example:

CH₃–CH₃

Hydrocarbons

Hydrocarbons are the simplest organic compounds and form the basis of all organic chemistry.

Sources of Hydrocarbons

1. Crude oil (Petroleum)

2. Natural gas

3. Coal

4. Biomass

Classification of Hydrocarbons

Hydrocarbons are broadly classified into:

1. Aliphatic Hydrocarbons

These consist of straight-chain, branched-chain, or non-aromatic cyclic compounds.

They are divided into:

A. Alkanes

Alkanes are saturated hydrocarbons containing only single covalent bonds.

General Formula

CₙH₂ₙ₊₂

Examples

Alkane	Formula
Methane	CH₄
Ethane	C₂H₆
Propane	C₃H₈
Butane	C₄H₁₀

Properties

• Relatively unreactive

• Undergo combustion

• Undergo substitution reactions

Uses

• Domestic cooking gas

• Fuel for vehicles

• Industrial heating

B. Alkenes

Alkenes are unsaturated hydrocarbons containing at least one carbon-carbon double bond.

General Formula

CₙH₂ₙ

Examples

Alkene	Formula
Ethene	C₂H₄
Propene	C₃H₆
Butene	C₄H₈

Properties

• More reactive than alkanes

• Undergo addition reactions

Uses

• Manufacture of plastics

• Production of alcohols

• Chemical synthesis

C. Alkynes

Alkynes are unsaturated hydrocarbons containing at least one carbon-carbon triple bond.

General Formula

CₙH₂ₙ₋₂

Examples

Alkyne	Formula
Ethyne	C₂H₂
Propyne	C₃H₄

Properties

• Highly reactive

• Undergo addition reactions

Uses

• Welding and cutting metals

• Production of industrial chemicals

Aromatic Hydrocarbons

Aromatic hydrocarbons contain one or more benzene rings.

Examples

• Benzene (C₆H₆)

• Toluene (C₇H₈)

• Naphthalene (C₁₀H₈)

Characteristics

• Highly stable

• Possess delocalized electrons

• Undergo substitution reactions

Uses

• Solvents

• Dye manufacture

• Pharmaceutical production

Reactions of Hydrocarbons

1. Combustion

Hydrocarbons burn in oxygen to produce carbon dioxide and water.

Example:

CH₄ + 2O₂ → CO₂ + 2H₂O

Uses:

i. Energy generation

ii. Domestic cooking

iii. Transportation

2. Substitution Reaction

Common in alkanes and aromatic compounds.

Example:

CH₄ + Cl₂ → CH₃Cl + HCl

3. Addition Reaction

Occurs in alkenes and alkynes.

Example:

C₂H₄ + H₂ → C₂H₆

4. Polymerization

Small molecules combine to form large molecules called polymers.

Example:

n(C₂H₄) → (–CH₂–CH₂–)ₙ

Polymer produced: Polyethene

Importance of Hydrocarbons

1. Source of energy and fuel.

2. Raw materials for petrochemical industries.

3. Manufacture of plastics and synthetic fibres.

4. Production of detergents and solvents.

5. Pharmaceutical manufacturing.

6. Production of fertilizers and pesticides.

Environmental Effects of Hydrocarbon Use

Advantages

i. High energy content

ii. Easily available

iii. Versatile industrial applications

Disadvantages

i. Air pollution

ii. Greenhouse gas emissions

iii. Global warming

iv. Oil spill contamination

Conclusion

Hydrocarbons are the fundamental compounds of organic chemistry and serve as the building blocks for countless organic substances. Understanding their classification, properties, reactions, and applications provides a strong foundation for studying advanced organic chemistry. Knowledge of key organic chemistry terminologies such as functional groups, homologous series, isomerism, and saturation is essential for understanding the behavior and reactions of organic compounds.

Objectives Questions 

Instructions: Choose the correct option (A–D) for each question.

1. Organic chemistry is the branch of chemistry that deals mainly with the compounds of: A. Oxygen
B. Carbon
C. Nitrogen
D. Sulphur

2. The simplest hydrocarbon is: A. Ethane
B. Methane
C. Propane
D. Butane

3. Hydrocarbons are compounds containing only: A. Carbon and oxygen
B. Carbon and nitrogen
C. Carbon and hydrogen
D. Hydrogen and oxygen

4. Which of the following belongs to the homologous series of alkanes? A. C₂H₄
B. C₃H₆
C. C₄H₁₀
D. C₂H₂

5. The general formula of alkanes is: A. CₙH₂ₙ
B. CₙH₂ₙ₋₂
C. CₙH₂ₙ₊₂
D. CₙHₙ

6. Which of the following is an alkene? A. CH₄
B. C₂H₆
C. C₂H₄
D. C₃H₈

7. The functional group present in alkenes is: A. Triple bond
B. Single bond
C. Double bond
D. Hydroxyl group

8. The general formula of alkenes is: A. CₙH₂ₙ
B. CₙH₂ₙ₊₂
C. CₙH₂ₙ₋₂
D. CₙHₙ

9. Which of the following is an alkyne? A. Ethene
B. Ethane
C. Ethyne
D. Propene

10. The general formula of alkynes is: A. CₙH₂ₙ
B. CₙH₂ₙ₊₂
C. CₙH₂ₙ₋₂
D. CₙHₙ

11. The IUPAC name of CH₄ is: A. Methane
B. Ethane
C. Propane
D. Butane

12. The IUPAC name of C₂H₆ is: A. Methane
B. Ethane
C. Ethene
D. Ethyne

13. The first member of the alkene series is: A. Methene
B. Ethene
C. Propene
D. Butene

14. The process by which large hydrocarbon molecules are broken into smaller ones is called: A. Polymerization
B. Fractional distillation
C. Cracking
D. Hydrogenation

15. The main constituent of natural gas is: A. Ethane
B. Propane
C. Butane
D. Methane

16. The test used to distinguish an alkene from an alkane is: A. Litmus test
B. Bromine water test
C. Flame test
D. pH test

17. An alkene decolourizes bromine water because it: A. Is acidic
B. Contains a double bond
C. Is basic
D. Contains oxygen

18. Which of the following hydrocarbons has the highest carbon content? A. CH₄
B. C₂H₆
C. C₃H₈
D. C₄H₁₀

19. The major products of complete combustion of hydrocarbons are: A. CO and H₂O
B. CO₂ and H₂O
C. C and H₂O
D. CO₂ and H₂

20. The brown colour of bromine water disappears when shaken with: A. Methane
B. Ethane
C. Ethene
D. Propane

21. Which of the following is an aromatic hydrocarbon? A. Ethane
B. Propene
C. Benzene
D. Ethyne

22. The molecular formula of benzene is: A. C₆H₁₂
B. C₆H₆
C. C₆H₁₄
D. C₆H₁₀

23. The functional group present in alcohols is: A. –COOH
B. –OH
C. –CHO
D. –NH₂

24. The IUPAC name of CH₃CH₂OH is: A. Methanol
B. Ethanol
C. Propanol
D. Butanol

25. The homologous series characterized by the –COOH group is: A. Alcohols
B. Alkanes
C. Carboxylic acids
D. Esters

26. Which of the following compounds is a carboxylic acid? A. Ethanol
B. Ethanoic acid
C. Ethene
D. Ethanal

27. The process of joining many alkene molecules together to form a giant molecule is called: A. Cracking
B. Hydrogenation
C. Polymerization
D. Distillation

28. PVC and polythene are examples of: A. Fuels
B. Polymers
C. Alcohols
D. Acids

29. The source of most hydrocarbons used as fuels is: A. Limestone
B. Air
C. Crude oil
D. Water

30. Which of the following compounds is unsaturated? A. Methane
B. Ethane
C. Propane
D. Ethene

Rates of Chemical Reactions

During a chemical reaction, reactants collide with one another to form products, and the formation of these products do not occur at the same rates. Hence 

Rate of a chemical reaction can be defined as the number of moles of reactants that are converted, or products that are formed per unit time.

Mathematically 

Rate =      mass in grammes 

                      time taken

For instance, if 6g of zinc metal is placed in dilute tetraoxosulphate (VI) acid and it takes 3 mins to completely react, then the rate of chemical reaction is given by. 

Rate =      6g     = 2g/mins

                3min

That is, 2g of the zinc was converted to ZnCl₂ per minute 

Factors used for Measuring Rates of Reaction

The rate of a chemical reaction can be measured or can be determine by any one of the following.

i.   decrease in mass of reactants.

ii.  increase in volume of a gaseous product 

iii. change in pH

iv. change in colour intensity 

v. Change in pressure

 

These are all measurable factors.

 Factors Affecting the Rate of Chemical Reactions.

The following factors will a reaction to be fast or slow.

i. Nature of reactants

ii. Temperature

iii.. Concentration 

iv. Pressure 

v.  Presence of light

vi. Surface area 

vii. Presence of a catalyst

Before we discussed how each of these factors will affect the rate of a chemical reaction. It is important that we understand the concept of collision theory.

Collision theory assumes that for a chemical reaction to occur, there must be Collision between reactants particles, and these Collisions must be effective.

A collision is said to be effective when it leads to formation of products

What this concept is actually implying is that all collisions do not lead to the formation of a product, only the ones that are effective. So, the various factors that affect chemical reactions are factors that actually increase the number of effective collisions.

I. Effect of Nature of reactants: - this is one of the factors that affects the rate of a reaction, since different elements/ compounds behave differently.

The reactivity of metals varies as you go down the activity series and so when metals react with acids for example the reactions are not the same.

Example by virtue of their nature (their high reactivity) sodium and potassium will react explosively with dilut acids while metals like zinc and iron will react moderately with dilute acids.

II. Effect of Temperature: - An increase in temperature will cause reactants particles to gain more kinetic energy leading to an increase in effective collision and hence, an increase in the rate of reaction. An increase in temperature will also lead to an increase in the energy of the system.

III. Effect of Concentration: - An increase in the concentration of the reactants will lead to an increase in the number of reactants per unit area (the reactants becomes closer) thus, leading to overcrowding and increase in the effective collision of the reactants and hence an increase in the rate of the reaction.

IV. Effect of pressure: - An increase in pressure will lead to a decrease in volume that is, a decrease in the intermolecular space between the reactants particles leading to an increase in the effective collision and hence an increase in the rate of reaction. And vice versa 

V. Effect of presence of light: - Some reactions are photochemical, that is, affected by light. When such reactions are exposed to light the reactants, particles become more activated and collide more increasing the number of effective collisions and hence an increase in the rate of reaction.

VI. Effect of a catalyst: - A catalyst increases the rate of a reaction by creating a different pathway with a lower activation energy.

ACTIVATION ENERGY: see definition in chemistry.

  For a collision to be effective, the reactants must possess the minimum amount of energy needed to overcome the energy barrier (activation energy for the reaction) for that reaction. The higher the activation energy, the slower the rate of reaction; positive catalyst helps to lower the activation energy.

 Energy Profile Diagram 

Energy profile diagram is a diagram / graph that shows the pathway of a chemical reaction. whether the reaction is exothermic or endothermic.

                                          Figure1: Energy profile diagram of an exothermic reaction. 

The reactants have higher energy than the products, showing that heat is released during the reaction. The peak represents the activated complex, while Ea is the activation energy and ΔH is the heat of reaction.

                                         Figure2: Energy profile diagram of an endothermic reaction.

 The products have higher energy than the reactants, indicating that heat is absorbed during the reaction. The highest point is the activated complex, Ea is the activation energy, and ΔH represents the heat of reaction.

 Rate Curve

A rate Curve is the graph which shows the rate of a reaction. It is a graph of reaction against time.( that is, change in concentration against time, decrease in mass against time, e.t.c) 

The slope or the gradient of the curve is steep at the beginning because the reaction is fastest ( since  , it becomes less steep as the reaction progresses and slows down, then it finally becomes horizontal. 

The point at which the graph becomes horizontal indicates the end point of the reaction, when one of the reactants is completely used up

figure 1:  A typical rate curve showing how the mass of a reactant decreases with time during a chemical reaction. The steep part of the curve shows a fast reaction at the beginning, while the flatter part shows the reaction slowing down as the reactants are used up.

Figure 2: A graph showing how the volume of a gaseous product increases with time during a chemical reaction. The curve rises steeply at first, indicating a fast rate of gas production, and then levels off as the reaction nears completion.

ORDER Of REACTIONS

1. A first-order reaction is a chemical reaction in which the rate depends on the concentration of only one reactant raised to the power one.

In simple terms:
The speed of the reaction is directly proportional to the concentration of one reactant.

           Rate ɑ [A]
   or

           {Rate} = k[A]

Where:

• (A) = reactant

• (k) = rate constant

What this means

If the concentration of the reactant is doubled, the rate of reaction also doubles.
If the concentration is halved, the rate is halved.

Example

The decomposition of hydrogen peroxide:

H₂O₂ → H₂O + O₂

The rate depends only on the concentration of (H₂O₂), so it is a first-order reaction

A first-order reaction has a constant half-life — the time taken for half of the reactant to be used up does not change, no matter the starting concentration.

Example of a First-order reaction)

The half-life of a first-order reaction is 10 minutes.
If the initial concentration of the reactant is 80 mol dm⁻³, find the concentration after 20 minutes.

Solution

For a first-order reaction, the half-life is constant.

In 10 minutes → concentration becomes half

                 80 →40

In another 10 minutes (total = 20 minutes) → it halves again

            40 → 20

Answer

The concentration after 20 minutes is 20 mol dm⁻³.

A second-order reaction is a chemical reaction in which the rate depends on the square of the concentration of one reactant, or on the product of two reactants.

It can be written as:

                                         Rate = k[A]²
                             or 
                          

                         Rate = k[A][B]

what this means is that

• If the concentration of a reactant is doubled, the rate increases four times.

• If the concentration is tripled, the rate increases nine times.

Simple example

The reaction between nitrogen dioxide molecules:

                           2NO₂ →2NO + O₂

This is second order because the rate depends on ([NO₂]²).

Another example of a 2nd order reaction is 

The reaction between hydrogen and iodine:

                                H₂ + I₂ →2HI

This reaction is second order because experiments show that its rate depends on the product of the concentrations of both reactants:

Rate = k[H₂][I₂]

It means:

• If the concentration of H₂ is doubled, the rate doubles.

• If the concentration of I₂ is also doubled, the rate doubles again. So the overall rate becomes four times faster.

The reaction is second order because the rate depends on the concentrations of two reacting substances.

waec/neco keypoint

A second-order reaction does not have a constant half-life — its half-life changes as the concentration changes.

OBJECTIVE QUESTIONS 

1. Which of the following best describes the rate of a chemical reaction?

A. The amount of heat produced
B. The speed at which reactants are used up
C. The colour change in a reaction
D. The total energy of the reaction

2. Which of the following factors does NOT affect the rate of a chemical reaction?

A. Temperature
B. Pressure
C. Concentration
D. Density

3. An increase in temperature increases the rate of reaction because

A. molecules become heavier
B. molecules move faster and collide more
C. the volume of the gas increases
D. the pressure decreases

4. Which of the following will increase the rate of reaction between zinc and hydrochloric acid?

A. Using dilute acid
B. Using powdered zinc
C. Lowering the temperature
D. Using large zinc pieces

5. A catalyst increases the rate of a chemical reaction by

A. increasing the temperature
B. creating a different pathway with a lower activation energy
C. increasing the pressure
D. increasing the concentration

6. Which of the following is an example of a catalyst?

A. Copper (II) sulphate
B. Manganese (IV) oxide
C. Sodium chloride
D. Water

7. In a reaction between a solid and a liquid, the rate of reaction is increased by

A. decreasing the surface area of the solid
B. increasing the size of the solid
C. increasing the surface area of the solid
D. reducing the concentration of the liquid

8.  Which of the following will slow down a chemical reaction?

A. Increasing temperature
B. Increasing concentration
C. Adding a catalyst
D. Lowering temperature

9. The rate of reaction between magnesium and dilute hydrochloric acid can be measured by

A. change in colour
B. volume of gas produced
C. mass of magnesium used
D. number of bubbles formed

10. Which graph best represents a fast reaction?

A. One that rises steeply
B. One that rises slowly
C. One that is flat
D. One that slopes downward

11. Which of the following graphs best represents an exothermic reaction?
A. Products higher than reactants
B. Products lower than reactants
C. Reactants and products at same level
D. No activation energy

12. The peak of an energy profile diagram represents the
A. reactants
B. products
C. activated complex
D. catalyst

13. The minimum energy required for a reaction to occur is called
A. enthalpy
B. heat of reaction
C. activation energy
D. reaction rate

14. In an endothermic reaction, the heat of reaction (ΔH) is
A. zero
B. negative
C. positive
D. constant

15. If a reaction produces a gas and the mass of the reaction mixture decreases with time, this is because
A. heat is absorbed
B. gas escapes
C. the solid melts
D. the reaction stops

16. A steep slope on a rate of reaction graph indicates
A. a slow reaction
B. no reaction
C. a fast reaction
D. equilibrium

17. Which of the following will increase the rate of a chemical reaction?
A. Decreasing temperature
B. Removing a catalyst
C. Increasing concentration
D. Decreasing surface area

18. In an exothermic reaction, the products are
A. more energetic than the reactants
B. less energetic than the reactants
C. equal in energy to the reactants
D. unstable

19. The heat energy absorbed or released during a reaction is represented by
A. Ea
B. ΔH
C. K
D. pH

20. On a volume of gas versus time graph, the reaction is complete when
A. the curve is steep
B. the curve is straight
C. the curve becomes horizontal
D. the volume decreases 

21. The rate of a reaction is given by the expression
{Rate} = k[A]^2
If the concentration of (A) is increased from 0.2 mol dm⁻³ to 0.4 mol dm⁻³, how does the rate of reaction change?

A. It doubles
B. It triples
C. It increases four times
D. It remains the same

22. A finely divided form of a metal burn more readily in air than the rod form because the rod has  (a) higher molar mass (b).  smaller surface area (c) protective oxide coating (d) different chemical properties 

THEORY QUESTIONS.

1.(a)(i) Define rate of a chemical reaction?

     ii). mention three factors that can affect the rate of a chemical reaction

     iii). state the collision theory

b).  A sample of carbon is burnt at a rate of 0.50gper second for 30 minutes to generate heat.

    (i). write a balanced equation for the reaction

   (ii). determine the    I. volume of carbon (IV) oxide produced at s.t.p.  II. moles of oxygen used up in the process at s.t.p. [ C= 12.0, O= 16.0, Molar volume Vm = 22.4dm³

c. State how each of the following affects the rate of chemical reactions (i) surface area (ii) catalysts [waec]

2.a(I) What is meant by the rate of chemical reaction? 

(ii). Explain in terms of collision theory, the effect of temperature increase on reaction rate.

(b) When hydrogen peroxide is exposed to air, it decomposes (I) write an equation for the reaction (ii). Outline an experiment to illustrate the effect of a named catalyst on the rate of decomposition. 

(iii).         

3a(i) Sketch an energy profile diagram to show the effect of a catalyst on the reaction rate, given that it is exothermic.

b. The graph below is the ratio curve for the following reaction carried out in an open vessel 

MgCO3(aq) + 2HCl → MgCl2(aq) +H2O(l) + CO2(g)

(i)  For how long the reaction occurred 

(ii) why was there a loss in mass?

(iii) State whether the reaction rate was fastest at the beginning, the middle  or towards the end of the reaction.  Give reason for your answer.

(iv) List three reaction conditions that can affect the slope of the curve.(waec)

4(a)In an experiment, excess 0.050mol/dm3 HCl was added to 10g of granulated zincin a beaker. Other conditions remaining constant state how the reaction rate would be affected in each case if the experiment was repeated using 

(i) 1.0mol/dm₃ HCl

(ii) 8.0g of granulated zinc

(iii) 10g of zinc dust 

(iv) a higher volume of 0.5mol/dm₃ HCl 

(v) a reaction vessel dipped in crushed ice 

(vi) equal volumes of water and 0.50mol/dm3 HCl.

b. 

5. (a) What is meant by the rate of a chemical reaction?

     (b) State three factors that affect the rate of a chemical reaction.

6. Explain how each of the following affects the rate of a chemical reaction:

(a) Temperature
(b) Concentration
(c) Surface area

7. (a) What is a catalyst?

(b) Give two examples of catalysts.
(c) State two characteristics of a catalyst.

8. A piece of calcium carbonate reacts with dilute hydrochloric acid.

(a) Write the balanced chemical equation for the reaction.
(b) State two ways in which the rate of the reaction can be increased.
(c) Explain one of the ways stated in (b).

9. (a) Explain why powdered zinc reacts faster with dilute hydrochloric acid than a lump of zinc.

 (b) What is meant by activation energy?

(c) How does a catalyst affect the activation energy of a reaction?

10. During a chemical reaction, the volume of gas produced was measured with time.

 (a) What information can be obtained from such a graph?
(b) How can you tell from the graph that the reaction is fast?

11. State two industrial processes where catalysts are used and name  the catalyst used in each case.

 (b) Explain why an increase in pressure increases the rate of reaction between gases.

(12).  (i) Draw the energy profile diagram for the reaction H2(g) + I2(g) → 2HI(g) △H = -13kJmol-1 if the concentration of HI(g) increases from 0.001 to 0.002 mol/dm3 in 80 secs what is the rate of the reaction

LAWS AND PRINCIPLES

      LAWS AND PRINCIPLES

Aufbau principle: - when building up atoms one proton is added at a time to the nucleus and one electron around it to obtain the ground state electron configuration of the element.  

AVOGADRO’S LAW: - States that equal volume of all gases at the same temperature and pressure contain the same number of molecules

BOYLE’S LAW: - States that the volume of a given mass of gas is inversely proportional to its pressure provided the temperature remains constant.

Mathematically   Vἀ1/P       T= constant

CHARLES LAW: - States that the volume of a given mass of gas is directly proportional to it temperature provided the pressure remains constant. 

Mathematically   V ἀ T         P=constant

COLLISION THEORY: - This theory assumes that for a chemical reaction to occur, there must be effective collision between reactants particles 

COULOUMB’S LAW: - state stat the electrostatic force associated with two charges A and B is directly proportional to the product of their magnitudes and inversely proportional to the square of the distance between them

DALTON’S ATOMIC THEORY: - States that 

I.      All element is made up of small indivisible particles called atoms

II.    Atoms can neither be created nor destroyed during the cause of a chemical reaction to 

III.   Atoms of a particular element are exactly alike in all respect but are different from atoms of other              elements.

IV.   When atoms combine together, they do so in simple whole number ratio to one another 

DALTON’S LAW OF PARTIAL PRESSURE: - of partial pressure; states the in a mixture of gases that do not react chemically together, the total pressure exerted by the gas is the sum of the individual gases that make up the mixture.

P_TOTAL =P₁ +P₂+P₃+.......+P_n

FARADAY’S FIRST LAW OF ELECTROLYSIS: - States that the mass of an element deposited or liberated at an electrode during electrolysis is directly proportional to the quantity of electricity passing through the electrolyte.

 Mathematically m ἀ Q

FARADAY’S FIRST LAW OF ELECTROLYSIS: State that the mass of an element discharged during electrolysis is directly proportional to the quantity of electricity passing through the electrolyte.

FARADAY’S SECOND LAW OF ELECTROLYSIS: - states that if the same quantity of electricity is passed through solutions of different electrolyte the number of moles of each element discharged is inversely proportional to the charge on the ion

GAY –LUSSACS LAW of combining volume: - state that when gases combine, they do so in volumes which are in simple ratio to one another and to the volume of the product if gaseous provided temperature and pressure remain constant.

GRAHAM’S LAW OF DIFFUSION: - States that the rate of diffuse on of a gas is inversely proportional to the square root of its vapour density provided temperature and pressure remains constant.

HESS’S LAW OF CONSTANT HEAT OF SUMMATION: - This law states that the total enthalpy change of a chemical reaction is constant regardless of the route by which the chemical change occurs, provided that the conditions at the start of a reaction are the same as the final conditions

HUND’S RULE of maximum multiplicity: - state that when electrons fill degenerate orbitals they go in singly first before pairing occurs.

LE’CHATERLIER’S PRINCIPLE: - states that if an external constraint (such as a change in temperature, pressure or concentration) is imposed on a system in equilibrium the equilibrium will shift so as to cancel /annul the effect of the change.

LAW OF CONSERVATION OF MASS: - State that mater can neither be created nor destroyed but can be converted from one form to another.

LAW OF CONSTANT COMPOSITION: - States that all pure samples of a given chemical compound contain the same element combined in the same proportion by mass.

LAW OF DEFINITE PROPORTION: -See law of constant composition

LAW OF MULTIPLE PROPORTIONS: - States that if two elements A and B combine to form more than one compound, the various masses of A that combines with a fixed mass of B are in simple ratio with one another

MARKOVNIKOFF'S RULE: - states that when a hydrogen halide is adding to an already substituted alkene, the hydrogen atom from the halide will attach itself to the Carbon atom with the highest number of hydrogen atoms.

PAULI’S EXCLUSSION PRINCIPLE: - This principles states that 'No two electrons in the same orbital of an atom should have the same set of four quantum numbers'.

DEFINITIONS IN CHEMISTRY

DEFINITION

AN ACID

Arrhenius definition: An acid is a substance which produces hydrogen ion (H⁺) as the only positive ion in solution.

                                   HCl  → H+  +  Cl-

                                    H2O → H+  + OH-

Bronsted -Lowry’s definition: An acid is a proton donor.

Lewis's acid: An acid is any species that accepts an electron pair.

ACID-ANHYDRIDE: is the oxide of a nonmetal which dissolves in water to yield the corresponding acid.

ABSOLUTE-ZERO-TEMPERATURE: This is the lowest temperature in the Kelvin scale in which the volume of a gas is assumed to be zero.

ACTINADES: The Period 7 elements that forms the second inner transition series (5f block). It includes thorium (Th;Z=90) through lawrencium (Lr; Z=103) 

ACTIVATED COMPLEX: It is the highest energy level in a chemical reaction where the reactants are no longer reactants but are not yet products.

ACTIVATION ENERGY: this is the minimum amount of energy reactant particles must possess before a chemical reaction can occur.    OR it is the energy barrier that reactants must overcome to become products

ACTIVITY: The change in number of nuclei (N) of a radioactive sample divided by the change in time (t)

ALKANES: A hydrocarbon with the general molecular formular CnH2n+2. having only C-C single bonds

ALKENES: A hydrocarbon that contains at least one  carbon-carbon double bond (C=C bond)with the general formula CnH₂n.

ALKYNES: A hydrocarbon that contains at least one carbon-carbon triple bond (C=C ) with general formula CnH_2n-2

ALLOTROPY: This is  when an element occurs in different form but in the same physical state.

ALLOTROPES: These are different forms of an element occurring in the same physical state.

ALPHA (Ἀ) DECAY:  A radioactive process in which an alpha particle is emitted from the  nucleus of a radioactive element.

ALPHA  PARTICLE (ἀ or ⁴₂He).  A  positively charged particle, identical to a helium nucleus.

ANION: A negatively charged ion e.g  Cl^-, O^2-, N^3- .

ANODE: The electrode at which oxidation occurs in an electrochemical cell or an electrolytic cell.

ATOM: this is the smallest particle of an element that can take part in a chemical reaction.

ATOMIC MASS: This is the sum of the protons and neutrons in an atom of an element.

ATOMIC NUMBER: This is the number of protons in one atom an element.

BETA (β) DECAY: This involves the emission of a beta particle by a radioactive isotope.

BOILING POINT OF A LIQUID -: This is the temperature at which the saturated vapour pressure of the liquid is equal to the atmospheric pressure.

CATALYST: This is a substance that alters the rate of a chemical reaction, but itself is not affected by the reaction. 

CARBOHYDRATES:- These are organic compounds that contain carbon, hydrogen and oxygen, where     the hydrogen and oxygen are in the ratio of 2:1

CATHODE :- this is the electrode where reduction occurs in an electrochemical cell or an electrolytic cell.

CHEMICAL CHANGE: this is a change that is not easily reversible and in which a new substance is formed.

CONCENTRATION: this is the amount of a solute in moles per dm³ of   solution.  

COMBINATION REACTION: This is when two or more elements  combine  together to form a single compound       example        

                                     Fe_{(s) +}  S_(s) → FeS_(s)

COVALENT BONDING: this is a type of bonding that involves the sharing of electron pair between two atoms ( usually non-metals)

Cracking: this is the breaking down of higher molecular mass alkanes to lower molecular mass alkanes and alkenes.

   C₁₀H₂₂  → C8H18 +  C2H4

DEGENERATE ORBITALS: These are orbitals that are at the same energy level examples include the  p-orbital, the d-orbital and the f-orbital.

EFFLORESCENCE: this is the phenomenon whereby some salts when exposed to the atmosphere loses part or all of their water of crystallization.

EFFLORECENT SALTS; these are salts which loses part or all of their wate of crystallization when exposed to the atmosphere.

ELECTRON AFFINITY: This is the energy evolved when an electron enters an atom in the gaseous state to form a mole of gaseous negative ions.

ELECTROLYSIS: - This is the decomposition of a compound brought about by the passage of a direct current through either a solution of the compound or its molten form 

ELECTRONEGATIVITY:  Is defined as the power of an atom to attract (shared pair or bonded) electrons in a molecule.

ELECTROVALENT BOND: this is a type of bond that involves the transfer of electrons from one atom (metal) to another (non-metal).           OR             

 it is the electrostatic force of attraction between oppositely charged ions / cations and anions.

EMPIRICAL FORMULA: - This is the simplest formula of a compound; it shows the elements present and the ratio to which they are combined.

ENDOTHERMIC REACTION: This is a reaction during which heat is absorbed from the  surrounding.

END POINT: This is the point at which the chemical reaction is complete during titration. The end point is detected with the help of an indicator.

ENTHALPY: This is the total heat content of a body/substance 

ENTROPY:- This the degree of disorder or randomness of a system.

ESTERIFICATION REACTION: This is the reaction between an alkanoic acid and an alkanol to form an alkanoate (ester) and water only. 

  RCOOH + R'OH  → RCOOR' + H2O

EXOTHERMIC REACTION: This is a reaction during which heat is given off to the surrounding.

FERMENTATION:- This is the breakdown of carbohydrates into ethanol and carbon (IV) oxide by the action of micro-organism.

FUNCTIONAL GROUP: - A functional group may be a bond, an atom or a radical it is common to a homologous series and it  also determines the  chemical property of the series.

HALF-LIFE: - This is the time taken for half the total number of atoms in a given sample of a radioactive substance to undergo decay.

HOMOLOGOUS SERIES: - This is a family of organic compounds that have a regular structural pattern where successive members differs by a -CH2- group.

HYBRIDIZATION:- This is mixing of two or more orbitals to form a set of new and equal number of hybrid orbitals.  the three most common types of hybridization are the sp3, the sp2 and the sp hybridization

HYGROSCOPY: This is a phenomenon whereby some substances when exposed to the atmosphere absorbs moisture and only become sticky or wet.

ION: This is a charged atom (particle) or group of atoms carrying a charged.

IONISATION ENERGY: - This is the energy required to remove an electron from an atom to form a mole of gaseous ions.

IONIC BOND: see electrovalent bond.

ISOMERS: these are organic compounds with the same molecular formula but different structural formula.

ISOMERISM: This is the occurrence of two or more organic compounds with the same molecular formula but different structural formula.

ISOTOPES: These are atoms of the same element with the same atomic number but different mass number.

ISOTOPY: This is the occurrence of atoms of the same element with the same atomic number but different mass number. 

MASS CONCENTRATION: This is the concentration expressed in g/dm3

MOLAR CONCENTRATION: This is the concentration expressed in mols/dm3

MOLAR MASS: - This is the mass of one mole of a substance. the unit is g/mol.

MOLAR SOLUTION: These is a solution that contains one mole (1mol) or the molar mass of a substance in 1dm3 of solution

MOLECULAR FORMULA: -This is the actual formula of a compound; it shows the exact number of atoms present in one molecule of compound.

OXYDATION: This is the loss of electrons from a substance.

OXYDIXING AGENT: A substance that accepts/gains electrons.

PHYSICAL CHANGE: this is a change that is easily reversible and in which no new substance is formed.

POLLUTION:- This is the release of harmful substances into the atmosphere  in concentration that is harmful to man and his environment.

POLYMERIZATION: This is the process whereby two or more small molecules (monomers) link together to form large molecules (polymer).

REDUCTION: This is the gain of electrons 

REDUCING AGENT: A substance that donate/loss electrons 

SATURATED SOLUTION: - This is a solution that contains as much solute particles as it can hold at a particular temperature in the presence of undissolved solute particles.

STANDARD SOLUTION: This is a solution with a known concentration.  

SUPER SATURATED SOLUTION: - This is a solution that contains More than the solute it can normally hold a particular temperature.

SOLUBILITY: - Solubility of a solute in a solvent is the amount of solute in moles or grams that can saturate 1dm3 of solvent (water) at a particular temperature.

VULCANIZATION:- Vulcanization is a process whereby natural rubber is heated with sulphur under pressure in order to obtain a harder, tougher and more elastic rubber