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Introduction to Environmental Chemistry
Environmental chemistry is the study of the chemical and biochemical phenomena that occur in nature. It involves the understanding of how the uncontaminated environment works, and which naturally occurring chemicals are present, in what concentrations and with what effects. Environmental chemistry; is the study of sources, reactions, transport, effects and fate of chemical species in water, soil and air environment as well as their effects on human health and natural environment
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Origin of the solar System
Cosmology; is the branch of astronomy involving the study of the of the universe and the solar system. Cosmo-chemistry ;( chemical cosmology); is the study of chemical composition of the matter in the universe and the process that led to those compositions The solar system is made up of the sun (a star) with nine planets orbiting around it. These planets together with all the other heavenly bodies moving around or between individual planet form members of the solar system. Other heavenly body include; asteroids, comets, meteors, meteorites and satellites such as moon. The solar system does not include other stars .
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Solutions
Solutions are defined as homogeneous mixtures that are mixed so thoroughly that neither component can be observed independently of the other. The major component of the solution is called solvent, and the minor component(s) are called solute.
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Chemical Equilibria
Chemical equilibrium in the environment refers to the state where the rates of forward and reverse reactions of a chemical reaction reach a balance. In this state, the concentrations of reactants and products remain constant over time, although the reactions continue to occur.
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Phase Interactions
Phase interactions in solutions refer to the behavior and changes that occur when two or more substances (solutes and solvents) mix together to form a homogeneous mixture. These interactions are related to the different phases of matter, such as solids, liquids, and gases, and how they interact and transform during the process of solution formation.
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Colligative Properties of Solutions
COLLIGATIVE PROPERTIES OF SOLUTIONS Colligative properties are physical properties of solutions that depend on the concentration of solute particles, rather than the specific identity of the solute. The four colligative properties that can be exhibited by a solution are: 1.Boiling point elevation 2.Freezing point depression 3.Relative lowering of vapour pressure 4.Osmotic pressure
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Introduction To Organic Chemistry
Organic chemistry is the study of carbon containing compounds and their properties. This includes the great majority of chemical compounds on the planet, but some substances such as carbonates and oxides of carbon are considered to be inorganic substances even though they contain carbon.
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Air Quality and Pollution
Air Quality and Pollution
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Introduction To Environmental Chemistry
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Laws of Chemical Equilibria

The laws of chemical equilibrium describe the behavior of chemical reactions when they reach a state of equilibrium, where the forward and reverse reactions occur at equal rates. These laws were formulated based on observations and experimental data, and they provide a mathematical description of equilibrium conditions. The two main laws of chemical equilibrium are:

  1. Law of Mass Action (Law of Chemical Equilibrium): The law of mass action states that the rate of a chemical reaction is directly proportional to the product of the concentrations (or partial pressures) of the reactants raised to the power of their stoichiometric coefficients at a given temperature. This law is summarized by the following equation:

    For a general reaction: aA + bB ⇌ cC + dD

    The law of mass action can be expressed as:

    K = ([C]^c [D]^d) / ([A]^a [B]^b)

    where [A], [B], [C], and [D] represent the concentrations of A, B, C, and D, respectively, and a, b, c, and d are the stoichiometric coefficients of the balanced chemical equation.

    K is the equilibrium constant, which is a constant value at a given temperature and represents the ratio of the concentrations of products to reactants at equilibrium. It provides information about the extent of the reaction and the composition of the equilibrium mixture.

  2. Le Chatelier’s Principle: Le Chatelier’s principle states that when a system at equilibrium is subjected to a change in conditions (such as concentration, pressure, or temperature), the system will adjust to counteract the imposed change and restore equilibrium. The principle can be summarized by the following statements:

  • If the concentration of a reactant is increased, the equilibrium will shift in the direction that consumes the added substance (towards the products), and vice versa.
  • If the concentration of a product is increased, the equilibrium will shift in the direction that produces more of the added substance (towards the reactants), and vice versa.
  • If the pressure (for gaseous reactions) is increased, the equilibrium will shift in the direction that reduces the total number of moles of gas, and vice versa.
  • If the temperature is increased, the equilibrium will shift in the endothermic direction (absorbing heat), and vice versa for a decrease in temperature.

3. Kohlrausch’s law of independent migration of ions”  is related to the conductivity of electrolytic solutions.

Kohlrausch’s law of independent migration of ions, also known as Kohlrausch’s Law, states that the molar conductivity of an electrolyte at a given concentration is the sum of the individual contributions of its constituent ions. This law is based on the assumption that each ion moves independently in solution, unaffected by the presence of other ions.

Mathematically, Kohlrausch’s law can be expressed as:

Λm = Λ+(c+) + Λ-(c-)

Where:

  • Λm represents the molar conductivity of the electrolyte.
  • Λ+(c+) represents the molar conductivity of the cation (positive ion) at the given concentration.
  • Λ-(c-) represents the molar conductivity of the anion (negative ion) at the given concentration.

According to Kohlrausch’s law, the molar conductivity of an electrolyte increases with increasing dilution. At infinite dilution, the molar conductivity reaches a maximum value, which is known as the limiting molar conductivity (Λ°). The limiting molar conductivity is specific to each ion and can be used to compare the ionic conductivities of different ions.

Kohlrausch’s law is valuable in understanding and predicting the conductive properties of electrolytes, as well as in determining the degree of dissociation of electrolytes in solution. It has practical applications in fields such as electrochemistry, analytical chemistry, and chemical engineering.

4. Ostwald’s law, also known as Ostwald’s dilution law or the law of stages of dilution, relates to the behavior of weak electrolytes in solution. It was formulated by the German chemist Wilhelm Ostwald.

Ostwald’s law states that the degree of ionization (or dissociation) of a weak electrolyte increases with increasing dilution. In other words, as a weak electrolyte is progressively diluted, a higher proportion of the molecules dissociate into ions.

Mathematically, Ostwald’s law can be expressed as:

α ∝ √C

Where:

  • α represents the degree of ionization (fraction of molecules that dissociate into ions).
  • C represents the concentration of the weak electrolyte.

According to Ostwald’s law, at very low concentrations (high dilutions), the degree of ionization approaches its maximum value. This is because the presence of fewer molecules allows for less interference and increases the likelihood of dissociation. As the concentration increases, the degree of ionization decreases.

Ostwald’s law is particularly applicable to weak acids and weak bases, which only partially ionize in solution. It helps in understanding the behavior of these substances and predicting their properties at different concentrations. It also has implications in areas such as chemical equilibrium, acid-base chemistry, and the study of solutions.

These laws, along with other thermodynamic principles, help in understanding and predicting the behavior of chemical reactions at equilibrium. They are essential for studying chemical equilibrium and its applications in various fields of chemistry.

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