General Chemistry for Pharmaceutical Sciences PHARM-101 PDF

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This document is lecture notes for a general chemistry course for pharmaceutical sciences. The lecture covers stoichiometry, solution concentrations, and chemical reactions.

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 General Chemistry for
Pharmaceutical Sciences
PHARM-101
Presented by Dr. Azza H. Rageh
Associate Professor of Pharmaceutical
Analytical Chemistry
 D- Stoichiometry, Solution
Concentration and Chemical Reactions
1- Reaction Stoichiometry, Solution Concentration
and Types of Aqueous Solutions
What is meant by Stoichiometry

 Stoichiometry: calculations of the quantities of reactants
and products in a chemical reaction.

 Stoichiometry allows us to predict the amounts of products that will
form in a chemical reaction based on the amount of the reactants.
 Stoichiometry also allows us to determine the amount of reactants
necessary to form a given amount of product.

4
Reaction Stoichiometry

 The coefficients in a balanced chemical equation specify the relative

amounts in moles of each of the substances involved in the reaction:

 How Much CO2 is Produced?

 Example: 2 C8H18(l) + 25 O2(g) 16 CO2(g) + 18 H2O(g)

2 molecules of C8H18 react with 25 molecules of O2 to

form 16 molecules of CO2 and 18 molecules of H2O.

Or: 2 moles of C8H18 react with 25 moles of O2 to

form 16 moles of CO2 and 18 moles of H2O.

2 mol C8H18 : 25 mol O2 : 16 mol CO2 : 18 mol H2O
5
Reaction Stoichiometry

From the balanced equation of the combustion of octane:

2 C8H18(l) + 25 O2(g) 16 CO2(g) + 18 H2O(g)
we can write the following stoichiometric ratio:

2 moles C8H18(l) : 16 moles CO2
(This ratio is called: The Conversion Factor)

Suppose that we burn 22 moles of C8H18: the amount of CO2 produced
can be calculated using the conversion factor, as follows:

22 𝑚𝑜𝑙𝑒𝑠 𝑜𝑓 𝐶8𝐻18 × 16 𝑚𝑜𝑙𝑒𝑠 𝑜𝑓 𝐶𝑂2
= 176 𝑚𝑜𝑙𝑒𝑠 𝑜𝑓 𝐶𝑂2
2 𝑚𝑜𝑙𝑒𝑠 𝑜𝑓 𝐶8𝐻18

6
Concentration of Solutions

What Is a “Solution”?

Solution: A homogenous mixture of two or more substances:

- Solvent: material present in largest amount.

- Solute: all other materials present.
- Example:

Consider sugar dissolved in water:

- Water is the solvent.

- Sugar is the solute.

Concentrated solution has a relatively large proportion of solute to solvent.
Dilute solution has a relatively smaller proportion of solute to solvent.
7
Concentration of Solutions
 Concentration: is the amount of solute present in the solution.
Concentration units:
Name Units Symbol
% Weight Gram solute/100 g solution %, w/w
% Volume Milliliter solute/100 mL solution %, v/v
% Weight per volume Gram solute/100 mL solution %, w/v
Parts per million Gram solute/106 g solution ppm
Parts per billion Gram solute/109 g solution ppb
Gram molecular weight of solute
Molarity M
(Moles)/liter solution
Gram formula weight of
Formality F
solute/liter solution
Gram equivalent weight of solute
Normality N
/liter solution
Molality Moles solute/1000 g solution m
8
Concentration of Solutions: Molarity

 Molarity: is a method to express the concentration. It shows the
relationship between the moles of solute and liters of solution.
 is the No of gram molecular weight (moles) of solute per one litre
of solution.

No. of moles = weight (g)/molecular weight
So, Molarity (M) = weight (g)/molecular weight × volume (L)

 Unit of molarity (M) = moles of solute / liter of solution

M = mol/L = mol.L-1 = molar 9
The States of Matter
Concentration of Solutions: Molarity
Example 1: Find the molarity of a solution that has 25.5 g KBr
dissolved in 1.75 L of solution
Given: 25.5 g KBr, 1.75 L solution
Find: molarity, M
Plan:
g KBr mol KBr
M
L sol’n
Relationships:
1 mol KBr = 119.00 g, M = moles/L

Solution:

Check:
because most solutions are between 0 and 18 M, the
answer makes sense 10
Concentration of Solutions: Molarity
Example 2: How many litres of 0.125 M NaOH solution would
contain 0.255 mol NaOH?
Given: 0.125 M NaOH, 0.255 mol NaOH
Find: liters, L

Plan:
mol NaOH L sol’n

Relationships: 0.125 mol NaOH = 1 L solution
Solution:

Check:
because each L has only 0.125 mol NaOH, it makes
sense that 0.255 mol should require a little more than112 L
 Concentration of Solutions: Molarity
Example 3: Preparing 1 L of a 1 M NaCl Solution

12
Types of aqueous solution and Solubility

Consider two familiar aqueous solutions: salt water and sugar

water:

– Salt water is a homogeneous mixture of NaCl and H2O.

– Sugar water is a homogeneous mixture of C12H22O11 and H2O.

As you stir either of these two substances into the water, it

seems to disappear.

– How do solids such as salt and sugar dissolve in water?

13
What Happens When a Solute Dissolves?

There are attractive forces between the solute particles holding them
together.
There are also attractive forces between the solvent molecules.

 When we mix the solute with the solvent,
there are attractive forces between the
solute particles and the solvent molecules.
 If the attractions between solute and
solvent are strong enough, the solute will
dissolve.

14
Dissolving of Sodium Chloride in Water

 Each ion is attracted to the
surrounding water molecules and
pulled off and away from the crystal.

 Compounds such as salt that
dissociate into ions when dissolved
in water are called electrolytes, and
the resulting solutions are able to
conduct electricity.

15
Dissolving of Sugar in Water

 Table sugar (sucrose, C12H22O11) molecules homogeneously mixed
with water molecules (H2O).

 Compounds such as sugar that
don’t dissociate into ions
when dissolved in water are
called nonelectrolytes, and the
resulting solutions do not
conduct electricity.

16
Electrolytes and Nonelectrolytes
Substances that dissolve in water to form solutions that conduct
electricity are called Electrolytes

 Solution of salt (an electrolyte)  Solution of sugar (a nonelectrolyte)
17
Electrolytes and Nonelectrolytes
 Strong Electrolytes:
 substances that completely ionize when dissolve in water.
 They can conduct electrical current strongly.
 Important Examples: Soluble ionic salts (e.g. NaCl & MgBr2 …), strong
acids (e.g. HCl & HNO3) and strong bases (e.g. NaOH & Mg(OH)2).
 Weak Electrolytes:
 Include substances that partially ionize when dissolve in water.
 They can conduct electrical current weakly.
 Important Examples: weak acids (e.g. HF & CH3COOH) and weak
bases (e.g. NH4OH).
 Nonelectrolytes:
 Include substances that do not ionize when dissolve in water.
 They don’t conduct electrical current.
 Important Examples: molecular substances (e.g. sugar & alcohol).
18
Electrolytes and Nonelectrolytes: A Summary

Complete Ionizing in Partial Ionizing in water No Ionizing in water (no
water (full dissociation) (partial dissociation) dissociation)
Examples: ionic salts, Examples: molecular
Examples: weak acids
strong acids & strong (covalent) compounds as
bases & weak bases sugars & alcohols
19
Assessment
All of the following compounds are soluble in water, indicate
which of them is expected to produce strong, weak or non-
electrolyte solution?

1. CsCl(aq)
2. CH3OH(aq)
3. Ca(NO2)2(aq)

4. C6H12O6(aq)
5.Acetic acid, vinegar, CH3COOH(aq) (weak acid)
6. HCl(aq) (strong acid)
7. NaOH(aq) (strong base)
8. KOH(aq) (strong base)
9. HF(aq) (weak acid)
10.NH4OH(aq) (weak base)
21
 D- Stoichiometry, Solution
Concentration and Chemical Reactions
2- Basic types of Chemical Reactions and Reactions
involving Oxidation-Reduction
Basic Types of Chemical Reactions

1- Synthesis Reaction

2- Decomposition Reaction

3- Replacement Reactions

23
1- Synthesis Reactions

 In a synthesis reaction, two or more reactants combine to yield
one product.
 These reactions are expressed in the general form:
A + B ⟶ AB
 An example of a synthesis reaction is the combination of iron
and sulfur to form iron(II) sulfide:
8 Fe + S8 ⟶ 8FeS
 Another example is simple hydrogen gas combined with simple
oxygen gas to produce a more complex substance, such as
water.
2 H2 + O2 ⟶ 2 H2O

24
2- Decomposition Reactions

 A decomposition reaction occurs when a more complex
substance breaks down into its simpler parts.
 It is the opposite of a synthesis reaction, and can be written as:
AB ⟶ A + B
 An example of a decomposition reaction is the electrolysis of
water to make oxygen and hydrogen gas:
2 H2O ⟶ 2 H2 + O2

25
3- Replacement Reactions

 There are two types of the replacement reactions:
A. Single replacement reaction
B. Double replacement reaction

A. Single replacement reaction
 In this reaction, a single uncombined element replaces
another element in a compound
 These reactions come in the general form of:
A + BC ⟶ AC + B
 For example; magnesium replaces hydrogen in water to make
magnesium hydroxide and hydrogen gas
Mg + 2 H2O ⟶ Mg(OH)2 + H2↑

26
3- Replacement Reactions

B. Double replacement reaction
 In a double replacement reaction, the anions and cations of
two compounds switch places and form two entirely different
compounds.
 These reactions are in the general form:
AB + CD ⟶ AD + CB
 For example; the reaction of lead(II) nitrate with potassium
iodide to form lead(II) iodide and potassium nitrate:
Pb(NO3)2 + 2 KI ⟶ PbI2 ↓ + 2 KNO3

27
Types of Chemical Reactions: A Summary

Representation of four basic types of chemical reactions:
1- Synthesis,
2- Decomposition,
3- Single replacement and
4- Double replacement.
28
Chemical Reactions between Ions
 Combination of ions occurs through the formation of any of
the following:
Water
1

Weak electrolyte
2

Precipitate
3

Gas
4

Complex ion
5
29
1- Formation of Water

 When metallic hydroxide, including ammonium hydroxide, is
mixed with an acid , water is formed.

Ex. 1 NaOH + HCl NaCl + H2O

Ex. 2 NH4OH + HCl NH4Cl + H2O

 These examples represent Acid-Base reactions (reactions
between strong/weak base with strong/weak acid to form salt
and water).

30
2- Formation of Weak Electrolyte

 When a solution of a strong acid is mixed with a solution of
a salt containing the anion of a weak acid, the weak acid is
formed.

HCl + CH3COONa NaCl + CH3COOH (weak acid)

 When a solution of a strong base is mixed with a solution
of ammonium salt, the weak base (ammonium hydroxide)
is formed:

NH4Cl + NaOH NH4OH (weak base) + NaCl

31
3- Formation of a Precipitate

 Precipitation is the formation of a solid in a solution during a
chemical reaction.

 It usually takes place when the concentration of dissolved ions
exceeds the solubility limit and forms an insoluble salt.

 This process can be assisted by adding a precipitating agent or
by removal of the solvent.

 For example; the reaction between silver nitrate (precipitating
agent) and sodium chloride to form silver chloride precipitate
AgNO3 + NaCl AgCl + NaNO3
ppt 32
3- Formation of a Precipitate

Another example:
 If solutions of ferric chloride and sodium hydroxide are
mixed, the following ions are present: Fe3+, Cl-, Na+ and
OH-.

 Ferric hydroxide is formed which is insoluble in water

 The following reaction occurs:

FeCl3+ 3 NaOH Fe(OH)3 + 3NaCl
ppt

33
 4- Formation of a Gas
 The combination of ions may result in the evolution of a gas for two
reasons because either the product is gaseous, or the product is
unstable and decomposes to form a gas.
 Examples of the former are:
Ex. 1 2H+ + S2- H2S ↑ hydrogen sulphide gas
Ex. 2 H+ + CN- HCN ↑ Hydrogen cyanide

 Unstable acids formed by the combination of ions are H2CO3, H2SO3,
H2S2O3, and HNO2:
2H+ + CO32- H2CO3 H 2O + CO2 ↑
2H+ + SO32- H2SO3 H 2O + SO2 ↑
2H+ + S2O32- H2S2O3 H 2O + S  + SO2 ↑
2H+ + 2NO2- 2HNO2 H 2O + NO ↑ + NO2 ↑
H2CO3 carbonic acid
H2SO3 sulfurous acid
H2S2O3 hydrogen thiosulphate
HNO2 nitrous acid 34
5- Formation of Complex Ions

 Complexation reaction is the reaction between Lewis acid
(electron acceptor; Metal) and Lewis base (electron donor; Ligand).

 In complexation reactions, several ligands form coordinate bonds
with a metal atom to form a complex.

 This is achieved by donating lone pairs of electrons from the ligand
(L) to the metal atom (M) to form a coordination complex (ML).

L: + M ⟶ M L

Coordinate bond

35
5- Formation of Complex Ions

 Ligands are Lewis bases, They can be both anions and neutral
molecules.
 Anions that frequently form complexes are chloride (Cl-), bromide (Br-),
iodide (I-), fluoride (F-), cyanide (CN-), thiocyanate (SCN-), thiosulphate
(S2O32-) and oxalate (C2O42-).
 Neutral molecules that frequently form complexes such as; carbon
monoxide (CO), ammonia (NH3) and water.

 Many cations act as metals such as (Ca2+, Mg2+, Fe2+, Fe3+, Pb2+,
Cu2+, Zn2+, Al3+...etc).
 The only common cations that do not usually form complexes are
sodium (Na+), potassium (K+), ammonium (NH4+).

Cu2++ 4 ¨NH3 [Cu(NH3)4]2+

36
Reactions involving Oxidation-Reduction (Redox)

Oxidation – reduction reactions or redox reactions are
reactions in which electrons are transferred from one reactant to the
other.
- Oxidation: is the loss of electrons.
- Reduction: is the gain of electrons.
 Based on these definitions, redox reactions do not need to
involve oxygen.
 One cannot occur without the other.
 Example on Redox Reactions:

 In this reaction, a metal (which has a tendency to lose electrons) reacts
with a nonmetal (which has a tendency to gain electrons). In other
words, metal atoms lose electrons to nonmetal atoms. 37
Reactions involving Oxidation-Reduction (Redox)

Other common redox reactions:

38
Oxidizing Agent & Reducing Agent

 Oxidizing Agent (Oxidant):
 A Substance that oxidizes something else. The oxidizing agent
itself is reduced in the same reaction:

 Reducing Agent (Reductant)
 A Substance that reduces something else. The reducing agent
itself is oxidized in the same reaction:

39
Assessment

1- For the following reactants, what are the products of the double
displacement reaction?
FeCl3(aq) + Ba(OH)2 ​(aq)→
Choose 1 answer:
A- no reaction
B- Fe(OH)2 ​(s) + BaCl (aq)
C- FeBa (s)+ HOCl (aq)
D- Fe(OH)3(s) + BaCl2 ​(aq)

2- What type of reaction is the above reaction?
Choose all answers that apply:
A- Oxidation-reduction reaction
B- Double replacement reaction
C- Neutralization reaction
D- Precipitation reaction
40
Assessment
1- What is the type of the following reactions:
BaCl2 + MgSO4 ⟶ BaSO4 + MgCl2
2 H2 + O2 ⟶ 2 H2 O
NaOH + CH3COOH ⟶ CH3COONa + H2O
AgNO3 + Kl AgI + KNO3
2 NaBr + Cl2 2 NaCl + Br2
2 Na + Cl2 2 NaCl
H2CO3 H2O + CO2
2- Calculate the oxidation number of:
Manganese in KMnO4 , MnSO4 , MnO2
Chromium in K2CrO4 , K2Cr2O7
Oxygen in H2O , O2 , H2O2
3- What is a decomposition reaction? What is the general equation for
this reaction and give an example?
4- Compare between:
Lewis acid and Lewis base
Oxidant and Reductant 41
Assessment

42