Physical Pharmacy I Lecture 7 Thermodynamics PDF

Summary

This document is a lecture on thermodynamics, including the first, second, and third laws, and thermochemistry. It includes definitions, examples, and equations related to these concepts. The lecture was delivered on October 11, 2024, to a physical pharmacy class at University of Al Ma'arif.

Full Transcript

Physical Pharmacy I

Lecture 7

Thermodynamics, first, second and
Third law, thermochemistry
11 October, 2024

Physical Pharmacy I

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Introduction

What is Thermodynamics?
ØThermodynamics is the study of the relationships between heat,
work, energy, and matter.
ØIt is essential to comprehend how energy is transformed and matter
behaves on a macroscopic scale.

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 The First Law of Thermodynamics
ØThe first law states that energy cannot be created or

destroyed, only transferred or converted.

ØIt's often expressed as ∆U = Q – W

where ∆U is the change in internal energy, Q is heat, and

W is work.

ØThis law underpins the principle of energy conservation.

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ØThermochemistry deals with the heat changes that occur during chemical reactions.

ØEnthalpy (∆H) is a central concept, representing the heat exchanged at constant pressure.

ØThermochemical equations are used to calculate ∆H, helping us understand reaction
energetics.

ØA thermochemical equation is a type of balanced chemical equation in which the amount
of energy absorbed or released during a chemical reaction is included.

Combustion of methane: C H 4 ( g ) + 1 2 O 2 ( g ) ⟶ C O 2 ( g ) + 2 H 2 O ( l ) Δ H = − 890.3 k J.

Formation of water: H 2 ( g ) + 1 2 O 2 ( g ) ⟶ H 2 O ( l ) Δ H = − 285.8 k J.

Melting of ice: H 2 O ( s ) ⟶ H 2 O ( l ) Δ H = + 6.00 k J

+ Δ H = Endothermic reaction
- Δ H = Exothermic reaction

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 Examples to illustrate the Second Law
Diffusion of Perfume:

ØOpen a bottle of perfume in one corner of a room.

ØEventually, the scent molecules disperse throughout the room, and you can smell the perfume
from any location.

ØThe spontaneous mixing of perfume molecules represents an increase in entropy, as they spread
out evenly.
Melting Ice Cube:

ØConsider an ice cube in a glass of water at room temperature.

ØAs time passes, the ice cube melts, and the cold ice water mixes with the warmer water.
ØThis process increases the overall entropy in the system, as the initially ordered state (separate ice
and water) transforms into a more disordered state (mixed water).

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The Third Law of Thermodynamics
Ø“the entropy of a system approaches a constant value as the temperature approaches

absolute zero”.

ØAbsolute zero is the point at which molecular motion ceases entirely.

ØAccording to the Third Law of Thermodynamics, as the crystal approaches absolute zero, its

entropy approaches a minimum value, which is typically zero.

ØEntropy is a measure of the disorder or randomness in a system, and at absolute zero, there is

no thermal motion of particles, making the system as ordered as it can possibly be.

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 The Third Law of Thermodynamics

ØSuperconductivity is a phenomenon in which certain materials, when cooled to very low

temperatures, exhibit zero electrical resistance e.g. MRI machines, particle accelerators,

and efficient power transmission lines.

ØThis law is essential for understanding the behaviour of materials at very low

temperatures.

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Free Energy Function
Gibbs free energy (G) and Helmholtz free energy (A)
are functions that describe a system's ability to do
work at constant temperature and pressure.
∆G = ∆H - T∆S
∆G is the change in Gibbs free energy.
∆H is the change in enthalpy (heat) of the system.
Enthalpy Change (∆H): If the energy required to
break the bonds is greater than the energy released
when forming the new bonds, ∆H is positive
(endothermic reaction). If the energy released is
greater, ∆H is negative (exothermic reaction).
T is the temperature in Kelvin.
∆S is the change in entropy (refers to the disorder
or randomness in the system).
helps predict whether a reaction is spontaneous (∆G
< 0) or non-spontaneous (∆G > 0)

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 Thank you

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