Thermodynamics class 11 Notes Chemistry

Table of Contents

myCBSEguide App

Download the app to get CBSE Sample Papers 2024-25, NCERT Solutions (Revised), Most Important Questions, Previous Year Question Bank, Mock Tests, and Detailed Notes.

Install Now

CBSE Chemistry Chapter 6 Thermodynamics class 11 Notes Chemistry in PDF are available for free download in myCBSEguide mobile app. The best app for CBSE students now provides Thermodynamics class 11 Notes Chemistry latest chapter wise notes for quick preparation of CBSE exams and school based annual examinations. Class 11 Chemistry notes on Chapter 6 Thermodynamics class 11 Notes Chemistry are also available for download in CBSE Guide website.

CBSE Guide Thermodynamics class 11 Notes

CBSE guide notes are the comprehensive notes which covers the latest syllabus of CBSE and NCERT. It includes all the topics given in NCERT class 11 Chemistry text book. Users can download CBSE guide quick revision notes from myCBSEguide mobile app and my CBSE guide website.

Thermodynamics class 11 Notes Chemistry

Download CBSE class 11th revision notes for Chapter 6 Thermodynamics class 11 Notes Chemistry in PDF format for free. Download revision notes for Thermodynamics class 11 Notes Chemistry and score high in exams. These are the Thermodynamics class 11 Notes Chemistry prepared by team of expert teachers. The revision notes help you revise the whole chapter in minutes. Revising notes in exam days is on of the best tips recommended by teachers during exam days.

Revision Notes for Class 11 Chemistry Download as PDF

CBSE Class 11 Chemistry Revision Notes Chapter 6 Thermodynamics

Thermodynamic State and Applications
First Law of Thermodynamics
Second Law of Thermodynamics
Third Law of Thermodynamics
Spontaneity and Gibbs Energy Change and Equilibrium

Thermodynamics deals with energy changes in chemical or physical processes and enables us to study these changes quantitatively and to make useful predictions. For these purposes, we divide the universe into the system and the surroundings.

First law of thermodynamics:

is also called as law of conservation of energy. It states that energy can neither be created nor destroyed. It also states that the energy of an isolated system is constant.

Chemical or physical processes lead to evolution or absorption of heat (q), part of which may be converted into work (w).

These quantities are related through the first law of thermodynamics via $\Delta \text{U }=\text{ q }+\text{ w}. \text{ }\Delta \text{U}$ is the change in internal energy. It depends on initial and final states only and is a state function, whereas q and w depend on the path and are not the state functions.

We follow sign conventions of q and w by giving the positive sign to these quantities when these are added to the system. We can measure the transfer of heat from one system to another which causes the change in temperature.

The magnitude of rise in temperature depends on the heat capacity (C) of a substance. Therefore, heat absorbed or evolved is q = CDT. Work can be measured by w = – $P\text{ }\Delta \text{V}$ in case of expansion of gases.

Work done in isothermal and reversible expansion of ideal gas is

W_rev $=- 2.303n\:RT\: log\frac{Vf}{Vi}$

$\Delta \text{U}$ is measured by using special calorimeter called bomb calorimeter.

We define another state function, enthalpy.

The enthalpy of a system may be defined as the sum of the internal energy and the product of its pressure and volume. It is denoted by the symbol H and is given by H = U + PV

An extensive property is a property whose value depends on the quantity or size of matter present in the system. Examples are enthalpy, mass, heat capacity, volume, internal energy, etc.

An intensive property is a property whose value does not depend on the quantity or size of matter present in the system. Examples are temperature, density, pressure, etc.

Specific heat, also called specific heat capacity is the quantity of heat required to raise the temperature of one unit mass of a substance by one degree Celsius (or one Kelvin).

Relation between amount of heat, q, required to raise the temperatures of a sample, specific heat of the substance, c and change in temperatures is given as:

$q=mc\text{ }\Delta \text{T }=C{ }\Delta {{\text{}}{}}\text{T}$

Enthalpy change, can be found directly from the heat changes at constant pressure, $\Delta \text{H }=\text{ }{{\text{q}}_{p}}.~$

There are varieties of enthalpy changes. Changes of phase such as melting, vaporization and sublimation usually occur at constant temperature and can be characterized by enthalpy changes which are always positive.

The enthalpy change accompanying a reaction is called the reaction enthalpy ( ${{\Delta }_{r}}{{H}}$ )
${{\Delta }_{r}}{{H}}$ = (sum of enthalpies of products) – (sum of enthalpies of reactants)

A balanced chemical equation together with the value of it ${{\Delta }_{r}}{{H}^{\Theta }}$ is called a thermochemical equation

Enthalpy of formation, combustion and other enthalpy changes can be calculated using Hess’s law.

Hess’s Law of Constant Heat Summation states:

If a reaction takes place in several steps then its standard reaction enthalpy is the sum of the standard enthalpies of the intermediate reactions into which the overall reaction may be divided at the same temperature

Enthalpy change for chemical reactions can be determined by

${{\Delta }_{r}}H=\sum\limits_{f}^{{}}{({{a}_{t}}}{{\Delta }_{f}}{{H}_{products}})-\sum\limits_{t}^{{}}{({{b}_{t}}{{\Delta }_{f}}{{H}_{reactions}})}$

And in gaseous state by

${{\Delta }_{r}}{{H}^{\Theta }}=\sum\limits_{{}}^{{}}{{}}$ bond enthalpies of the reactants – $\sum\limits_{{}}^{{}}{{}}$ bond enthalpies of the products.

First law of thermodynamics does not guide us about the direction of chemical reactions i.e., what is the driving force of a chemical reaction. For isolated systems, DU = 0.

Born-Haber Cycle

is used to determine lattice enthalpy of ionic compounds since they cannot be determined by experiment directly.

The lattice enthalpy of an ionic compound is the enthalpy change which occurs when one mole of an ionic compound dissociates into its ions in gaseous state

We define another state function, S, entropy for this purpose.

Second Law of thermodynamics states that the entropy of the universe is continously increasing due to spontaneous processes taking place in it.

Entropy (S) is a measure of disorder or randomness. For a spontaneous change, total entropy change is positive. Therefore, for an isolated system, DU = 0, DS > 0, so entropy change distinguishes a spontaneous change, while energy change does not. Entropy changes can be measured by the equation $\Delta \text{S }=~\frac{{{q}_{rev}}}{T}~$ for a reversible process. $\frac{{{q}_{rev}}}{T}~$ is independent of path.

Chemical reactions are generally carried at constant pressure, so we define another state function.

Gibbs energy,

G, which is related to entropy and enthalpy changes of the system by the equation:

$\;{\Delta _r}{\text{G }} = {\text{ }}{\Delta _r}H-\;{\text{T }}{\Delta _r}{\text{S}}$

For a spontaneous change $\Delta {{\text{G}}_{sys}}~<\text{ }0$ and at equilibrium, $\Delta {{\text{G}}_{sys}}~=\text{ }0.$

If $\Delta {{\text{G}}_{sys}}~>\text{ }0$ , process is non-spontaneous.

Standard Gibbs energy change is related to equilibrium constant by

$\;{\Delta _1}{{\text{G}}^\theta }{\text{ }} = {\text{ }}-\;R{\text{T In K}}{\text{.}}$

K can be calculated from this equation, if we know ${{\Delta }_{r}}{{\text{G}}^{\theta }}$ which can be found from ${{\Delta }_{r}}{{\text{G}}^{\theta }}\text{=}{{\Delta }_{r}}{{\text{H}}^{\theta }}\text{-T}{{\Delta }_{r}}{{\text{S}}^{\theta }}$ .

Temperature is an important factor in the equation. Many reactions which are non-spontaneous at low temperature, are made spontaneous at high temperature for systems having positive entropy of reaction.

Thermodynamics class 11 Notes

CBSE Revision notes (PDF Download) Free
CBSE Revision notes for Class 11 Chemistry PDF
Revision notes Class 11 Chemistry – CBSE
CBSE Revisions notes and Key Points Class 11 Chemistry
Summary of the NCERT books all chapters in Chemistry class 11
Short notes for CBSE class 11th Chemistry
Key notes and chapter summary of Chemistry class 11
Quick revision notes for CBSE exams

CBSE Class 11 Revision Notes and Key Points

Thermodynamics class 11 Notes Chemistry. CBSE quick revision note for class-11 Chemistry, Physics, Maths, Biology and other subject are very helpful to revise the whole syllabus during exam days. The revision notes covers all important formulas and concepts given in the chapter. Even if you wish to have an overview of a chapter, quick revision notes are here to do if for you. These notes will certainly save your time during stressful exam days.

To download Thermodynamics class 11 Notes, sample paper for class 11 Chemistry, Physics, Biology, History, Political Science, Economics, Geography, Computer Science, Home Science, Accountancy, Business Studies and Home Science; do check myCBSEguide app or website. myCBSEguide provides sample papers with solution, test papers for chapter-wise practice, NCERT solutions, NCERT Exemplar solutions, quick revision notes for ready reference, CBSE guess papers and CBSE important question papers. Sample Paper all are made available through the best app for CBSE students and myCBSEguide website.

Test Generator

Create question paper PDF and online tests with your own name & logo in minutes.

Create Now

myCBSEguide

Question Bank, Mock Tests, Exam Papers, NCERT Solutions, Sample Papers, Notes

Install Now

Thermodynamics class 11 Notes Chemistry

myCBSEguide App

CBSE Guide Thermodynamics class 11 Notes

Thermodynamics class 11 Notes Chemistry

CBSE Class 11 Chemistry Revision Notes Chapter 6 Thermodynamics

First law of thermodynamics:

$q=mc\text{ }\Delta \text{T }=C{ }\Delta {{\text{}}{}}\text{T}$

Hess’s Law of Constant Heat Summation states:

Born-Haber Cycle

Gibbs energy,

Thermodynamics class 11 Notes

CBSE Class 11 Revision Notes and Key Points

Test Generator

myCBSEguide

Related Posts

Leave a Comment