Spontaneity in Thermodynamics – Spontaneous reaction & Gibbs Equation

According to the First Law of Thermodynamics, the total energy of an isolated system always remains constant.

The first law explains the relationship between the work done by the system or by the system and the heat absorbed without putting any limitation on the direction of heat flow.

However, all processes which occur naturally tend to proceed spontaneously in one direction only. What does spontaneity mean here? What factors determine the direction of a spontaneous change?

What is Spontaneity?

Naturally, all processes have a tendency to occur in one direction under a given set of conditions. A spontaneous process is an irreversible process and it could only be reversed by some external agents. The entropy of any system is defined as the degree of randomness in it.

Predicting the spontaneity of a reaction

Generally, the total entropy change is the essential parameter which defines the spontaneity of any process.

Since most of the chemical reactions fall under the category of a closed system and open system; we can say there is a change in enthalpy too along with the change in entropy.

Since, change in enthalpy also increases or decreases the randomness by affecting the molecular motions, entropy change alone cannot account for the spontaneity of such a process.

Therefore, for explaining the spontaneity of a process we use the Gibbs energy change. Gibbs’ energy is a state function and an extensive property.

The general expression for Gibbs energy change at constant temperature is expressed as:

Gibbs Equation ⇒

ΔGsys = ΔHsys – TΔSsys

Where,

ΔGsys = Gibbs energy change of the system

ΔHsys = enthalpy change of the system

ΔSsys = entropy change of the system

= Temperature of the system

This is known as the Gibbs equation.

For a spontaneous process, the total entropy change, ΔStotal is always greater than zero.

ΔStotalSsys + ΔSsurr

Where,

ΔStotal= total entropy change for the process

ΔSsys = entropy change of the system

ΔSsurr = entropy change of the surrounding

The change in temperature between the system and the surroundings in the case of thermal equilibrium between the system and surroundings is 0, i.e. ΔT= 0. Thus, enthalpy lost by the system is gained by the surrounding. Hence, the entropy change of the surrounding is given as,

According to the First Law of Thermodynamics, the total energy of an isolated system always remains constant.

ΔHsurr = change in enthalpy of the surrounding

ΔHsys = change in enthalpy of the system

Also, for a spontaneous process, the total change in entropy is 0,

i.e. ΔStotal > 0.

Therefore;

TΔSsys – ΔHsys>0

ΔHsys– TΔSsys<0

Using the Gibbs equation, it can be said that

ΔGsys < 0

Thus, it can be inferred that any process is spontaneous if the change in Gibbs energy of the system is less than zero or else the process is not spontaneous.

Therefore, with the help of the above relation, the spontaneity of a reaction can be easily predicted.

  • In the case of exothermic reactions, the enthalpy of the system is negative thereby making all exothermic reactions spontaneous.
  • In the case of endothermic reactions, Gibbs free energy becomes negative only when the temperature is very high or the entropy change is very high.

Frequently Asked Questions – FAQs

Q1

How is a reaction spontaneous?

Reactions are favourable when they result in a decrease in enthalpy and an increase in entropy of the system. When both of these conditions are met, the reaction occurs naturally. A spontaneous reaction is a reaction that favours the formation of products at the conditions under which the reaction is occurring.

Q2

Which chemical reaction is always spontaneous?

A reaction which is exothermic (ΔH negative) and results in an increase in the entropy of the system (ΔS positive) will always be spontaneous.

Q3

Which process is spontaneous?

A spontaneous process is one that occurs on its own, without any energy input from the outside. For example, a ball will roll down an incline; water will flow downhill; ice will melt into water; radioisotopes will decay, and the iron will rust.

Q4

Name two factors which favour a spontaneous reaction.

Enthalpy is the total heat content of the system. Entropy is the measurement of randomness of the system. change in enthalpy and change in entropy should be positive for a reaction to be spontaneous.

Q5

What is a spontaneous and non-spontaneous reaction?

A spontaneous process is capable of proceeding in a given direction without needing to be driven by an outside source of energy. An endergonic reaction (also called a nonspontaneous reaction) is a chemical reaction in which the standard change in free energy is positive and energy is absorbed.

Er. Neeraj K.Anand is a freelance mentor and writer who specializes in Engineering & Science subjects. Neeraj Anand received a B.Tech degree in Electronics and Communication Engineering from N.I.T Warangal & M.Tech Post Graduation from IETE, New Delhi. He has over 30 years of teaching experience and serves as the Head of Department of ANAND CLASSES. He concentrated all his energy and experiences in academics and subsequently grew up as one of the best mentors in the country for students aspiring for success in competitive examinations. In parallel, he started a Technical Publication "ANAND TECHNICAL PUBLISHERS" in 2002 and Educational Newspaper "NATIONAL EDUCATION NEWS" in 2014 at Jalandhar. Now he is a Director of leading publication "ANAND TECHNICAL PUBLISHERS", "ANAND CLASSES" and "NATIONAL EDUCATION NEWS". He has published more than hundred books in the field of Physics, Mathematics, Computers and Information Technology. Besides this he has written many books to help students prepare for IIT-JEE and AIPMT entrance exams. He is an executive member of the IEEE (Institute of Electrical & Electronics Engineers. USA) and honorary member of many Indian scientific societies such as Institution of Electronics & Telecommunication Engineers, Aeronautical Society of India, Bioinformatics Institute of India, Institution of Engineers. He has got award from American Biographical Institute Board of International Research in the year 2005.