Chem.211                  States of Matter and Chemical Kinetics                          3+1

               LEARNING OBJECTIVES:


               The objective of this course is
                     to  develop  understanding  of  basic  and  advanced  concepts  regarding  gases,  liquids  and
                       solids.
                     to study the similarity and differences between the different states of matter and reasons
                       responsible for these.
                     to develop skills for working in physical chemistry laboratory.

               LEARNING OUTCOMES:

               By the end of the course, the students will be able to:
                     Derive mathematical expressions for different properties of gas and liquid and understand
               their physical significance.
                     Apply the concepts of gas equations and liquids while studying other chemistry courses
               and everyday life.
                     Handle stalagmometer and Ostwald viscometer properly.
                     Determine the density of aqueous solutions.

               THEORY (45 Hours)

               UNIT – I                                                                           (24 Hours)

               Gaseous state
               Kinetic Theory of gases- postulates and derivation of kinetic gas equation, Maxwell distribution
               of molecular velocities and its use in evaluating average, root mean square and most probable
               velocities and average  kinetic energy. Definition, expression, applications  and temperature  and
               pressure dependence of each one of the following properties of ideal gases: Collision frequency,
               Collision  diameter,  Mean  free  path.  Coefficient  of  viscosity,  definition,  units  and  origin  of
               viscosity of gases, relation between mean free path and coefficient of viscosity, temperature and
               pressure dependence of viscosity of a gas, calculation of molecular diameter from viscosity
               Barometric  distribution  law,  its  derivation  and  applications,  alternative  forms  of  barometric
               distribution law in terms of density and number of molecules per unit volume, effect of height,
               temperature and molecular mass of the gas on barometric distribution
               Behaviour  of  real  gases-  Compressibility  factor,  Z,  Variation  of  compressibility  factor  with
               pressure at constant temperature (plot of Z vs P) for different gases ( H 2, CO 2, CH 4 and NH 3),
               Cause of deviations from ideal gas behaviour and explanation of the observed behaviour of real
               gases in the light of molecular interactions
               van der Waals equation of state,Limitations of ideal gas equation of state and its modifications in
               the form of derivation of van der Waal equation, Physical significance of van der Waals constants,
               application of van der Waal equation to explain the observed behaviour of real gases.
               Isotherms  of  real  gases-  Critical  state,  relation  between  critical  constants  and  van  der  Waals
               constants,  correlation  of  critical  temperature  of  gases  with  intermolecular  forces  of  attraction,
               Continuity of states, Limitations of van der Waals equation, Reduced equation of state and law of
               corresponding states (statement only).
               Virial  equation  of  state-Physical  significance  of  second  and  third  virial  coefficients,  van  der
               Waals equation expressed in virial form, Relations between virial coefficients and van der Waals
               constants




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