Postgraduate Course: Adsorption (MSc) (PGEE11081)
|School||School of Engineering
||College||College of Science and Engineering
|Credit level (Normal year taken)||SCQF Level 11 (Postgraduate)
||Availability||Available to all students
|Summary||The course will cover the basic principles of adsorption and
adsorption separation processes including both equilibrium and
dynamic modelling and a brief overview of representative
industrial processes. The main topics will be:
Forces and energetics of adsorption;
Adsorption equilibrium (including both single and
Adsorbent materials (with emphasis on zeolites and activated
Sorption kinetics and measurement of transport properties;
Adsorption Column Dynamics (including linear, non-linear and
Adsorption Separation processes (choice of regeneration
methods, pressure swing, thermal swing and displacement
Membrane Processes (brief introduction)
The relationship between the properties of the adsorbent and
the process applications will be emphasized.
This course comprises 20 hours of lectures assessed by written examination and coursework.
The course is delivered in two hour lectures.
Importance of adsorption in a separation process
Advantages and limitations
Forces and Energetics of Adsorption
Physical adsorption vs. chemisorption
van der Waals forces
Heats of adsorption
Selectivity and capacity
Carbons; Aluminas; Silica Gels; Zeolites; MOFs
Representation of equilibrium data
Monte Carlo simulation of adsorption equilibrium
Langmuir, dual site Langmuir and Freundlich
Isosteric heat of adsorption
Multicomponent Adsorption Equilibrium
Extended Langmuir isotherms
Thermodynamic consistency of multicomponent
Ideal Adsorbed Solution Theory (IAST)
Limits on applicability of IAST
Characterization of Adsorbents
BET isotherm and area measurement
Capillary Condensation and the Kelvin equation
Measurement of pore size distributions
Gravimetric, volumetric and chromatographic
measurement of adsorption isotherms.
Diffusion in Porous Solids
Mass transport mechanisms
Range of diffusivities
Definitions and relationship between the various
Chemical potential as driving force
Diffusion in macro/mesopores.
Measurement of Diffusion in Porous Solids
Classification of experimental methods
Microscopic (PFG NMR, QENS, Neutron Spin-Echo)
Mesoscopic (Single crystal membrane, FTSR and
FR, Chromatography, TAP, effectiveness factor
Examples from literature of incorrect interpretation of kinetic experiments.
Analytical solution to the diffusion equation with surface resistance.
Separation of variables.
Properties of Laplace transforms.
Asymptotic limits and moments of solutions.
Inversion of solution using the method or residues.
Numerical solution using finite differences.
The Linear Driving Force model
Equivalence to the diffusion equation
Limitations at fast cycle times
Adsorption Column Dynamics
Mass balance equation
Danckwerts boundary conditions
Equilibrium theory - isothermal single transition
Qualitative treatment from wave theory perspective
Moments and HETP
Constant and proportional pattern behaviour
Adsorption Column Dynamics
Equilibrium theory - isothermal multicomponent
Solution for extended Langmuir isotherm
Equilibrium theory - non-isothermal systems
Watershed point and temperature swing adsorption
Adsorption Separation Processes
Regeneration methods - T Swing, P Swing and
Cyclic batch vs continuous counter-current operation
Equilibrium vs Kinetic selectivity
Trace impurity removal
Pressure Swing Adsorption Processes
Cycles and energy efficiency
PSA oxygen process
PSA nitrogen process (carbon molecular sieve)
Countercurrent and Simulated Countercurrent Processes
Adsorbent circulation - Hypersorption, Pursiv
UOP Simulated Moving Bed Sorbex Process
Triangle theory of SMBs
Completion of Course
Review and open discussion.
Each lecture has corresponding self-study materials.
Entry Requirements (not applicable to Visiting Students)
||Other requirements|| None
Information for Visiting Students
|High Demand Course?
Course Delivery Information
|Not being delivered|
| Students attending this course should gain:
1. An understanding of the fundamental equilibrium and
transport properties in adsorption.
2. A capability to model transient adsorption processes.
3. An understanding of the basic design of adsorption systems.
|Graduate Attributes and Skills
|Keywords||Adsorption,Separation,emissions,molecular simulation,CCS Carbon Capture
|Course organiser||Prof Stefano Brandani
|Course secretary||Mrs Shona Barnet
Tel: (0131 6)51 7715