The main aim of this module is to equip students with an understanding of basic kinetics and thermodynamics as they relate to chemical reactions.

By the end of the module students should be familiar with, and be able to make appropriate use of:

• Basic ideas of energy changes in chemical reactions
• Ideas relating to the rates of chemical reactions
• Basic laboratory skills and report writing, including data and error analysis

Lecture - Lecture

Tutorial - Workshop

Five workshops

Laboratory Work - Laboratory Work

Lecture Material

Thermodynamics [mostly energy changes in chemical reactions]

• ideal gas equation, including definitions/units of pressure, temperature, mole and standard conditions (& use of PV=nRT in context of le Chatelier, with "reminders" of K_c and K_p); intermolecular forces (and mention of van der Waals equation);
• conservation of energy, including heat & work vs internal energy (state function);
• definition of enthalpy, plus formation & combustion reactions, Hess'' law cycles, and so on;
• qualitative idea of entropy (and of its variation from solid to liquid to gas) and the idea of a "natural" direction of change;
• definition of Gibbs energy, various examples of ΔG reactions, relationship of ΔG to K;
• pH and pKa; buffer solutions;
• temperature dependence of lnK (done graphically);
• Nernst equation;
• Trouton''s rule; intermolecular forces in gases and the van der Waals equation of state.

Kinetics

• idea of rates of chemical reactions and of factors that determine them;
• orders of reactions; 0th order 1st order and (simple) 2nd order reactions, including how data are manipulated;
• initial rates;
• half life, using traditional 1st order examples;
• activation energy barriers and temperature dependence, including Arrhenius equation & variation of lnk wit h 1/T (done graphically);
• kinetic isotope effects;
• elementary step, rate-determining step & reaction mechanism;
• chain reactions;
• catalysis, including industrial examples; Lineweaver-Burk plots & Michaelis-Menten model (enzymes).

Tutorial Material

• The lecture course will be supported by fortnightly tutorial (workshop) sessions designed to give students an opportunity to practise solving kinetics and thermodynamics problems

Laboratory Material

• The lab-related workshop session will be devoted mostly to transferable skills: data and error analysis. It includes a mock experimental write up which students will have to completed in th eir own time, with a deadline before they start any laboratory work.
• In the subsequent five laboratory sessions, students will carry out two kinetics experiements and three thermodynamics experiment. These experiments will be designed so as to allow students to finish the experimental work in one three-hour session. Some of the analysis (as well as the formal report) will then have to be completed in their own time, with a deadline before their next lab session; they will be encouraged to make appropriate use of the demonstrators to deal with any questions/problems that arise. There are compulsory pre-lab activities associated with each of the practical sessions.