8251 modules
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BIOL6069 2028-29
Advanced Field Research Project
The aim of this module is to allow students to carry out an extensive field-based research project on a specific topic related to his/her main area of study. -
BIOL6069 2030-31
Advanced Field Research Project
The aim of this module is to allow students to carry out an extensive field-based research project on a specific topic related to his/her main area of study. -
BIOL6069 2029-30
Advanced Field Research Project
The aim of this module is to allow students to carry out an extensive field-based research project on a specific topic related to his/her main area of study. -
FEEG6010 2030-31
Advanced Finite Element Analysis
This module is aimed at providing exposure to and understanding of advanced, specialist areas of Finite Element Analysis and their underlying Solid/Structural Mechanics concepts. It then
concentrates on using this knowledge for solving discipline-specific engineering problems employing commercial Finite Element Analysis software. -
FEEG6010 2025-26
Advanced Finite Element Analysis
This module is aimed at providing exposure to and understanding of advanced, specialist areas of Finite Element Analysis and their underlying Solid/Structural Mechanics concepts. It then
concentrates on using this knowledge for solving discipline-specific engineering problems employing commercial Finite Element Analysis software. -
FEEG6010 2026-27
Advanced Finite Element Analysis
This module is aimed at providing exposure to and understanding of advanced, specialist areas of Finite Element Analysis and their underlying Solid/Structural Mechanics concepts. It then
concentrates on using this knowledge for solving discipline-specific engineering problems employing commercial Finite Element Analysis software. -
FEEG6010 2028-29
Advanced Finite Element Analysis
This module is aimed at providing exposure to and understanding of advanced, specialist areas of Finite Element Analysis and their underlying Solid/Structural Mechanics concepts. It then
concentrates on using this knowledge for solving discipline-specific engineering problems employing commercial Finite Element Analysis software. -
FEEG6010 2029-30
Advanced Finite Element Analysis
This module is aimed at providing exposure to and understanding of advanced, specialist areas of Finite Element Analysis and their underlying Solid/Structural Mechanics concepts. It then
concentrates on using this knowledge for solving discipline-specific engineering problems employing commercial Finite Element Analysis software. -
MATH3072 2027-28
Advanced Fluid Dynamics
Modelling fluid flow requires us first to extend vector calculus to include volumes that change with time. This will allow us to rephrase Newton’s second law of motion, that the force is equal to the time derivative of the linear momentum, in a way that can be applied to materials that flow and do not have a constant shape, i.e. to fluids. The final resulting equations are called the Navier-Stokes equations and are at the foundation of all fluid studies, from the microscopic motion of a bacterium to the hypersonic flow around a missile. In this module we will just touch on the simplest of the cases model by them: exact solutions of steady flows, water in a sloping channel, or of time dependent flows, driven by pulsating pressure (like blood flow). We will conclude by studying one of the most intriguing aspects of fluid dynamics, namely surface tension, the phenomenon responsible for the round shape of rain drops or soap bubbles. We will study its physical origin and how to model it in the context of the Navier-Stokes equations; we will finish by considering some fluid configurations where surface tension plays a dominant role (e.g. the capillary effect and soap bubbles). -
MATH3072 2028-29
Advanced Fluid Dynamics
Modelling fluid flow requires us first to extend vector calculus to include volumes that change with time. This will allow us to rephrase Newton’s second law of motion, that the force is equal to the time derivative of the linear momentum, in a way that can be applied to materials that flow and do not have a constant shape, i.e. to fluids. The final resulting equations are called the Navier-Stokes equations and are at the foundation of all fluid studies, from the microscopic motion of a bacterium to the hypersonic flow around a missile. In this module we will just touch on the simplest of the cases model by them: exact solutions of steady flows, water in a sloping channel, or of time dependent flows, driven by pulsating pressure (like blood flow). We will conclude by studying one of the most intriguing aspects of fluid dynamics, namely surface tension, the phenomenon responsible for the round shape of rain drops or soap bubbles. We will study its physical origin and how to model it in the context of the Navier-Stokes equations; we will finish by considering some fluid configurations where surface tension plays a dominant role (e.g. the capillary effect and soap bubbles).