Earth Scientists often interpret evidence in the geological record using processes that are observed on the present Earth. However, this Principle of Uniformitarianism cannot always be applied to the very early Earth, which may be better understood by consideration of other planets. This module uses a variety of strands of chemical, mathematical and geological evidence to examine more than 4.5 billion years of Earth history, from before the establishment of the dynamic processes that currently rework our planet to the anthropogenic controls on Earth evolution. The course will place the evolution of the Earth in the context of this and other solar systems, and consider the nature of other planets and their planetary processes and atmospheres. The Evolution of the Earth and Planetary Systems module enables you to conceptualise the scales and rates of change on our life-sustaining planet, and to develop view-points and research strategies. It pulls together scientific literature with current affairs to examine the implications for future environmental and societal change.

You will find the course difficult unless you have attended the first level geology module, and the second level igneous and metamorphic module, which are formal prerequisites. It is advantageous to have also completed the second level sedimentology module, though not a formal requirement. This module is not recommended for interdisciplinary pathways unless the prerequisite modules have been studied. There is a strong focus on critical thinking, problem solving and communication skills. The module is suitable for students interested in the subject areas of ancient planetary history or planetary change (and the Anthropocene), in geoscientific research of any kind, and communication of science in the media or relating to current affairs.

The module aims to introduce students to the stellar, planetary and Earth surface systems processes involved in the origin and development of the stratified Earth-Moon system able to support life, using both primary research and summative material. 

The practical component of the module aims to illustrate to students the chemical and mathematical methods that are used to model and interpret planetary processes.

In addition, the module aims to assist students to develop their abilities of scientific critique and presentation of complex concepts.

- the formation of the elements and the solar system;

- meteorites and planetary formation;

- a stratified Earth – Moon system;

- the thermal regime of the Archaean Earth and evolution of the mantle;

- Ancient crust, radiogenic isotopes and the growth of the continents;

- plate tectonics and volcanism throughout the inner solar system;

- Precambrian environments for mineralisation and deposition;

- the origins of life: minerals and oceans;

- development of a life-sustaining planet;

- connected and dynamic Earth surface systems and climate;

- evolution of the Earth in an anthropogenic context.


Practical skills

- uses of phase diagrams, major and trace elements, and isotopes applied to planetary interiors and ancient environments;

- scientific critique and scientific communication.
 

As above 1 piece of CW (presentation, or essay if presentation not possible) 40% and/or 1 Exam 60%
 

Web based and Electronic Resources:

The essential basic to advanced reading is provided on the ELE module page in a folder that accompanies each lecture topic -

ELE: http://vle.exeter.ac.uk/

Reading list for this module: