The document introduces approaches to reconstructing past environments from geological records, which provide evidence of environmental variation and change over time. Key points include:
1) The geological record reveals periods of both local and global environmental change through features like sediment cycles and extinction events.
2) Fossils are very useful proxies for indicating environmental conditions, and microfossil analysis can provide information about factors like temperature and ocean chemistry.
3) Reconstructing past environments is challenging and uncertain, but tools like isotope analysis of microfossils have improved understanding of global environmental shifts.
Energy Resources. ( B. Pharmacy, 1st Year, Sem-II) Natural Resources
An introduction to environmental change
1. Introduction toEnvironmental Change Professor Simon K. Haslett Centre for Excellence in Learning and Teaching Simon.haslett@newport.ac.uk 7th May 2010
2. Introduction The global environment is transient. No such thing as ‘normal’ environmental conditions. Environmental variation within the historic period, scientific reconstruction of prehistoric environments, and the geological record provide evidence for this. In this presentation, approaches to reconstructing past environments and events are examined.
3. Geological Record The geological record provides information about past or palaeo-environments that is essential for placing the present environment in context, and for predicting future environments. However, in interpreting the geological record it is important to distinguish between evidence that indicates global environmental change rather than local factors.
4. Geological Record For example, through the Phanerozoic (550 Ma-present) the area of the Earth now known as the British Isles has drifted northwards from a high-latitudinal position in the southern hemisphere to its present location in the northern hemisphere. On route, it has passed through many different climatic zones. Therefore, much of the British geological record reflects where the ‘British Isles’ was at a particular time.
5. Geological Record Nevertheless, there are still certain features present. These features are usually more subtle and superimposed on the drift record, which cannot be explained by the drift model. They include: Sediment cycles in the Lower Lias (Jurassic). The deposition of the Chalk. The extinction of many taxa, including the dinosaurs at the end of the Cretaceous (K-T Boundary); and The waxing and waning of ice ages within the last two million years. Evidence for these events are not only found in British geology, but in other countries on other continents, which were in different locations on the globe at the time the events took place. These events indicate periods of global environmental change.
6. Sediment cycles in the Lower Lias (Jurassic) Milankovitch Cycles are evident in geological sequences, such as the alternating limestone and shale of the Lower Lias. Lias-type site; Saltford, Somerset, UK.
7. Deposition of chalk Deposition of calcareous microplankton on seabed. Represents carbon drawdown from atmosphere (sequestration). Chalk is a carbon sink. Contributed to end-Cretaceous global cooling. St. Margaret’s Bay, nr Dover, Kent, UK.
8. K-T Boundary Cretaceous-Tertiary (K-T) Boundary characterised by lithological and biological change. Iridium spike at the Boundary suggests an extra-terrestrial impact as the cause of global change. Could have produced a ‘nuclear winter’ scenario. Impact crater located at Chicxulub, Mexico. The K-T Boundary section at Bidart, SW France
9. K-T Boundary Extinction event identified at K-T Boundary. E.g. planktonic foraminifera undergo an almost complete faunal turnover. A diverse Cretaceous fauna becomes extinct. Replaced by a reduced number (initially) of Tertiary taxa.
10. K-T Boundary Other organisms also become extinct e.g. dinosaurs. But the impact may have been the final straw only, as chalk deposition and the eruption of the volcanic Deccan Traps in India all coincided with the end-Cretaceous. The K-T Boundary section at Zumaya, Spain (the boundary is in front of the person on the bottom left).
11. Waxing and waning of ice ages Milankovitch Cycles (mainly eccentricity) dictate 100-kyr climate cycles in the mid-late Quaternary. Characterised by long cold stages (glacials) interspersed by shorter warm intervals (interglacials). Glaciation was widespread in high latitudes during many glacial stages, and corresponded to pluvial events in the lower latitudes. Glaciated landscape of the Alps, Switzerland
12. Reconstructing Environments Reconstructing environments from the geological record is fraught with difficulty and uncertainty. The main interpretative method is through the use of environmental proxies, components in rocks or sediment which indicate the depositional environment. Proxies include rock or sediment chemistry, mineralogy or sedimentology. One of the most useful and widely used proxies are fossils.
13. Fossils in the Geological Record Many fossils found in the later geological record are the same or closely related to living organisms. If the environmental parameters required by a modern organism are known, it is not unreasonable to assume that a fossil of the same organism required similar conditions to live. Inoceramid bivalve, Cretaceous, Sopelana, Spain
14.
15. Often abundant and possess niche-specific ecology.Foraminifera (protozoa) Radiolaria (protozoa) Diatoms (algae)
16. Fossils in the Geological Record In addition to direct evidence, such as the presence or absence of a particular species, analysis of the shell of some microfossils can also yield environmental information e.g. geochemistry. For example, isotope analysis of foraminifera shells has revolutionized some aspects of global environmental reconstruction. Isotope analysis may be performed on micro- and macrofossils (e.g. corals, snails), and ice cores.
17. Summary There is no such thing as ‘normal’ environmental conditions. The geological record and reconstruction of prehistoric environments demonstrates this. The geological record is essential for placing the present environment in context. Features and events in the geological record indicate periods of local and global environmental change. Reconstructing environments from the geological record is fraught with difficulty and uncertainty. Fossils are the most useful and widely used indicators of change. Analysis of microfossil shells can also yield environmental information.
18. Further Reading Haslett, S.K. 1994. Planktonicforaminiferalbiostratigraphy and palaeoceanography of the Cretaceous-Tertiary boundary section at Bidart, south-west France. Cretaceous Research, 15: 179-192. Haslett, S.K. ed. 2002. Quaternary Environmental Micropalaeontology. Arnold, 340pp. (especially chapters 1 and 11). Pickering, K.T. & Owen, L.A. 1997. An Introduction to Global Environmental Issues (2nd Edition). Routledge, 512pp. (read pp. 8-13, 21-26, 32, 39-41, 43-44, Box 2.1, Box 2.2).
19. This resource was created by the University of Wales, Newport and released as an open educational resource through the 'C-change in GEES' project exploring the open licensing of climate change and sustainability resources in the Geography, Earth and Environmental Sciences. The C-change in GEES project was funded by HEFCE as part of the JISC/HE Academy UKOER programme and coordinated by the GEES Subject Centre. This resource is licensed under the terms of the Attribution-Non-Commercial-Share Alike 2.0 UK: England & Wales license (http://creativecommons.org/licenses/by-nc-sa/2.0/uk/). All images courtesy of Professor Simon Haslett. However the resource, where specified below, contains other 3rd party materials under their own licenses. The licenses and attributions are outlined below: The name of the University of Wales, Newport and its logos are unregistered trade marks of the University. The University reserves all rights to these items beyond their inclusion in these CC resources. The JISC logo, the C-change logo and the logo of the Higher Education Academy Subject Centre for the Geography, Earth and Environmental Sciences are licensed under the terms of the Creative Commons Attribution -non-commercial-No Derivative Works 2.0 UK England & Wales license. All reproductions must comply with the terms of that license.