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The effect of extreme climatic change on insect-plant interactions during the Jurassic


Funded PhD


3.5 years

Application deadline:

Monday 7 January 2019

About this project

The increases in atmospheric concentrations of CO2 (pCO2), that are associated with climate change, cause decreases in the nutritional value of plants to the herbivorous insects that feed upon them. In turn these changes in plant quality are a key determinant in the reproduction and survival of herbivorous insects at both the individual and the population scale.

By investigating past geologic periods of global warming with high atmospheric pCO2 we can determine the nature and scale of future changes in insect-plant interactions.

The geological record contains a number of well-documented fossilized insect beds, but the reasons for their distribution through geological time have not yet been examined. Although a relationship between fossil insect accumulations—changes in plants—and changes in atmospheric composition have been suggested they have never been shown.

This project will firstly make a general assessment of insect fossil distribution through both space and time in the Mesozoic, and will then focus on fossil beds found throughout the UK and Europe during the Early Jurassic. We will consider changes in the insect and plant communities before, during and after the early Toarcian (186 million years ago) period extreme environmental change. For instance, during the Toarcian average global temperatures rose by approximately 10°C and large quantities of CO2 were released into the ocean-atmosphere system.

The scale of the changes during the Toarcian event are comparable with the IPCC climate predictions for 2099 under high emissions scenarios. A recent high-resolution geochemical study of the Toarcian in Leicestershire suggests the preservation of insect beds might be linked to key stages of the climatic change.

Additionally, the Coelorrhyncha (true bugs) seem to have evolved during the Toarcian and their modern counterparts would indicate that this may be related to increased humidity and decomposition rates.

The main objectives of this project are to

  1. Test the hypothesis that there is a link between the accumulation of fossilized insects and large increases in global temperatures and pCO2 by collating data from insect beds and comparing these to the record of palaeoenvironmental change from published geochemical proxies.
  2. Assess any variations in the composition of insect communities (type, abundance and diversity) before, during and after the Toarcian event. Firstly, by (a) collecting and identifying insects and assessing insect leaf damage from known successions in Leicestershire, Gloucestershire and Bornholm, Denmark. High-resolution graphic logging, biostratigraphy, elemental abundances and carbon isotope stratigraphy will be produced for these sections as needed. (b) Making observations from significant insect and plant collections from the same field sites now held in museum collections.
  3. Determine whether the nutritional quality of plants changed during the Toarcian event by measuring the leaf mass per area and leaf economic traits of plant matter associated with the insect beds and adjacent strata. These metrics are good indicators of plant C:N ratios (and so nutritional quality) and photosynthetic rates [8-9]. In particular, the Pliensbachian to Toarcian section at Bornholm is suitable for these analyses.
  4. Explore the relationship between changes and/or adaptations in the insect populations and the published records documenting the climatic changes during the Toarcian event (e.g. increased pCO2, an enhanced hydrological cycle, and increased global temperature).

The project will provide training in: (i) geological fieldwork, (ii) stratigraphy, (iii) fossil collection and preparation, (iv) taxonomy, (v) plant functional trait analysis, (vi) geochemistry (elemental abundances and carbon isotopes analyses), (vii) ecology, and (viii) statistics. You will be based in the School of Environmental Sciences at the University of Hull working under the supervision of Dr Bryony Caswell.

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This project is funded by Panorama NERC Doctoral Training Partnership (DTP). They are offering a fully funded 3.5 year studentship (stipend + fees) to both UK and EU applicants at the standard UKRI rate.

We are unable to offer studentships to non-EU international candidates.

Entry requirements

The prospective student should have, or expect to receive, a first class BSc degree, or a distinction at Masters level, in an appropriate discipline.