Postgraduate research opportunities The automated construction of thermodynamic models for complex mixtures
ApplyKey facts
- Opens: Thursday 22 February 2024
- Deadline: Monday 31 March 2025
- Number of places: 1
- Duration: 3 years
Overview
The project aims to develop a machine learning framework to construct accurate mathematical representations of the thermodynamics of complex multicomponent mixtures. This will provide an automated system to specify the precise sequence of experiments that will most efficiently provide the information to continuously improve the accuracy of thermodynamic models.Eligibility
Students applying should have (or expect to achieve) a minimum 2.1 undergraduate degree in a relevant engineering/science discipline, and be very motivated to undertake highly multidisciplinary research.
Project Details
Process design requires accurate and reliable thermodynamic data for multicomponent mixtures in the system over a wide range conditions (e.g., solvents, impurity concentrations, temperatures, pressures) which are often missing, especially for new compounds. These data can be obtained by performing a multitude of measurements across a broad range of conditions; however, this is time consuming, expensive and requires significant quantities of material which may not be available. Thermodynamic models can be used to estimate these data; however, they have limited accuracy and reliability, especially for compounds and process conditions not previously encountered. In principle, some of these models can be successively improved by incorporating additional experimental measurements. This project aims to develop an automated system that will specify the precise sequence of experiments that will most efficiently provide the information to produce an accurate thermodynamic model of complex, multicomponent mixtures. The proposed work will use machine learning to develop an automated methodology to efficiently construct accurate mathematical representations of the thermodynamics of complex multicomponent mixtures. This will provide engineers and scientists a novel system to determine the optimal experimental measurements that will most effectively improve the thermodynamic model and yield most accurate predictions. It will radically improve our ability to rapidly and efficiently construct accurate thermodynamic models, which is key to the development of any chemical manufacturing process.
In addition to undertaking cutting edge research, students are also registered for the Postgraduate Certificate in Researcher Development (PGCert), which is a supplementary qualification that develops a student’s skills, networks and career prospects.
Further information
This PhD project is initially offered on a self-funding basis. It is open to applicants with their own funding, or those applying to funding sources. However, excellent candidates will be eligible to be considered for a University scholarship.
The University of Strathclyde is a socially progressive institution that strives to ensure equality of opportunity and celebrates the diversity of its student and staff community. Strathclyde is people-oriented and collaborative, offering a supportive and flexible working culture with a deep commitment to our equality, diversity and inclusion charters, initiatives, groups and networks.
We strongly encourage applications from Black, Asian and minority ethnicity, women, LGBT+, and disabled candidates and candidates from lower socio-economic groups and care-experienced backgrounds.
Apply
Number of places: 1
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Chemical and Process Engineering
Programme: Chemical and Process Engineering
Contact us
- chemeng-pg-admissions@strath.ac.uk
- James Weir Building, 75 Montrose Street, Glasgow, G1 1XJ