West of Scotland Supercomputing Centre for Academia and Industry (Capital)
Lead Research Organisation:
University of Strathclyde
Department Name: Pure and Applied Chemistry
Abstract
This proposal is for an academia-industry High Performance Computing (HPC) regional centre for the West of Scotland that will be based at the University of Strathclyde. The other universities involved in the consortium are Glasgow, Glasgow Caledonian, West of Scotland and Stirling. The centre will provide a step-change in HPC provision within a community where academia collaborates most effectively with national and international industry, bringing enhanced business competitiveness and innovation opportunities through collaborative research and industrial product design and simulation.
A key component of our strategy is to provide a completely integrated package of HPC resource, support and training service locally, so that industries are more directly attracted to where the work is being performed, and can interact with the HPC experts and associated support. Personal interactions are crucial to both the initial engagement and for the development of longer-term strategic partnerships as relationships mature, building trust and confidence in the academic expertise and the benefits derived from access to HPC capability.
New, additive university collaborations and industry-university research partnerships in the Manufacturing, Energy, Health Technologies, and Physical Sciences priority areas will be made possible by the centre. Industries and other organisations working in these sectors will benefit from service provision access to the HPC facilities, as well as from opportunities for joint research and development that requires high performance computing.
In recognising that a "one size fits all" approach to industrial user engagement will not work, we will adopt a flexible approach to hosting and prioritising one-off/pump priming contract research in the HPC Centre, as well as develop long-lasting collaborative research relationships on a variety of problems. Participation in and by consortia involving other organisations with common interests (e.g. SMEs, and enterprise and economic development agencies) will also be strongly encouraged.
The management structure of the centre ensures that key industrial and academic stakeholders on the Advisory Board will be directly involved in steering the centre. The centre will have the agility to modify its access and operational plans, as well as its CPD and outreach activities, to ensure it remains focused on achieving its goals. This agility is not easily achieved in larger operations encumbered by entrenched practices and competing strategic priorities. The Centre's Director and operational team will facilitate cooperation between partner academics and industrialists, ensuring the right skills and expertise are brought to bear on all industrial needs, and that the advantages of high-performance computing for design and innovation are immediately apparent to both new and existing industrial users.
The centre's mission is to ensure that the best scientific and engineering research and development is deployed to full societal benefit by working closely with industry and academic partners. The alignment of the Centre to this mission guarantees its sustainability, and the continuing commitment of the host University and its partners will ensure long-term success in delivering its aims and objectives.
A key component of our strategy is to provide a completely integrated package of HPC resource, support and training service locally, so that industries are more directly attracted to where the work is being performed, and can interact with the HPC experts and associated support. Personal interactions are crucial to both the initial engagement and for the development of longer-term strategic partnerships as relationships mature, building trust and confidence in the academic expertise and the benefits derived from access to HPC capability.
New, additive university collaborations and industry-university research partnerships in the Manufacturing, Energy, Health Technologies, and Physical Sciences priority areas will be made possible by the centre. Industries and other organisations working in these sectors will benefit from service provision access to the HPC facilities, as well as from opportunities for joint research and development that requires high performance computing.
In recognising that a "one size fits all" approach to industrial user engagement will not work, we will adopt a flexible approach to hosting and prioritising one-off/pump priming contract research in the HPC Centre, as well as develop long-lasting collaborative research relationships on a variety of problems. Participation in and by consortia involving other organisations with common interests (e.g. SMEs, and enterprise and economic development agencies) will also be strongly encouraged.
The management structure of the centre ensures that key industrial and academic stakeholders on the Advisory Board will be directly involved in steering the centre. The centre will have the agility to modify its access and operational plans, as well as its CPD and outreach activities, to ensure it remains focused on achieving its goals. This agility is not easily achieved in larger operations encumbered by entrenched practices and competing strategic priorities. The Centre's Director and operational team will facilitate cooperation between partner academics and industrialists, ensuring the right skills and expertise are brought to bear on all industrial needs, and that the advantages of high-performance computing for design and innovation are immediately apparent to both new and existing industrial users.
The centre's mission is to ensure that the best scientific and engineering research and development is deployed to full societal benefit by working closely with industry and academic partners. The alignment of the Centre to this mission guarantees its sustainability, and the continuing commitment of the host University and its partners will ensure long-term success in delivering its aims and objectives.
Planned Impact
A wide range of companies will benefit from the formation of the HPC Centre, from large national/multinational organisations with engagement in the West of Scotland such as Rolls Royce, AstraZeneca, ScottishPower and SSE, to local and SME companies such as Sgurr Energy, GSE Systems and Clyde Space Ltd. Over 100 companies participate in the various industry-university consortia at Strathclyde alone. Across all the partner universities, several hundred companies and other organisation will be potential beneficiaries. Access to HPC will provide new company growth and wealth-creating opportunities through collaborative research and industrially relevant design, simulation and modelling. Furthermore, by offering a supercomputing service to industrial partners for product and process design and development, advances will be made in the energy, advanced manufacturing, health technologies and physical sciences sectors that will not only increase the competitiveness of the companies, but also provide health and quality of life benefits in the UK. The timescales for realisation of the industrial benefits could be quite short (under 24 months) especially when targeted towards process improvements, product design, and health care developments. Our experience of effective bridging between TRLs 1-4 and 5-8 will enhance the proposed Centre's impact and maximise the industrial exploitation of research outputs and the HPC facilities. Several companies have already identified areas where the HPC Centre will enhance product/process development:
"large scale wind mapping and short term forecasting of wind energy using the "WRF mesoscale model" for renewable energy applications (Sgurr Energy);
"molecular simulation and modelling expertise and solutions" for materials and life science (Accelrys);
"complex wind flow and turbine driveline system interaction modelling" for offshore wind turbines (David Brown Gear Systems);
"predict the fatigue life of the device and ensure safe performance" for ring stents in endovascular aneurysm repair devices (Terumo Vascutek);
"support the design and simulation work we do" in manufacturing real-time simulators for the Power and Process industries (GSE Systems);
"robust design optimisation and the simulation of large constellation of micro-spacecraft to assess long-term behaviour and coverage patterns" in relation to small satellite technology (Clyde Space Ltd);
"accelerate the introduction of continuous (manufacturing) technologies" in the pharmaceutical industry, and enhance "design of molecules and understanding in-vivo efficacy, exposure and toxicity" (AstraZeneca);
"underpinning research in "collective radiation-beam-plasma interactions at high intensities" using high power lasers ...and in the next generation accelerators" (National Nuclear Laboratory).
To maximise the benefits that companies gain from the centre, the HPC outreach and engagement programme will include a series of industrial user workshops that will be held shortly after commissioning to demonstrate and showcase the HPC facilities through exemplar calculations on real industrial problems. This will align potential industrial users with academics across the partner universities who can provide the best guidance and training on exploiting the opportunities afforded by the HPC centre. We recognise that supercomputing is an enabling resource not only for industry majors, but also for innovative SMEs that often make key supply chain contributions. In order to reach key industrial constituencies that do not presently access the power of supercomputing, current industrial partners of the collaborating universities will be invited to these workshops and encouraged to invite their supply chain and support SMEs. The provision of bespoke executive education and continuous professional development (CPD) will also be beneficial features of the centre and these will be used to drive and stimulate adoption of HPC methodologies by industry.
"large scale wind mapping and short term forecasting of wind energy using the "WRF mesoscale model" for renewable energy applications (Sgurr Energy);
"molecular simulation and modelling expertise and solutions" for materials and life science (Accelrys);
"complex wind flow and turbine driveline system interaction modelling" for offshore wind turbines (David Brown Gear Systems);
"predict the fatigue life of the device and ensure safe performance" for ring stents in endovascular aneurysm repair devices (Terumo Vascutek);
"support the design and simulation work we do" in manufacturing real-time simulators for the Power and Process industries (GSE Systems);
"robust design optimisation and the simulation of large constellation of micro-spacecraft to assess long-term behaviour and coverage patterns" in relation to small satellite technology (Clyde Space Ltd);
"accelerate the introduction of continuous (manufacturing) technologies" in the pharmaceutical industry, and enhance "design of molecules and understanding in-vivo efficacy, exposure and toxicity" (AstraZeneca);
"underpinning research in "collective radiation-beam-plasma interactions at high intensities" using high power lasers ...and in the next generation accelerators" (National Nuclear Laboratory).
To maximise the benefits that companies gain from the centre, the HPC outreach and engagement programme will include a series of industrial user workshops that will be held shortly after commissioning to demonstrate and showcase the HPC facilities through exemplar calculations on real industrial problems. This will align potential industrial users with academics across the partner universities who can provide the best guidance and training on exploiting the opportunities afforded by the HPC centre. We recognise that supercomputing is an enabling resource not only for industry majors, but also for innovative SMEs that often make key supply chain contributions. In order to reach key industrial constituencies that do not presently access the power of supercomputing, current industrial partners of the collaborating universities will be invited to these workshops and encouraged to invite their supply chain and support SMEs. The provision of bespoke executive education and continuous professional development (CPD) will also be beneficial features of the centre and these will be used to drive and stimulate adoption of HPC methodologies by industry.
Organisations
Publications

Yilmaz N
(2019)
An improved Mesh Adaption and Refinement approach to Cavitation Simulation (MARCS) of propellers
in Ocean Engineering

Bonifacio R
(2017)
Design of sub-Angstrom compact free-electron laser source
in Optics Communications

Brown M
(2017)
An extended model of the quantum free-electron laser
in Optics Express

Morgan J
(2022)
X-ray pulse generation with ultra-fast flipping of its orbital angular momentum.
in Optics express

Campbell LT
(2019)
Frequency modulated free electron laser.
in Optics express

Emery KJ
(2017)
Evidence of single electron transfer from the enolate anion of an N,N'-dialkyldiketopiperazine additive in BHAS coupling reactions.
in Organic & biomolecular chemistry

Sasselli IR
(2017)
Molecular dynamics simulations reveal disruptive self-assembly in dynamic peptide libraries.
in Organic & biomolecular chemistry

Ritos K
(2016)
Electric fields can control the transport of water in carbon nanotubes.
in Philosophical transactions. Series A, Mathematical, physical, and engineering sciences

Önskog T
(2015)
An accurate treatment of diffuse reflection boundary conditions for a stochastic particle Fokker-Planck algorithm with large time steps
in Physica A: Statistical Mechanics and its Applications

Van Teijlingen A
(2024)
An active machine learning discovery platform for membrane-disrupting and pore-forming peptides
in Physical Chemistry Chemical Physics

Mancini O
(2018)
Probing beta amyloid aggregation using fluorescence anisotropy: experiments and simulation
in Physical Chemistry Chemical Physics

Koshti B
(2023)
Solvent-controlled self-assembly of Fmoc protected aliphatic amino acids
in Physical Chemistry Chemical Physics

Brandani GB
(2017)
Adsorption of the natural protein surfactant Rsn-2 onto liquid interfaces.
in Physical chemistry chemical physics : PCCP

Urquhart RJ
(2024)
ANI neural network potentials for small molecule pKa prediction.
in Physical chemistry chemical physics : PCCP

Ramos Sasselli I
(2016)
CHARMM force field parameterization protocol for self-assembling peptide amphiphiles: the Fmoc moiety.
in Physical chemistry chemical physics : PCCP

Coles SW
(2017)
The nanostructure of a lithium glyme solvate ionic liquid at electrified interfaces.
in Physical chemistry chemical physics : PCCP

Ruzanov A
(2018)
On the thickness of the double layer in ionic liquids.
in Physical chemistry chemical physics : PCCP

Russell BA
(2015)
Locating the nucleation sites for protein encapsulated gold nanoclusters: a molecular dynamics and fluorescence study.
in Physical chemistry chemical physics : PCCP

Ivaništšev V
(2016)
Molecular origin of high free energy barriers for alkali metal ion transfer through ionic liquid-graphene electrode interfaces.
in Physical chemistry chemical physics : PCCP

Kubiak-Ossowska K
(2015)
Lysozyme adsorption at a silica surface using simulation and experiment: effects of pH on protein layer structure.
in Physical chemistry chemical physics : PCCP

Lage-Estebanez I
(2016)
Self-interaction error in DFT-based modelling of ionic liquids.
in Physical chemistry chemical physics : PCCP

Buyskikh A
(2019)
Resonant two-site tunneling dynamics of bosons in a tilted optical superlattice
in Physical Review A

Yago Malo J
(2018)
Particle statistics and lossy dynamics of ultracold atoms in optical lattices
in Physical Review A

Morgan J
(2021)
Attosecond polarization modulation of x-ray radiation in a free-electron laser
in Physical Review Accelerators and Beams

Garcia B
(2016)
Method to generate a pulse train of few-cycle coherent radiation
in Physical Review Accelerators and Beams

Zhang J
(2015)
Wetting and evaporation of salt-water nanodroplets: A molecular dynamics investigation
in Physical Review E

Nikolaou Z
(2018)
Scalar flux modeling in turbulent flames using iterative deconvolution
in Physical Review Fluids

Dimitrova I
(2020)
Enhanced Superexchange in a Tilted Mott Insulator.
in Physical review letters

Tooley MP
(2017)
Towards Attosecond High-Energy Electron Bunches: Controlling Self-Injection in Laser-Wakefield Accelerators Through Plasma-Density Modulation.
in Physical review letters

Kokkinakis IW
(2019)
Modeling of Rayleigh-Taylor mixing using single-fluid models.
in Physical review. E

Robb G
(2017)
Collective dynamics out of thermodynamic equilibrium.
in Physical review. E

Dongari N
(2013)
Effects of curvature on rarefied gas flows between rotating concentric cylinders
in Physics of Fluids

Germanou L
(2020)
Shale gas permeability upscaling from the pore-scale
in Physics of Fluids

Capobianchi P
(2017)
Walls and domain shape effects on the thermal Marangoni migration of three-dimensional droplets
in Physics of Fluids

Todorova B
(2020)
Numerical evaluation of novel kinetic models for binary gas mixture flows
in Physics of Fluids

Wang E
(2017)
The effect of spacing on the vortex-induced vibrations of two tandem flexible cylinders
in Physics of Fluids

Ritos K
(2017)
Implicit large eddy simulation of acoustic loading in supersonic turbulent boundary layers
in Physics of Fluids

Loupy G
(2017)
Processing and analysis methods for transonic cavity flow
in Physics of Fluids

McKechnie D
(2020)
Glass transition temperature of a polymer thin film: Statistical and fitting uncertainties
in Polymer

Pelizza F
(2019)
A density functional theory study of poly(vinylidene difluoride) crystalline phases
in Polymer

Rahman M
(2013)
Effect of column base strength on steel portal frames in fire
in Proceedings of the Institution of Civil Engineers - Structures and Buildings

Docherty S
(2013)
Boundary conditions for molecular dynamics simulations of water transport through nanotubes
in Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science

Dinwoodie I
(2018)
On modeling insights for emerging engineering problems: A case study on the impact of climate uncertainty on the operational performance of offshore wind farms
in Proceedings of the Institution of Mechanical Engineers, Part O: Journal of Risk and Reliability

Zhang Y.
(2017)
Numerical investigation of shark skin inspired riblet drag reduction structure
in Proceedings of the International Offshore and Polar Engineering Conference

Greenshields C
(2012)
Rarefied hypersonic flow simulations using the Navier-Stokes equations with non-equilibrium boundary conditions
in Progress in Aerospace Sciences

Ansari SM
(2018)
On the effect of mutations in bovine or camel chymosin on the thermodynamics of binding ?-caseins.
in Proteins

Xiao Q
(2012)
How motion trajectory affects energy extraction performance of a biomimic energy generator with an oscillating foil?
in Renewable Energy

Liu Y
(2017)
Establishing a fully coupled CFD analysis tool for floating offshore wind turbines
in Renewable Energy

Dai S
(2019)
Investigation on the hydrodynamic scaling effect of an OWC type wave energy device using experiment and CFD simulation
in Renewable Energy

Zitrou A
(2022)
Modeling Epistemic Uncertainty in Offshore Wind Farm Production Capacity to Reduce Risk.
in Risk analysis : an official publication of the Society for Risk Analysis
Description | The University of Strathclyde has successfully hosted and managed the ARCHIE-WeSt Tier 2 Regional High Performance Computing (HPC) Centre since 2012. ARCHIE-WeSt is a consortium of 5 Universities in the West of Scotland created with £1.3M capital investment from EPSRC. Amongst the key outputs and achievements through this period to date, ARCHIE-WeSt has supported the work of 130 PhD students with substantial computational requirements; facilitated the generation of over 300 academic and conference papers; fostered 35 partnerships between academia and industry; and trained 380 users across fields as diverse as advanced manufacturing, business analytics, spacecraft re-entry, and high energy physics. During the last year, ARCHIE (the computer itself) has been running consistently at 85% capacity with an aggregate of 155 users. Strathclyde has been the primary beneficiary of this facility with researchers from every department across the Faculties of Science & Engineering using the facility to some extent, as well as some users from the department of Economics and Management Science, along with recent expressions of interest from the department of Psychology. During its lifetime, ARCHIE has underpinned a research grant portfolio in excess of £30M across the University, so that ARCHIE-WeSt played an important role in the successes of the 2014 REF results. |
Exploitation Route | N/A |
Sectors | Other |
Title | Bovine Serum Albumin (BSA) Adsorption on Silica |
Description | Data set to accompany the paper "How Negatively Charged Proteins Adsorb to Negatively Charged Surfaces - a Molecular Dynamics Study of BSA Adsorption on Silica". It contains run files for a NAMD simulation, plus a short trajectory file that can be analysed. |
Type Of Material | Database/Collection of data |
Year Produced | 2016 |
Provided To Others? | Yes |
Impact | n/a |