When I first set foot outside the old Dyce terminal, one cold night of the winter of 2003, I never imagined my life and career would be entangled with this fantastic University, city and country. I was then an Erasmus student, who found in Aberdeen a place where to discover and grow.
Some months after that night, I graduated as a Chemical Engineer at the Universitat Politècnica de València (UPV, 2003), and then pursued a double PhD degree in Chemical Engineering (UPV) and Chemistry (University of Aberdeen) (2010). I also completed the Erasmus Mundus MSc International Master in Materials and Sensors Systems for Environmental Technologies, awarded by both UPV and the University of Bologna (2010).
In 2014 I joined the Department of Chemistry at the University of Aberdeen as a teaching fellow, and in 2015 I became lecturer in Chemical Engineering at the School of Engineering.
As a member of the Chemical and Materials Engineering research group, I am committed to lead Aberdeen in becoming a main player in the energy transition in the UK and overseas. My aim is to integrate research and teaching excellence, through different development areas.
Whether you are a student, colleague, industrialist or an individual with motivation to challenge the state of the art in science and enginering, and from any part of the world, my door will always be open to join forces in this fantastic adventure. Together we thrive.
I work with colleagues from different countries, including the University of Malaya, MARA University of Technology. University of Zaragoza (via research projects and PhD co-supervision), Tokyo University of Science (via the RSC Research Exchange Grant in 2020-2021), Georgian State Teaching University of Physical Education and Sport, University of Nevada Las Vegas, Kent State University, University of Genoa and University of Bologna, among others.
Research GrantsAs principal investigator, PI:
- Multifunctional liquid crystals stabilised by hydrogen-bonding and their integration in new devices for energy harvesting, conversion and storage, SAPHIRE: Funding for Scottish research partnerships with India, Japan and Pakistan, 2020-2021,The Royal Society and Scottish Government, £6,000.
- Ferroelectric liquid crystals stabilised by hydrogen-bonding: towards new energy harvesters, Royal Society Research Grants, 2020-2021, The Royal Society, £12,507.
- Light-responsive ferroelectric liquid crystals stabilised by hydrogen bonding as energy harvesters, International travel grants, 2020-2021, Royal Society of Chemistry, £2,100.
- Add your value, Erasmus+ Key Action 2, Strategical Alliances, 2019-2021, European Commission, £47,179.
- Light-responsive liquid crystalline polymeric electrolytes with high ionic conductivity for energy conversion devices, Research Incentive Grants, 2019-2020, The Carnegie Trust for the Universities of Scotland, £13,963.
- Production of bioenergy and smart materials from palm tree waste in Malaysia, Global Challenges - Internal Pump Research Grant, 2018, University of Aberdeen, £9,850.
- Enhanced Ionic Transport of New Liquid Crystal Materials with Application in Direct Methanol Fuel Cells, Vacation Scholarship Application, 2018, £1,000.
- Performance of polymeric electrolytes in low temperature fuel cells, Chevron development trust, School of Engineering, University of Aberdeen, 2016, £10,000.
- New Candidates for Targeted Drug Carriers based on Palm oil-based Glycosides and Polymeric Complexes. Towards tuneable natural-based controlled release systems, Newton Research Collaboration Programme, 2016-2017, Royal Academy of Engineering, £12,000.
As an external researcher:
- Supramolecular glycosides for energy conversion applications, Fundamental Research Grant Scheme (FRGS, MARA University of Technology), 2019-2022, Ministry of Higher Education Malaysia, £22,000.
- Versatile Block Copolymers Platforms to Approach Supramolecular Stimuli Responsive Nanocarriers, Spanish National Funding Scheme (University of Zaragoza), 2018/2020, Spanish Ministry of Education, £70000.
Coordinator of the MSc in Decommissioning (since 2020). https://www.abdn.ac.uk/study/postgraduate-taught/degree-programmes/1015/decommissioning/
Senior advisor of the PrototAU team of students from different disciplines, whose aim is to build and optimise a car using hydrogen-powered fuel cells. The students combine elements of chemical, electrical/electronic and mechanical engineering, and I integrate their activities within UG project dissertations and laboratories for MSc courses. The team won the Best Newcomer Award in the European Shell Eco-Marathon held in London in 2019. https://www.facebook.com/ProtoTAU/
Chemical reaction engineering – EX3501 (3rd year MEng and BEng Chemical Engineering, 15 credits). Course coordinator and sole contributor (since 2015).
Energy conversion and storage – EG551J/EG55M3 (MSc in Renewable Energies, 15 credits). Course coordinator and sole contributor. Campus + Online course (since 2016).
Separation and purification processes - EG50Y2 (MSc in Advanced Chemical Engineering, 15 credits). Co-contributor (50%) (since 2018).
MEng Group Design – EG5565” (5th year MEng Chemical Engineering, 15 credits). Course contributor (since 2018).
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- Velayutham, TS, Azmina, NMS, Manickam-Achari, V, Roche, A, Ramesh, R & Martinez-Felipe, A 2021, 'A new light-responsive resistive random-access memory device containing hydrogen-bonded complexes.', Journal of Photochemistry and Photobiology. A, Chemistry, vol. 404, 112914. [Online] DOI: https://doi.org/10.1016/j.jphotochem.2020.112914
- Martinez-Felipe, A, Velayutham, TS, Kamalul Aripin, NF, Yusoff, M, Farquharson, E & Hashim, R 2020, 'Glycolipids from Natural Sources: Dry Liquid Crystal Properties, Hydrogen Bonding and Molecular Mobility of Palm Kernel Oil Mannosides', Liquid Crystals, vol. 47, no. 8, pp. 1180-1194. [Online] DOI: https://doi.org/10.1080/02678292.2020.1750719
- Mohd Alauddin, S, Kamalul Aripin, NF, Velayutham, TS & Martinez-Felipe, A 2020, 'Liquid Crystalline Copolymers Containing Sulfonic and Light-Responsive Groups: From Molecular Design to Conductivity', Molecules, vol. 25, no. 11, 2579. [Online] DOI: https://doi.org/10.3390/molecules25112579
- Momoh, EO, Osofero, AI, Martinez-Felipe, A & Hamzah, F 2020, 'Physico-mechanical behaviour of Oil Palm Broom Fibres (OPBF) as eco-friendly building material', Journal of Building Engineering, vol. 30, 101208. [Online] DOI: https://doi.org/10.1016/j.jobe.2020.101208
- Alauddin, SM, Kamalul Aripin, NF, Velayutham, TS, Chaganava, I & Martinez-Felipe, A 2020, 'The role of conductivity and molecular mobility on the photoanisotropic response of a new azo-polymer containing sulfonic groups', Journal of Photochemistry and Photobiology A: Chemistry, vol. 389, 112268. [Online] DOI: https://doi.org/10.1016/j.jphotochem.2019.112268
- Walker, R, Pociecha, D, Martinez-Felipe, A, Storey, JMD, Gorecka, E & Imrie, CT 2020, 'Twist-Bend Nematogenic Supramolecular Dimers and Trimers Formed by Hydrogen Bonding', Crystals, vol. 10, no. 3, 175. [Online] DOI: https://doi.org/10.3390/cryst10030175
- Kamalul Aripin, NF, Heap, J, Piñol, R, Achari, VM & Martinez-Felipe, A 2020, 'Unveiling the hydrogen bonding network in liquid crystalline natural-based glycosides containing polymeric complexes: experimental and theoretical assessment', Colloids and Surfaces. A, Physicochemical and Engineering Aspects, vol. 596, 124685. [Online] DOI: https://doi.org/10.1016/j.colsurfa.2020.124685
- Moliner, C, Marchelli, F, Spanachi, N, Martinez-Felipe, A, Bosio, B & Arato, E 2019, 'CFD simulation of a Spouted Bed: comparison between the Discrete Element Method (DEM) and the Two Fluid Method (TFM)', Chemical Engineering Journal, vol. 377, 120466. [Online] DOI: https://doi.org/10.1016/j.cej.2018.11.164
- Brown, AW & Martinez-Felipe, A 2019, 'Ionic conductivity mediated by hydrogen bonding in liquid crystalline 4-n-alkoxybenzoic acids', Journal of Molecular Structure, vol. 1197, pp. 487-496. [Online] DOI: https://doi.org/10.1016/j.molstruc.2019.07.072
- Chaganava, I, Kobulashvili, I, Mohd Alauddin, S, Kamalul Aripin, NF & Martinez-Felipe, A 2019, Light-inducing birefringence of organic photoanisotropic materials integrated via covalent bonds. in F Kajzar, T Kaino & CE Tabor (eds), Organic Photonic Materials and Devices XXI., 1091517, Proceedings of SPIE - The International Society for Optical Engineering, vol. 10915, SPIE, Organic Photonic Materials and Devices XXI 2019, San Francisco, United States, 5/02/19. [Online] DOI: https://doi.org/10.1117/12.2506036