The materials in this page were prepared throughout my PhD studies at the University of Nottingham. Looking for my PhD thesis? Find it on the EPrints repository of the University of Nottingham. There, you can also find my self-archived publications (green open access).

Energy harvesting & Civil engineering materials (ResearchGate)

Articles

• A. Chiarelli, A.R. Dawson, A. García, Analysis of the performance of an air-powered energy harvesting pavement, Transportation Research Record (TRR), Journal of the Transportation Research Board, 2015
• A. Chiarelli, A.R. Dawson, A. García, Parametric analysis of energy harvesting pavements operated by air convection, Applied Energy, 2015
• A. Chiarelli, A.R. Dawson, A. García, Field evaluation of the effects of air convection in energy harvesting asphalt pavements, Sustainable Energy Technologies and Assessments, 2017
• A. Chiarelli, A. Al-Mohammedawi, A.R. Dawson, A. García, Construction and configuration of convection-powered asphalt solar collectors for the reduction of urban temperatures, International Journal of Thermal Sciences, 2016
• A. Chiarelli, A. Dawson, A. García, Pavement temperature mitigation by the means of geothermally and solar heated air, Geothermics, 2017
• A. García, A. Hassn, A. Chiarelli, A. Dawson, Multivariable analysis of potential evaporation from moist asphalt mixture, Construction and Building Materials, 2015
• A. Hassn, A. Chiarelli, A. Dawson, A. García, Thermal properties of asphalt pavements under dry and wet conditions, Materials and Design, 2015
• A. Chiarelli, A. Dawson, A. García, Mitigation of asphalt pavement temperatures by means of natural air convection, Proceedings of the 4th Chinese-European Workshop on Functional Pavement Design, CEW, 2016

Data

• Asphalt Core CT Scan Images (5.6% Air voids)
• Asphalt Core CT Scan Images (10.4% Air voids)
• Asphalt Core CT Scan Images (15.6% Air voids)
• Asphalt Core CT Scan Images (18.9% Air voids)
• Asphalt Core CT Scan Images (21.9% Air voids)
• Asphalt Core CT Scan Images (25.6% Air voids)

Modelling of porous materials (ResearchGate)

Articles

• A. Chiarelli, A.R. Dawson, A. García, Generation of virtual asphalt mixture porosity for computational modelling, Powder Technology, 2015
• A. Chiarelli, A.R. Dawson, A. García, Stochastic generation of virtual air pores in granular materials, Granular Matter, 2015
• A. Chiarelli, A.R. Dawson, A. García, Generation Of 3D Soil/Asphalt Porosity Patterns For Numerical Modelling, Proceedings of the 15th Pan-American Conference on Soil Mechanics and Geotechnical Engineering, 15–18 November 2015, Buenos Aires, Argentina
• A. Chiarelli, A. Dawson, A. García, Computational packing of aggregates for the study of virtual asphalt samples, ISAP Symposium, 2016, Jackson Hole, Wyoming
• M. Aboufoul, A. Chiarelli, I. Triguero, A. García, Virtual porous materials to predict the air void topology and hydraulic conductivity of asphalt roads, Powder Technology, 2019 (preprint version)
• A. García, S. Michot-Roberto, S. Dopazo-Hilario, A. Chiarelli, A. Dawson, Creation of realistic virtual aggregate avatars, Powder Technology, 2020
• A.García, L. Wan, S. Dopazo-Hilario, A. Chiarelli, A. Dawson, Generation of virtual asphalt concrete in a physics engine, Construction and Building Materials, 2021

Algorithms

• Packing circles in a rectangular domain with a touch-and-stop model of growth (contact inhibition)
• Packing circles in a circular domain with a touch-and-stop model of growth (contact inhibition)

Business and management 

Articles

• A. Chiarelli, The impact of dynamic capabilities and market orientation on firm performance: a case study of higher education consulting firms, Small Business International Review, 2021

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