[25] S. McFadden, **R. P. Mooney**, L. Sturz, and G. Zimmermann, “A Nucleation Progenitor Function approach to polycrystalline equiaxed solidification modelling with application to a microgravity transparent alloy experiment observed in-situ,” *Acta Mater.*, vol. 148, pp.289-299, Feb. 2018.

[24] **R. P. Mooney**, L. Sturz, G. Zimmermann, and S. McFadden, “Thermal characterisation with modelling for a microgravity experiment into polycrystalline equiaxed dendritic solidification with in-situ observation,” *Int. J. Therm. Sci.*, vol. 125, pp. 283–292, 2018.

[23] **R. P. Mooney** and S. McFadden, “Theoretical analysis to interpret projected image data from in-situ 3-dimensional equiaxed nucleation and growth,” *J. Cryst. Growth*, vol. 480, pp. 43–50, Dec. 2017.

[22] G. Zimmermann, L. Sturz, H. Nguyen-Thi, N. Mangelinck-Noel, Y. Z. Li, C.-A. Gandin, R. Fleurisson, G. Guillemot, S. McFadden, **R. P. Mooney**, P. Voorhees, A. Roosz, A. Ronaföldi, C. Beckermann, A. Karma, C.-H. Chen, N. Warnken, A. Saad, G.-U. Grün, M. Grohn, I. Poitrault, T. Pehl, I. Nagy, D. Todt, O. Minster, and W. Sillekens, “Columnar and Equiaxed Solidification of Al-7 wt.% Si Alloys in Reduced Gravity in the Framework of the CETSOL Project,” *JOM*, pp. 1–11, Jun. 2017.

[21] M. Seredyński, S. Battaglioli, **R. P. Mooney**, A. Robinson, J. Banaszek, and S. McFadden, “Code-to-code verification of an axisymmetric model of the Bridgman solidification process for alloys.,” *Int. J. Numer. Methods Heat Fluid Flow*, vol. 27, no. 5, p. HFF-03-2016-0123, May 2017.

[20] G. Zimmermann, L. Sturz, H. Nguyen-Thi, N. Mangelinck-Noel, Y. Z. Li, L. D.-R., C.-A. Gandin, R. Fleurisson, G. Guillemot, S. McFadden, **R. P. Mooney**, P. W. Voorhees, A. Roosz, A. Ronaföldi, C. Beckermann, A. Karma, N. Warnken, A. Saad, G.-U. Grün, M. Grohn, I. Poitrault, T. Pehl, I. Nagy, D. Todt, O. Minster, and W. Sillekens, “(in review) Columnar and equiaxed solidification in a microgravity environment – The CETSOL project,” in 6*th Decennial International Conference on Solidification Processing, SP17*, 2017, pp. 300-303

[19] S. Battaglioli, **R. P. Mooney**, A. Robinson, and S. McFadden, “(poster) Macroscale modelling of Bridgman furnace solidification for the prediction of texture evolution and columnar to equiaxed transition,” in *8th International Conference on Multiscale Materials Modeling*, 2016.

[18] **R. P. Mooney**, “A Theoretical Overview of Unlearning in Engineering,” *Trinity Coll. Dublin Postgrad. Rev.*, vol. 1, pp. 181–191, 2016.

[17] **R. P. Mooney** and S. McFadden, “Sensitivity analysis of dendritic growth kinetics in a Bridgman furnace front tracking model,” *IOP Conf. Ser. Mater. Sci. Eng.*, vol. 117, no. 1, p. 12012, Mar. 2016.

[16] S. Battaglioli, **R. P. Mooney**, A. Robinson, M. Seredyński, and S. McFadden, “Computer Modelling of Manufacturing Processes: The Development of a 2D Axisymmetric Model of the Bridgman Casting Process,” in *32nd International Manufacturing Conference (IMC-32)*, 2015.

[15] **R. P. Mooney**, J. Lapin, A. Klimová, and S. McFadden, “Conditions for CET in a gamma TiAl alloy,” *IOP Conf. Ser. Mater. Sci. Eng.*, vol. 84, no. 1, p. 12088, Jun. 2015.

[14] **R. P. Mooney**, U. Hecht, Z. Gabalcová, J. Lapin, and S. McFadden, “Directional solidification of a TiAl alloy by combined Bridgman and power-down technique,” *Kov. Mater.*, vol. 53, no. 3, pp. 187–917, 2015.

[13] M. Seredyński, S. Battaglioli, **R. P. Mooney**, A. Robinson, J. Banaszek, and S. McFadden, “Verification of a 2D axisymmetric model of the Bridgman solidification process for metallic alloys,” in *Numerical Heat Transfer 2015, Eurotherm Seminar No 109*, 2015, pp. 295–303.

[12] **R. P. Mooney**, “A Bridgman Furnace Front Tracking Model,” University of Dublin, Trinity College, 2015.

[11] **R. P. Mooney** and S. McFadden, “The Role of Verification in Computer Modelling: A Case Study in Solidification Processing,” in *31st International Manufacturing Conference*, 2014, pp. 173–180.

[10] J. Lapin, Z. Gabalcová, U. Hecht, **R. P. Mooney**, and S. McFadden, “Columnar to Equiaxed Transition in Peritectic TiAl Based Alloy Studied by a Power-Down Technique,” *Mater. Sci. Forum*, vol. 790–791, pp. 193–198, 2014.

[9] **R. P. Mooney** and S. McFadden, “Order verification of a Bridgman furnace front tracking model in steady state,” *Simul. Model. Pract. Theory*, vol. 48, pp. 24–34, 2014.

[8] **R. P. Mooney**, S. McFadden, Z. Gabalcová, and J. Lapin, “An experimental–numerical method for estimating heat transfer in a Bridgman furnace,” *Appl. Therm. Eng.*, vol. 67, no. 1–2, pp. 61–71, 2014.

[7] **R. P. Mooney** and S. McFadden, “An investigation into Bridgman furnace solidification,” in *30th International Manufacturing Conference*, 2013, pp. 375–383.

[6] ** R. P. Mooney**, S. McFadden, M. Rebow, and D. J. Browne, “A Front Tracking Model for Transient Solidification of Al–7wt%Si in a Bridgman Furnace,” *Trans. Indian Inst. Met.*, vol. 65, no. 6, pp. 527–530, 2012.

[5] **R. P. Mooney**, S. McFadden, M. Rebow, and D. J. Browne, “A front tracking model of the MAXUS-8 microgravity solidification experiment on a Ti-45.5at.% Al-8at.%Nb alloy,” *IOP Conf. Ser. Mater. Sci. Eng.*, vol. 27, no. 1, p. 12020, 2012.

[4] **R. P. Mooney**, D. Browne, O. Budenkova, Y. Fautrelle, L. Froyen, A. Kartavykh, S. McFadden, S. Rex, B. Schmitz, and D. Voss, “Review of the MAXUS 8 sounding rocket experiment to investigate solidification in a Ti-Al-Nb alloy,” in *European Space Agency, (Special Publication) ESA SP*, 2011, vol. 700 SP, pp. 453–458.

[3] **R. P. Mooney** and A. O’Dwyer, “A case study in modeling and process control: the control of a pilot scale heating and ventilation system,” in *Proceedings of IMC-23; the 23rd International Manufacturing Conference*, 2006, pp. 123–130.

[2] ** R. P. Mooney**, “The gain-scheduled control of a non-linear laboratory heating and ventilation process,” in *IEE Irish Signals and Systems Conference 2005*, 2005, vol. 2005, pp. 42–47.

[1] **R. P. Mooney**, “The Estimation and Control of a Laboratory Heating and Ventilation System,” *Masters Thesis*, 2003.