The list below includes Annex 62 research results published in peer-reviewed journals and conference proceedings grouped by country.

Denmark

• Yu, T., Zhang, C., Heiselberg, P. K., Pomianowski, M. Z., & Jensen, R. L. (2015). Dynamic Measurements of a Novel System: Combining Natural Ventilation with Diffuse Ceiling Inlet and Thermally Activated Building Constructions. Department of Civil Engineering, Aalborg University. Retrieved from http://vbn.aau.dk/en/publications/dynamic-measurements-of-a-novel-system(e2911994-5fee-46cc-bbc2-662e72652a52).html
• Hidalgo, J. M., Psomas, T. C., Gáfaro, C. G., Heiselberg, P. K., & Millán, J. A. (2015). Overheating Assessment of a Passive House Case Study in Spain. Proceedings of the 36th AIVC Conference “Effective ventilation in high performance buildings”, Madrid, Spain, 23-24 September 2015 (pp. 645-655). Madrid: AIVC. Retrieved from http://vbn.aau.dk/da/publications/overheating-assessment-of-a-passive-house-case-study-in-spain(bb46c64b-af83-4058-b78c-143c3b2ea674).html
• Psomas, T. C., Heiselberg, P. K., & Duer, K. (2016, January). Overheating assessment of energy renovations. REHVA Journal, 53(1), 32-35. Retrieved from http://vbn.aau.dk/da/publications/overheating-assessment-of-energy-renovations(f6f371dc-ea6b-424b-a6db-cd7b07f50535).html
• Psomas, T. C., Heiselberg, P. K., Duer, K., & Bjørn, E. (2015). Analysis and Comparison of Overheating Indices in Energy Renovated Houses. Proceedings of the 14th International Conference of the International Building Performance Simulation Association: IBPSA 2015: Building Simulation 2015. Hyderabad, India: IBPSA. Retrieved from http://vbn.aau.dk/da/publications/analysis-and-comparison-of-overheating-indices-in-energy-renovated-houses(707d4808-c003-41de-b3b5-2adf664caf03).html
• Psomas, T. C., Heiselberg, P. K., Duer, K., & Bjørn, E. (2016). Control Strategies for Ventilative Cooling of Overheated Houses. CLIMA 2016: proceedings of the 12th REHVA World Congress, 22-25 May 2016, Aalborg, Denmark. Aalborg. Retrieved from http://vbn.aau.dk/da/publications/control-strategies-for-ventilative-cooling-of-overheated-houses(3c646d67-24eb-49b7-84b8-14d248f29c3b).html
• Psomas, T. C., Heiselberg, P. K., Duer, K., & Bjørn, E. (2016, April). Overheating risk barriers to energy renovations of single family houses: Multicriteria analysis and assessment. Energy and Buildings, 117, 138–148. Retrieved from http://vbn.aau.dk/da/publications/overheating-risk-barriers-to-energy-renovations-of-single-family-houses(c5ad2287-1d4f-4421-86d8-7058ee5d7007).html
• Yu, T., Heiselberg, P. K., Lei, B., Pomianowski, M. Z., Zhang, C., & Jensen, R. L. (2015, October). Experimental investigation of cooling performance of a novel HVAC system combining natural ventilation with diffuse ceiling inlet and TABS. Energy and Buildings, 105, 165-177. Retrieved from http://vbn.aau.dk/da/publications/experimental-investigation-of-cooling-performance-of-a-novel-hvac-system-combining-natural-ventilation-with-diffuse-ceiling-inlet-and-tabs(0d4a789d-f06f-4a19-9a93-f12a93456679).html
• Yu, T., Heiselberg, P. K., Lei, B., Zhang, C., Pomianowski, M. Z., & Jensen, R. L. (2016, May). Experimental study on the dynamic performance of a novel system combining natural ventilation with diffuse ceiling inlet and TABS. Applied Energy, 169, 218-229. Retrieved from http://vbn.aau.dk/da/publications/experimental-study-on-the-dynamic-performance-of-a-novel-system-combining-natural-ventilation-with-diffuse-ceiling-inlet-and-tabs(52037029-5b1e-4d75-8a71-f5accb34add2).html10.1016/j.apenergy.2016.01.116
• Yu, T., Heiselberg, P., Lei, B., Pomianowski, M. Z., & Zhang, C. (2015, March 1). A novel system solution for cooling and ventilation in office buildings: A review of applied technologies and a case study. Energy and Buildings, 90, 142–155. Retrieved from http://vbn.aau.dk/da/publications/a-novel-system-solution-for-cooling-and-ventilation-in-office-buildings(2e866f20-8474-4123-83e0-695dd75c2a15).html
• Zhang, C., Chen, Q., Heiselberg, P. K., & Pomianowski, M. Z. (2015). Airflow Pattern and Performance Analysis of Diffuse Ceiling Ventilation in an Office Room using CFD Study. Proceedings of the 14th International Conference of the International Building Performance Simulation Association: IBPSA 2015 : Building Simulation 2015. Hyderabad: IBPSA. Retrieved from http://vbn.aau.dk/da/publications/airflow-pattern-and-performance-analysis-of-diffuse-ceiling-ventilation-in-an-office-room-using-cfd-study(c4fa0910-4a94-4564-9dc7-897f38abc5f1).html
• Zhang, C., Heiselberg, P. K., Pomianowski, M. Z., Yu, T., & Jensen, R. L. (2015, October 15). Experimental study of diffuse ceiling ventilation coupled with a thermally activated building construction in an office room. Energy and Buildings, 105, 60-70. Retrieved from http://vbn.aau.dk/da/publications/experimental-study-of-diffuse-ceiling-ventilation-coupled-with-a-thermally-activated-building-construction-in-an-office-room(c34f3c80-6240-4c5f-b65f-42bec1dc5ad4).html
• Zhang, C., Heiselberg, P. K., Pomianowski, M. Z., Yu, T., & Jensen, R. L. (June 2015). Integrated Solution in an Office Room with Diffuse Ceiling Ventilation and Thermally Activated Building Constructions. Proceedings of the 6th Int. Building Physics Conference. Turin, Italy. Retrieved from http://vbn.aau.dk/da/publications/integrated-solution-in-an-office-room-with-diffuse-ceiling-ventilation-and-thermally-activated-building-constructions(0b687e11-8b42-425c-a7b5-853e42f57e32).html
• Zhang, C., Heiselberg, P., & Nielsen, P. (2014, June). Diffuse Ceiling Ventilation: A Review. International Journal of Ventilation, 13(1), 49-64. Retrieved from http://vbn.aau.dk/da/publications/diffuse-ceiling-ventilation(e62a8749-25e8-4b37-87c8-7c13aca995f6).html
• Zhang, C., Kristensen, M. H., Jensen, J. S., Heiselberg, P. K., Jensen, R. L., & Pomianowski, M. Z. (2016, January). Parametrical analysis on the diffuse ceiling ventilation by experimental and numerical studies. Energy and Buildings, 111, 87-97. Retrieved from http://vbn.aau.dk/da/publications/parametrical-analysis-on-the-diffuse-ceiling-ventilation-by-experimental-and-numerical-studies(18eaf879-e645-4311-9a67-17ad392c7501).html
• Zhang, C., Yu, T., Heiselberg, P., & Pomianowski, M. (December 2014). Experimental Study of an integrated system with diffuse ceiling ventilation and thermally activated building constructions. Department of Civil Engineering, Aalborg University. Retrieved from http://vbn.aau.dk/da/publications/experimental-study-of-an-integrated-system-with-diffuse-ceiling-ventilation-and-thermally-activated-building-constructions(3a960bb0-5a73-44c0-a88e-4eee4dd22f24).html

Finland

• Maula, H., Hongisto, V., Koskela, H., & Haapakangas, A. (2016, August 1). The effect of cooling jet on work performance and comfort in warm office environment. Building and Environment, 104, 13–20. Retrieved from http://www.sciencedirect.com/science/article/pii/S0360132316301391
• Maula, H., Koskela, H., Haapakangas, A., & Hongisto, V. (2014). Perception of a cooling jet from ceiling – a laboratory study. 35th AIVC Conference ” Ventilation and airtightness in transforming the building stock to high performance”, Poznań, Poland, 24-25 September 2014 (pp. 94-99). AIVC. Retrieved from http://www.aivc.org/resource/perception-cooling-jet-ceiling-laboratory-study
• Maula, H., Koskela, H., Varjo, J., & Hongisto, V. (2015). The effect of a ceiling based cooling jet on work performance and thermal comfort – a laboratory study. Proceedings of Healthy Buildings 2015 Europe, 18-20 May 2015, Eindhoven, The Netherlands. ISIAQ.

Italy

• Avantaggiato, M., Belleri, A., De Carli, M., & Lollini, R. (2015). Ventilative cooling strategies to reduce cooling and ventilation needs in shopping centres. 36th AIVC Conference ” Effective ventilation in high performance buildings”, Madrid, Spain, 23-24 September 2015 (pp. 633-644). Madrid: AIVC. Retrieved from http://www.aivc.org/resource/ventilative-cooling-strategies-reduce-cooling-and-ventilation-needs-shopping-centres
• Belleri, A. (2014, May 22). Integrated design methods for natural ventilation. Doctoral Thesis. Retrieved from https://aisberg.unibg.it/handle/10446/30436#.WCLYVfl96M9
• Belleri, A., & Avantaggiato, M. (2016). Ventilative cooling in shopping centers’ retrofit. REHVA Journal(53), 21-25. Retrieved from http://www.rehva.eu/fileadmin/REHVA_Journal/REHVA_Journal_2016/RJ_issue_1/P.21/21-25_RJ1601_WEB.pdf
• Belleri, A., Avantaggiato, M., & Lollini, R. (2016). Ventilative cooling in shopping centers’ retrofit: the Mercado del Val case study. International Conference on Sustainability in Energy and Buildings, Torino, Italy, 11-13 September, 2016. Torino.
• Belleri, A., Lollini, R., & Dutton, S. M. (2014, November). Natural ventilation design: An analysis of predicted and measured performance. Building and Environment, 81, 123-138. Retrieved from http://www.sciencedirect.com/science/article/pii/S0360132314001954
• Belleri, A., Noris, F., & Lollini, R. (2014). Strategies for exploiting climate potential through ventilative cooling in a renovated historic market. 35th AIVC Conference ” Ventilation and airtightness in transforming the building stock to high performance”, Poznań, Poland, 24-25 September 2014 (pp. 257-267). Poznań: AIVC. Retrieved from http://www.aivc.org/resource/strategies-exploiting-climate-potential-through-ventilative-cooling-renovated-historic
• Belleri, A., Psomas, T., & Heiselberg, P. (2015). Evaluation tool of climate potential for ventilative cooling. 36th AIVC Conference ” Effective ventilation in high performance buildings”, Madrid, Spain, 23-24 September 2015. (pp. 53-66). AIVC. Retrieved from http://www.aivc.org/resource/evaluation-tool-climate-potential-ventilative-cooling
• Chiesa , G., & Grosso, M. (2015, November). The Influence of Different Hourly Typical Meteorological Years on Dynamic Simulation of Buildings. Energy Procedia, 78, 2560-2565. Retrieved from http://www.sciencedirect.com/science/article/pii/S1876610215020123
• Chiesa, G. (2016). Geo-climatic applicability of evaporative and ventilative cooling in China. International Journal of Ventilation, 14(3-4), 205-219. Retrieved from http://www.tandfonline.com/doi/full/10.1080/14733315.2016.1214395
• Chiesa, G., & Grosso, M. (2015). Direct evaporative passive cooling of building. A comparison amid simplified simulation models based on experimental data. Building and Environment, 94-Part 1, 263-272. Retrieved from http://www.sciencedirect.com/science/article/pii/S0360132315300950
• Chiesa, G., & Grosso, M. (2015, November 15). Geo-climatic applicability of natural ventilative cooling in the Mediterranean area. Energy and Buildings, 107, 376–391. Retrieved from http://www.sciencedirect.com/science/article/pii/S0378778815302279
• Chiesa, G., & Grosso, M. (2016). Cooling potential of natural ventilation in representative climates of central and southern Europe. International Journal of Ventilation, 16(1), 1-15. Retrieved from http://www.tandfonline.com/doi/full/10.1080/14733315.2016.1214394
• Chiesa, G., & Grosso, M. (2016). Editorial: Breakthrough of natural and hybrid ventilative cooling technologies: models and simulations. International Journal of Ventilation, 15(3-4), 183-185. Retrieved from http://www.tandfonline.com/doi/full/10.1080/14733315.2016.1220701
• Chiesa, G., Grosso, M., Bogni, A., & Garavaglia, G. (2016). Passive downdraught evaporative cooling system integration in existing residential building typologies: a case study. Sustainability in Energy and Buildings, SEB-16 Turin, Italy 11-13 September 2016.
• Chiesa, G., Huberman, N., Pearlmutter, D., & Grosso, M. (2016). Summer discomfort reduction by direct evaporative cooling in Southern Mediterranean areas. Sustainability in Energy and Buildings, SEB-16, Turin, Italy, 11-13 September 2016. Turin.
• Chiesa, G., Simonetti, M., & Grosso, M. (2014, February). A 3-field earth-heat-exchange system for a school building in Imola, Italy: Monitoring results. Renewable Energy, 62, 563-570. Retrieved from http://www.sciencedirect.com/science/article/pii/S0960148113004229
• Pellegrino, M., Simonetti, M., & Chiesa, G. (2016, February). Reducing thermal discomfort and energy consumption of Indian residential buildings: Model validation by in-field measurements and simulation of low-cost interventions. Energy and Buildings, 113, 145–158. Retrieved from http://www.sciencedirect.com/science/article/pii/S0378778815304515
• Simonetti, M., Chiesa, G., Grosso, M., & Fracastoro, G. V. (2016, October 1). NAC wall: An open cycle solar-DEC with naturally driven ventilation. Energy and Buildings, 129, 357-366. Retrieved from http://www.sciencedirect.com/science/article/pii/S0378778816306752
• Simonetti, M., Fracastoro, G. V., Chiesa, G., & Sola, S. (2016, June 25). Numerical optimization and experimental testing of a new low pressure heat exchanger (LoPHEx) for passive ventilation of buildings. Applied Thermal Engineering, 103, 720–729. Retrieved from http://www.sciencedirect.com/science/article/pii/S1359431116306317

Netherlands

• Barbosa, R., Bartak, M., Hensen, J., & Loomans, M. (2015). Ventilative cooling control strategies applied to passive house in order to avoid indoor overheating. Building Simulation 2015 : 14th International conference of IBPSA, December 7-9, 2015, Hyderabad, India (pp. 1142-1148). IBPSA. Retrieved from https://pure.tue.nl/ws/files/18304335/ventilative.pdf
• Barbosa, R., Loomans, M., Hensen, J., & Bartak, M. (2015). The impact of increased airflow rates on indoor temperatures of passive house in The Netherlands. Proceedings of Healthy Buildings 2015 Europe, 18-20 May 2015, Eindhoven, The Netherlands (pp. 1-7). Eindhoven: ISIAQ. Retrieved from: http://www.janhensen.nl/publications_folder/15_hb_barbosa.pdf
• Bouwens, E., Loomans, M., Hensen, J. L., & Lichtenberg, J. (2016). Potentie van natuurlijke ventilatie voor vrije koeling. TVVL Magazine, 45(7/8).
• Bouwens, E., Loomans, M., Hensen, J., & Lichtenberg, J. (2016). Ventilative Cooling Potential in Low-Energy Dwellings –The HoTT Case Study. CLIMA 2016 : Proceedings of the 12th REHVA World Congress, 22-25 May 2016, Aalborg, Denmark (pp. 1-10). Aalborg: Aalborg University Department of Civil Engineering. Retrieved from http://vbn.aau.dk/files/233719336/paper_263.pdf
• Hamdy, M., & Hensen, J. (2014). Impact of climate change on overheating risk in dwellings. Eindhoven University of Technology: CPC Project: Climate proof cities. Retrieved from http://www.verozo.be/sites/verozo/files/files/Publicaties/building%20and%20environment%20122%20(2017)%20307-323%20The%20impact%20of%20climate%20change%20on%20the%20overheating%20risk%20in%20dwellings%20Dutch%20case%20study.pdf
• Hamdy, M., & Hensen, J. (2015). Assessment of overheating risk in dwellings. Proceedings of the Conference on Healthy Building Europe 2015, May 18-20th 2015, Eindhoven, The Netherlands (pp. 1-9). Eindhoven: Technische Universiteit Eindhoven.
• Hassan Mohamed, M., & Hensen, J. (2015). Ranking of dwelling types in terms of overheating risk and sensitivity to climate change. Proceedings Building Simulation ’15, 7-9 December 2015, Hyderabad, India (pp. 1-8). IBPSA. Retrieved from https://pure.tue.nl/ws/files/4025562/888917962478133.pdf
• Loomans, M., & Hensen, J. (2016). Natuurlijke ventilatie voor vrije koeling | kort overzicht van de stand van zaken. Bouwfysica, 27(2), 17-21.

Portugal

• Carrilho da Graça, G., & Linden, P. (2016, October). Ten questions about natural ventilation of non-domestic buildings. Building and Environment, 107, 263–273. Retrieved from http://www.sciencedirect.com/science/article/pii/S036013231630302X
• Carrilho da Graça, G., Daish, N., & Linden, P. (2015, July). A two-zone model for natural cross-ventilation. Building and Environment, 89, 72–85. Retrieved from http://www.sciencedirect.com/science/article/pii/S0360132315000712
• Daish, N., Carrilho da Graça, G., Linden, P., & Banks, D. (2016, November 1). Impact of aperture separation on wind-driven single-sided natural ventilation. Building and Environment, 108, 122–134. Retrieved from http://www.sciencedirect.com/science/article/pii/S0360132316303109
• Martins, N., & Carrilho da Graça, G. (2016, February). Validation of numerical simulation tools for wind-driven natural ventilation design. Building Simulation, 9(1), 75–87. Retrieved from http://link.springer.com/article/10.1007/s12273-015-0251-6
• Mateus, N. M., Nunes Simões, G., Lúcio, C., & Carrilho da Graça, G. (2016, December 1). Comparison of measured and simulated performance of natural displacement ventilation systems for classrooms. Energy and Buildings, 133, 185–196. Retrieved from http://www.sciencedirect.com/science/article/pii/S0378778816309343
• Mateus, N., Pinto, A., & Carrilho da Graça, G. (2014, June). Validation of EnergyPlus thermal simulation of a double skin naturally and mechanically ventilated test cell. Energy and Buildings, 75, 511–522. Retrieved from http://www.sciencedirect.com/science/article/pii/S0378778814001571

United Kingdom

• Kolokotroni, M., Santos, T., & Hopper, N. (2016, January). Ventilative cooling of a seminar room using active PCM thermal storage. REHVA Journal, 53(1), 36-40. Retrieved from http://www.rehva.eu/fileadmin/REHVA_Journal/REHVA_Journal_2016/RJ_issue_1/P.36/36-40_RJ1601_WEB.pdf
• Kolokotroni, M., Tassou, S., & Gowreesunker, B. (2015). Energy aspects and ventilation of food retail buildings. Advances in Building Energy Research, 9(1), 1-19. Retrieved from http://bura.brunel.ac.uk/handle/2438/10998
• Mylona, Z., Kolokotroni, M., & Tassou, S. (2015). Ventilative cooling and energy use in supermarkets. 36th AIVC Conference ” Effective ventilation in high performance buildings”, Madrid, Spain, 23-24 September 2015. (pp. 89-100). AIVC. Retrieved from http://www.aivc.org/resource/ventilative-cooling-and-energy-use-supermarkets
• O’Sullivan, P., & Kolokotroni , M. (2014). Experimental characterisation of dominant driving forces and fluctuating ventilation rates for a single sided slot louver ventilation system. 35th AIVC Conference ” Ventilation and airtightness in transforming the building stock to high performance”, Poznań, Poland, 24-25 September 2014 (pp. 547-556). AIVC. Retrieved from http://www.aivc.org/resource/experimental-characterisation-dominant-driving-forces-and-fluctuating-ventilation-rates
• O’Sullivan, P. D., & Kolokotroni, M. (2014). Time-averaged single sided ventilation rates and thermal environment in cooling mode for a low energy retrofit envelope. International Journal of Ventilation, 13(2), 153 – 168. Retrieved from http://bura.brunel.ac.uk/handle/2438/11006
• O’Sullivan, P. D., & Kolokotroni, M. (2016). Non dimensional analysis and characterisation of driving forces for a single sided slot louvre ventilation system. International Journal of Ventilation, 14(4), 335 – 347. Retrieved from http://bura.brunel.ac.uk/handle/2438/12638
• Santos, T., Hopper, N., & Kolokotroni, M. (2016). Performance in practice of a ventilation system with thermal storage in a computer seminar room. 12th REHVA World Congress – CLIMA2016, Aalborg, Denmark, 22- 26 May 2016. Retrieved from http://bura.brunel.ac.uk/handle/2438/12583