Abd Halid, H., Wang, F. (2012). Design and Low Energy Ventilation Solutions for Atria in the Tropics. Sustainable Cities and Society, 2(1), 8-28.
Abdoli, M. & Fasihi, A. (2006). The Climatic Impact of Tehran on Energy Consumption in Residential Buildings. 4th Conference on Energy Conservation in Building. Tehran, Iran.
Aldawoud, A. (2013). The Influence of the Atrium Geometry on the Building Energy Performance. Energy and Buildings, 57, 1-5.
Aldawoud, A., Clark, R. (2008). Comparative Analysis of Energy Performance between Courtyard and Atrium in Buildings. Energy and Buildings, 40(3), 209-214.
ASHRE Standard, 5. (2013). Thermal Environmental Conditions for Human Occupancy. Atlanta: ASHRAE.
Brown, G., DeKay , M. (2001). Sun, Wind, and Light: Architectural Design Strategies. New York.
Bryn, I. (1993). Atrium Buildings Environmental Design and Energy Use. Ashrae Transactins, 99 (part 1).
Center of the Built Environment (CBE). (n.d.). Berkeley. California. Retrieved 06 07, 2013, from http://cbe.berkeley.edu/research/index.htm.
Chun, C., Kwok, A., Mitamura, T., Miwa, N. & Tamura, A. (2008). Thermal Diary: Connecting Temperature History to Indoor Comfort. Building and Environment, 43, 877–885.
Etzion, Y., Pearlmutter, D., Erell, E., & Meier, I. (1997). Adaptive Architecture: Integrating Low Energy Technologies for Climate Control in Desert. Automation in Construction, 6(5-6), 417-425.
Fordham, M. (2000). Natural Ventilation. Renewable Energy, 19, 17-37.
Givoni, B. (1976). Man, Climate and Architecture. New York: Elsevier Press.
Guimarães-Costa, N., Pina, E. & Cunha, P. (2008). The Atrium Effect of Website Openness on the Communication of Corporate Social Responsibility. Corporate Social Responsibility and Environmental Management, 15, 43-51.
Hung, W. (2003). Architectural Aspects of Atrium. International Journal on Engineering Performance-based Fire Codes, 5(4), 131-137.
Laouadi, A. & Atif, M. (1999). Comparison between Computed and Field Measured Thermal Parameters in an Atrium Building. Building and Environment, 34, 129-138.
Laouadi, A., Atif, M. & Galasiu, A. (2002). Towards Developing Skylight Design Tools for Thermal and Energy Performance of Atriums in Cold Climates. Building and Environment, 37, 1289-1316.
Madani, R., Mokhtari, M. & Gharaati, M. (2012). The Role of Atrium in Optimizing Fuel Consumption in Office Buildings. 2nd Conference on Environmental Planning and Management (EPM). Tehran, Iran.
Martín, H., Martínez, R. & Gómez, V. (2008). Thermal Comfort Analysis of a Low Temperature Waste Energy Recovery System: SIECHP. Energy and Buildings, 40, 561–572.
Moosavi, L., Mahyuddin, N., & Ghafar, N. (2015). Atrium Cooling Performance in a Low Energy Office Building in the Tropics, A Field Study. Building and Environment, 94(1), 384-394.
Ochoa, C. & Capelute, I. (2006). Evaluating Visual Comfort and Performance of Three Natural Lighting Systems for Deep Office Buildings in Highly Luminous Climates. Journal of Building & Environment, 41, 1128-1135.
Sekkei, Y. (1989). Amenity Space for Interaction: Recent Works. Process Architecture, 16-37.
Sharples, S. & Lash, D. (2007). Daylight in Atrium Building. Architectural Science Review, 50, 301-312.
Szokolay, S. (1987). Thermal Design of Buildings. Australia: Raia Education Division Canberra.
Tsutsumi, H., Tanabe, S., Harigaya, J., Iguchi, Y. & Nakamura, G. (2007). Effect of Humidity on Human Comfort and Productivity after Step Changes from Warm and Humid Environment. Building and Environment, 42, 4034 – 4042.