Bahadori, Mehdi N. Passive cooling systems in iranian architecture. Scientific American, 238(2):144–155, 1978.
 Liu, Shichao, Mak, CM, and Niu, JianLei. Numerical evaluation of louver configuration and ventilation strategies for the windcatcher system. Building and environment, 46(8):1600–1616, 2011.
 Yaghoubi, MA, Sabzevari, A, and Golneshan, AA. Wind towers: measurement and performance. Solar energy, 47(2):97–106, 1991.
 Saadatian, Omidreza, Haw, Lim Chin, Sopian, Kamaruzzaman, and Sulaiman, Mohamad Yusof. Review of windcatcher technologies. Renewable and Sustainable Energy Reviews, 16(3):1477–1495, 2012.
 Li, Liu and Mak, CM. The assessment of the performance of a windcatcher system using computational fluid dynamics. Building and environment, 42(3):1135–1141, 2007.
 Bouchahm, Yasmina, Bourbia, Fatiha, and Belhamri, Azeddine. Performance analysis and improvement of the use of wind tower in hot dry climate. Renewable Energy, 36(3):898–906, 2011.
 Montazeri, Hamid and Azizian, Ruhollah. Experimental study on natural ventilation performance of a two-sided wind catcher, 2009.
 Bahramzadeh, Mohammad, Sadeghi, Bahador, and Rou, S. Sabok. Identifying the identity of iranian wind catchers and their types. Basic and Applied Scientific Research, 3(2):12–19, 2013.
 Pirhayati, M., Ainechi, Sh., M., Torkjazim, and Ashrafi, E. Ancient iran, the origin land of wind catcher in the world. Research Journal of Environmental and Earth Sciences, 5(8):433–439, 2013.
 Mahmoudi, Mahnaz. Windcatcher is a symbol of Iranian architecture. Yazda, 1388 (in Persian).
 Bahadourinejad, Mehdi and Dehghani, Ali Reza. Wind Catcher, Iranian engineering masterpiece. Yazda, 1391 (in Persian).
 Pirnia, Mohammad Karim. Iranian Architecture. Memarian, 1395 (in Persian). Collected by Memarian, Gholam Hossein.
 Abousabaa, Mohammad Reza and Khodakarami, Jamal. Investigating the physics of traditional windcatcher and their disadvantages with a ffunctional optimization approach. in 1th international conference on new energy maintenance approaches, Tehran, 1390 (in Persian). Amirkabir University of Technology.
 Escandari, Mohsen and Kamran Kasmaei, Hadiseh. Investigating the typology of windcatchers, their advantages, disadvantages and correcting them in terms of sustainability. in Third annual conference on architectural, urban planning and urban management research, Shiraz, 1390 (in Persian). Mehrazi Road Ambassadors Architecture and Urban Planning Institute.
 Ardakan one-sided windcatcher. Online, 1398 (in Persian). https://www.isna.ir/news/yazd-62106/.
 Six wind-catchers reservoir in yazd. Online, 1398 (in Persian). https://bit.ly/2Vbnntf.
 Patel, D and Rajan, ST. Design of a passive and wind speed responsive wind catcher for energy efficient buildings. IJIRST–International Journal for Innovative Research in Science & Technology, 1(8), 2015.
 Calautit, John Kaiser, Hughes, Ben Richard, and Shahzad, Sally Salome. Cfd and wind tunnel study of the performance of a uni-directional wind catcher with heat transfer devices. Renewable Energy, 83:85–99, 2015.
 Maleki, B Ahmadkhani. Wind catcher: passive and low energy cooling system in iranian vernacular architecture. International Journal on Technical and Physical Problems of Engineering (IJTPE), 8:130–137, 2011.
 Hosseini, SH, Shokry, E, Hosseini, AJ Ahmadian, Ahmadi, G, and Calautit, JK. Evaluation of airflow and thermal comfort in buildings ventilated with wind catchers: Simulation of conditions in yazd city, iran. Energy for Sustainable Development, 35:7–24, 2016.
 Bahadori, Mehdi N. An improved design of wind towers for natural ventilation and passive cooling. Solar Energy, 35(2):119–129, 1985.
 Bahadori, MN, Mazidi, M, and Dehghani, AR. Experimental investigation of new designs of wind towers. Renewable Energy, 33(10):2273–2281, 2008.
 Jafarian, SM, Jaafarian, SM, Haseli, P, and Taheri, M. Performance analysis of a passive cooling system using underground channel (naghb). Energy and Buildings, 42(5):559–562, 2010.
 Soutullo, S, Sanjuan, C, and Heras, MR. Energy performance evaluation of an evaporative wind tower. Solar energy, 86(5):1396–1410, 2012.
 Abdallah, Amr Sayed Hassan, Hiroshi, Yoshino, Goto, Tomonobu, Enteria, Napoleon, Radwan, Magdy M, and Eid, M Abdelsamei. Parametric investigation of solar chimney with new cooling tower integrated in a single room for new assiut city, egypt climate. International Journal of Energy and Environmental Engineering, 5(2-3):92, 2014.
 Benhammou, M, Draoui, B, Zerrouki, M, and Marif, Y. Performance analysis of an earth-to-air heat exchanger assisted by a wind tower for passive cooling of buildings in arid and hot climate. Energy conversion and management, 91:1–11, 2015.
 Jassim, JAAW. Sustainable design of wind-catcher of an earth-to-air heat exchanger in hot dry areas. International Journal of Scientific & Engineering Research, 6(4):582– 589, 2015.
 Chaudhry, Hassam Nasarullah, Calautit, John Kaiser, and Hughes, Ben Richard. Computational analysis of a wind tower assisted passive cooling technology for the built environment. Journal of Building Engineering, 1:63–71, 2015.
 Khani, SMR, Bahadori, MN, and Dehghani-Sanij, AR. Experimental investigation of a modular wind tower in hot and dry regions. Energy for Sustainable Development, 39:21–28, 2017.
 Calautit, John Kaiser, Aquino, Angelo I, Shahzad, Sally, Nasir, Diana SNM, and Hughes, Ben Richard. Thermal comfort and indoor air quality analysis of a low-energy cooling windcatcher. Energy Procedia, 105:2865–2870, 2017.
 Soltani, Madjid, Dehghani-Sanij, Alireza, Sayadnia, Ahmad, Kashkooli, Farshad M, Gharali, Kobra, Mahbaz, SeyedBijan, and Dusseault, Maurice B. Investigation of airflow patterns in a new design of wind tower with a wetted surface. Energies, 11(5):1100, 2018.
 Seidabadi, Leila, Ghadamian, Hossein, and Aminy, Mohammad. A novel integration of pcm with wind-catcher skin material in order to increase heat transfer rate. International Journal of Renewable Energy Development, 8(1):1–6, 2019.