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• [1] Huang, Y., Bird, R. N., & Heidrich, O. (2007). A review of the use of recycled solid waste materials in asphalt pavements. Resources, conservation and recycling, 52(1), 58-73.
• [2] Cetin, M., Altera A.Z.A., Bayraktar O.Y. (2019) Advanced Road Materials in Highway Infrastructure and Features. Kastamonu University Journal of Engineering and Sciences 5(1): 36-42.
• [3] Bayraktar, O.Y. (2019). The possibility of fly ash and blast furnace slag disposal by using these environmental wastes as substitutes in portland cement. Environmental monitoring and assessment, 191(9), 560. https://doi.org/10.1007/s10661-019-7741-4
• [4] Bayraktar, O.Y., Citoglu G.S., Belgin C.M., Cetin M. (2019). Investigation of the mechanical properties of marble dust and silica fume substituted portland cement samples under high temperature effect, Fresenius Environmental Bulletin, 28(5): 3865-3875.
• [5] Bayraktar, O.Y., Citoglu G.S., Belgin C.M., Cetin, S., Cetin M. (2019) Investigation of effect of brick dust and silica fume on the properties of portland cement mortar, Fresenius Environmental Bulletin 28(11): 7823-7832.
• [6] Bayraktar O.Y., Citoglu G.S., & Abo Aisha A.E.S. (2019) The use of scrap tires in the construction sector, International Journal of Trend in Research and Development, 6(1), 253-256. ISSN: 2394-9333, http://www.ijtrd.com/papers/IJTRD20299.pdf
• [7] Bayraktar O.Y., Citoglu G.S., & Abo Aisha A.E.S. (2019) Performance research of lime based mortars, International Journal of Trend in Research and Development, 6(1), 257-259. ISSN: 2394-9333, http://www.ijtrd.com/papers/IJTRD20300.pdf
• [8] Bayraktar, O. Y. (2012). Alternatif Sıva Harçlarının Yüksek Sıcaklık Etkisine Dayanıklılığı (Yüksek Lisans Tezi, Gazi Üniversitesi, Ankara-Türkiye).
• [9] Bayraktar, O. Y. (2016). Puzolanik Katkı Malzemeleriyle Üretilen Harçlarda Sıcaklık Etkisİ Altında Meydana Gelebilecek Kaza Anındaki Mekanik Davranışlarının İstatistiksel Olarak Karşılaştırılması. (Doktora Tezi, Gazi Üniversitesi, Ankara-Türkiye
• [10] Brooks, R., & Cetin, M. (2012) Application of construction demolition waste for improving performance of subgrade and subbase layers, Int. J. Res. Rev. Appl. Sci 12 (3), 375-381
• [11] Cetin, M. (2015). Chapter 55: Using Recycling Materials for Sustainable Landscape Planning. ST. Kliment Ohridski University Press, SOFIA. Book: Environment and Ecology at the Beginning of 21st Century. Eds: Recep Efe, Carmen Bizzarri, İsa Cürebal, Gulnara N. Nyusupova, ISBN:978-954-07-3999-1, pp.783-788.
• [12] Cetin, M. (2015). Consideration of permeable pavement in landscape architecture, Journal of Environmental Protection and Ecology 16 (1), 385-392
• [13] Cetin, M. (2013). Chapter 27: Landscape Engineering, Protecting Soil, and Runoff Storm Water. InTech-Open Science-Open Minds. Book: Advances in Landscape Architecture-Environmental Sciences. Eds: Murat Ozyavuz, , ISBN 978-953-51-1167-2, pp.697-722.
• [14] Cetin, M. (2013). Pavement design with porous asphalt, Temple University, Ph.D. Thesis, Philadelphia, USA.
• [15] Cetin, M., Adiguzel, F., Kaya, O., Sahap, A. (2018) Mapping of bioclimatic comfort for potential planning using GIS in Aydin. Environment, Development and Sustainability. 20(1), 361-375.
• [16] Cetin, M. (2017) Change in Amount of Chlorophyll in Some Interior Ornamental Plants. Kas-tamonu University Journal of Engineering and Sciences. 3(1), 11-19. [17] Kaya, E., Agca, M., Adiguzel, F., Cetin, M. (2019) Spatial data analysis with R programming for environment. Human and Ecological Risk Assessment: An International Journal 25 (6): 1521-1530. https://www.tandfonline.com/doi/full/10.1080/10807039.2018.1470896
• [18] Cetin, M. (2019). The effect of urban planning on urban formations determining bioclimatic comfort area's effect using satellitia imagines on air quality: a case study of Bursa city. (2019), pp. 1-13. Air Quality, Atmosphere & Health, 2019. Air Qual Atmos Health (2019). https://doi.org/10.1007/s11869-019-00742-4 https://rd.springer.com/article/10.1007/s11869-019-00742-4
• [19] Cetin, M., Adiguzel, F., Gungor, S., Kaya, E., Sancar, M.S. (2019) Evaluation of thermal climatic region areas in terms of building density in urban management and planning for Burdur, Turkey. Air Quality Atmosphere & Health (Air Qual Atmos Health) 12 (9): 1103-1112. https://doi.org/10.1007/s11869-019-00727-3; https://link.springer.com/content/pdf/10.1007%2Fs11869-019-00727-3.pdf
• [20] Ahmadinia, E., Zargar, M., Karim, M. R., Abdelaziz, M., & Shafigh, P. (2011). Using waste plastic bottles as additive for stone mastic asphalt. Materials & Design, 32(10), 4844-4849.
• [21] Ahmadinia, E., Zargar, M., Karim, M. R., Abdelaziz, M., and Ahmadinia, E. (2012). Execution assessment of use of waste Polyethylene Terephthalate (PET) in stone mastic asphalt. Development and Building Materials, 36, 984-989.
• [22] Hınıslıoğlu, S., and Ağar, E. (2004). Utilization of waste high thickness polyethylene as bitumen modifier in asphalt solid blend. Materials letters, 58(3-4), 267-271.
• [23] Jain, P. K., Kumar, S., and Sengupta, J. B. (2011). Alleviation of rutting in bituminous streets by utilization of waste polymeric bundling materials.
• [24] Al-Mehthel, M., Wahhab, H. I. A. An., and Hussein, I. A. (2013). U.S. Patent No. 8,444,761. Washington, DC: U.S. Patent and Trademark Office.
• [25] Hansen, K. R., McGennis, R. B., Prowell, B. R. I. A. N., and Stonex, A. N. N. E. (2000). Present and future employments of non-bituminous parts of bituminous clearing blends. Transportation in the New Millennium.
• [26] Yang, X., You, Z., Dai, Q., and Mills-Beale, J. (2014). Mechanical execution of asphalt blends adjusted by bio-oils got from waste wood assets. Development and Building Materials, 51, 424-431.
• [27] Kalantar, Z. N., Karim, M. R., and Mahrez, A. (2012). An audit of utilizing waste and virgin polymer in asphalt. Development and Building Materials, 33, 55-62.
• [28] Chandra, S., and Choudhary, R. (2012). Execution qualities of bituminous cement with modern squanders as filler. Diary of materials in structural building, 25(11), 1666-1673.
• [29] McNally, T. (Ed.). (2011). Polymer adjusted bitumen: Properties and characterisation. Elsevier.
• [30] Brooks, R. M., Jyothsna, K. S., & Cetin, M. (2012). Interrupted case method for teaching ethics in transportation engineering and systems management course. In American Society for Engineering Education. American Society for Engineering Education.
• [31] Cetin, M., Brooks, R. M., & Udo-Inyang, P. (2012). An innovative design methodology of pavement design by limiting surface deflection. International Journal of Research and Reviews in Applied Sciences, 13(2).
• [32] Cetin, M., Brooks, R. M., & Udo-Inyang, P. (2012). A comparative study between the results of an innovative design methodology by limiting surface deflection and AASHTO design method. Int J Recent Res Appl Stud, 13, 611-616.
• [33] Shu, X., and Huang, B. (2014). Reusing of waste tire elastic in asphalt and portland cement concrete: A review. Development and Building Materials, 67, 217-224.
• [34] Grzybowski, K. F. (1993). U.S. Patent No. 5,217,530. Washington, DC: U.S. Patent and Trademark Office.
• [35] Borhan, M. N., Ismail, An., and Rahmat, R. A. (2010). Assessment of palm oil fuel fiery remains (POFA) on asphalt blends. Australian Journal of Basic and Applied Sciences, 4(10), 5456-5463.
• [36] Presti, D. L. (2013). Reused tire elastic adjusted bitumens for street asphalt blends: A writing audit. Development and Building Materials, 49, 863-881.
• [37] Pasetto, M., and Baldo, N. (2010). Test assessment of superior base course and street base asphalt concrete with electric bend heater steel slags. Diary of dangerous materials, 181(1-3), 938-948.
• [38] Arabani, M., Tahami, S. An., and Taghipoor, M. (2017). Research facility examination of hot blend asphalt containing waste materials. Street Materials and Pavement Design, 18(3), 713-729.
• [39] Pereira, S. M., Oliveira, J. R., Freitas, E. F., and Machado, P. (2013). Mechanical execution of asphalt blends created with stopper or elastic grinds as total fractional substitutes. Development and Building Materials, 41, 209-215.
• [40] Pasetto, M., and Baldo, N. (2011). Blend plan and execution examination of asphalt cements with electric bend heater slag. Development and Building Materials, 25(8), 3458-3468.
• [41] Hussein, A. A., Jaya, R. P., Hassan, N. A., Yaacob, H., Huseien, G. F., and Ibrahim, M. H. W. (2017). Execution of nanoceramic powder on the synthetic and physical properties of bitumen. Development and Building Materials, 156, 496-505.
• [42] Ameri, M., Hesami, S., and Goli, H. (2013). Lab assessment of warm blend asphalt blends containing electric circular segment heater (EAF) steel slag. Development and Building materials, 49, 611-617.
• [43] Sojobi, A. O., Nwobodo, S. E., and Aladegboye, O. J. (2016). Reusing of polyethylene terephthalate (PET) plastic jug squanders in bituminous asphaltic cement. Apt building, 3(1), 1133480.
• [44] Vasudevan, R. N. S. K., Velkennedy, R., Sekar, A. R. C., and Sundarakannan, B. (2010). Use of waste polymers for adaptable asphalt and simple transfer of waste polymers. Universal Journal of Pavement Research and Technology, 3(1), 34-42. [45] Karakurt, C. (2015). Microstructure properties of waste tire elastic composites: an outline. Diary of Material Cycles and Waste Management, 17(3), 422-433.
• [46] Abdelaziz, M., and Mohamed Rehan, K. (2010). Rheological assessment of bituminous cover changed with waste plastic material. [47] Fini, E. H., Al-Qadi, I. L., You, Z., Zada, B., and Mills-Beale, J. (2012). Fractional replacement of asphalt folio with bio-fastener: characterisation and adjustment. Global Journal of Pavement Engineering, 13(6), 515-522.
• [48] Zoorob, S. E., and Suparma, L. B. (2000). Research facility structure and examination of the properties of ceaselessly evaluated Asphaltic cement containing reused plastics total replacement (Plastiphalt). Cement and Concrete Composites, 22(4), 233-242.
• [49] Katara, S. D., Modhiya, C. S., and Raval, N. G. (2014). Impact of change bituminous blend with fly slag. Universal Journal of Engineering and Technical Research (IJETR) ISSN, 2321-0869.
• [50] Yousefi, A. A. (2009). Polymer-changed bitumen from the losses of petrochemical plants.
• [51] Šušteršič, E., Tušar, M., and Valant, A. Z. (2014). Asphalt solid change with waste PMMA/ATH. Materials and structures, 47(11), 1817-1824.
• [52] Costa, L. M., Hugo, M. R., Silva, D., Oliveira, J. R., and Fernandes, S. R. (2013). Consolidation of waste plastic in asphalt folios to improve their execution in the asphalt. Global diary of asphalt research and innovation, 6(4), 457-464.
• [53] Abreu, L. P., Oliveira, J. R., Silva, H. M., and Fonseca, P. V. (2015). Reused asphalt blends created with high level of various waste materials. Development and Building Materials, 84, 230-238.