Research articles

1. Patchareeya Jaipakdee, Pathompong Vibhatabandhu, Phanpaporn Vitayavarawat, Nuta Supakata, Waste composition and engagement in management initiatives: A study at Chulalongkorn University across academic periods, Green Technologies and Sustainability, 2025, 100252, https://doi.org/10.1016/j.grets.2025.100252.

2. Patchareeya Jaipakdee, Ananya Prhomraksa, Supitsara Taprit, Nuttakorn Intaravicha, Sarawut Srithongouthai, Vorapot Kanokkantapong, Nuta Supakata, Characteristics of soil amendment produced from composting food waste and bioplastic bags, Results in Engineering,

2025, 106396, https://doi.org/10.1016/j.rineng.2025.106396.

3. Pornpan Kuekham, Nannaphat Peeraphunkuldech, Nuta Supakata, Paving blocks produced with crushed glass and high-density polyethylene: A case study of glass bottle and plastic waste management on Si Chang Island, Case Studies in Chemical and Environmental Engineering, 2024,100969, https://doi.org/10.1016/j.cscee.2024.100969.

4. Choochote, P. & Supakata, N. (2025). Urban food waste generation and sustainable management strategies: a case study of Nonthaburi Municipality, Thailand. Scientific Reports 15: 18405. https://doi.org/10.1038/ s41598-024- 52298-8.

5. Oludoye, O.O., Supakata, N. (2024). Breakingthe plastic habit: Drivers of single-use plastic reduction among Thai university students. PLoSONE19(5): e0299877. https://doi.org/10.1371/journal.pone.0299877.

6. Oludoye O.O., Supakata, N., Srithongouthai, S., Kanokkantapong, V., Broucke, S., Ogunyebi, L., Lubell, M. (2024). Pro-environmental behavior regarding single-use plastics reduction in urban-rural communities of Thailand: Implication for public policy. Scientific Reports 14: 4713. https://doi.org/10.1038/s41598-024-55192-5.

7. Kumpueng, P., Phutthimethakul, L. & Supakata, N. (2024). Production of Cement mortars from glass powder and municipal incinerated bottom ash. Scientific Reports 14: 1569. https://doi.org/10.1038/s41598-024-52298-8.

8. Srinok, K., Supakata, N., & Papong, S. (2024). Assessment of greenhouse gas emissions from waste management in the shopping center: A case study of the Central Plaza Rattanathibet, Thailand. Journal of Advanced Development in Engineering and Science 13(38). https://ph03.tci-thaijo.org/index.php/pitjournal/article/view/619.

9. Oludoye, O.O., Broucke, S., Chen, X., Supakata, N., Ogunyebi, A., Njoku, K. (2023). Identifying the determinants of face mask disposal behavior and policy implications: An application of the extended Theory of Planned Behavior. Resources, Conservation & Recycling Advances 18: 200148. https://doi.org/10.1016/j.rcradv.2023.200148.

10. Kwanyun, P., Praditwattana, N., Phutthimethakul, L., Chart-asa, C.; Intaravicha, N., Supakata, N. (2023). Characteristics of Soil Amendment Material from Food Waste Disposed of in Bioplastic Bags. Fermentation  9: 97. https://doi.org/10.3390/fermentation9020097.

11. Sukma, P., Srinok, K., Papong, S., Supakata, N. (2022). Chula model for sustainable municipal solid waste management in university canteens. Heliyon 8:e10975. https://doi.org/10.1016/j.heliyon.2022.e10975.

12. Phutthimethakul, L. and Supakata, N. (2022). Partial Replacement of Municipal Incinerated Bottom Ash and PET Pellets as Fine Aggregate in Cement Mortars. Polymers 14: 2597. https://doi.org/10.3390/polym14132597

13. Klomklang, U., Kulsirilak, N., Intaravicha, N., and Supakata, N. (2021). Vermicompost from Chula Zero Waste Cup and Rain Tree (Samanea Saman) Leaves. Engineering Journal (25): 1-10.

14. Chalermsakulkit, W., and Supakata, N. (2021). Effect of Using Flue-Gas Desulfurization Gypsum and Water Treatment Sludge on Compressive Strength of Cement Mortar. Key Engineering Materials 897: 143-149.

15. Phutthimethakul, L., Kumpueng, P., Supakata, N. (2020). Use of Flue Gas Desulfurization Gypsum, Construction and Demolition Waste, and Oil Palm Waste Trunks to Produce Concrete Bricks. Crystals 10:709. https://doi.org/10.3390/cryst10080709.

16. Apithanyasai, S., Supakata, N., and Papong, S. (2020). The potential of industrial waste: using foundry sand with fly ash and electric arc furnace slag for geopolymer brick production. Heliyon 6: e03697. https://doi.org/10.1016/j.heliyon.2020.e03697.

17. Dontriros, S., Nooaek, P., and Supakata, N. (2020). Geopolymer Bricks from Concrete Residue and Palm Oil Fuel Ash: Evaluating Physical-mechanical Properties, Life Cycle Assessment and Economic Feasibility. EnvironmentAsia 13 (1): 150-162. https://www.thaiscience.info/view_content.asp?id=10992191.

18. Chaisuwan, N., Kansai, N., Supakata, N., and Papong, S. (2020). The Comparison of Environmental Impacts of Carbonized Briquettes from Rain Tree Residues and Coffee Grounds/Tea Waste and Traditional Waste Management. International Journal of Environmental Science and Development 11 (1): 48-53. https://www.ijesd.org/show-142-1707-1.html.

19. Warnphen, H., Supakata, N., and Kanokkantapong, V. The Reuse of Waste Glass as Aggregate Replacement for Producing Concrete Bricks as an Alternative for Waste Glass Management on Koh Sichang. Engineering Journal. 2019 23 (5): 43-58. https://doi.org/10.4186/ej.2019.23.5.43.

20. Sangpatch, T., Supakata, N., Kanokkantapong, V., and Jongsomjit, B. Fuel oil generated from the cogon grass-derived Al-Si (Imperata cylindrica (L.) Beauv) catalysed pyrolysis of waste plastics. Heliyon. 2019 5: 1 - 8. https://doi.org/10.1016/j.heliyon.2019.e02324.

21. Punthama, C., Supakata, N., and Kanokkantapong, V. Characteristics of Concrete Bricks After Partially Substituting Portland Cement Type 1 with Cement and Seashell Waste and Partially Substituting Sand with Glass Waste. EnvironmentAsia. 2019 12 (1): 36 - 48. https://www.thaiscience.info/view_content.asp?id=10992037.

22. Kansai, N., Chaisuwan, N., and Supakata N. Carbonized briquettes as a tool for adding value to waste from rain tree and coffee ground/tea waste. Engineering Journal. 2018 22 (6): 47-63. https://doi.org/10.4186/ej.2018.22.6.47.

23. Supakata, N. Bin monsters for promoting waste separation. Applied Environmental Education and Communication. 2018 17 (4): 310-322. https://doi.org/10.1080/1533015X.2017.1415774.

24. Apithanyasai, S., Nooaek, P., and Supakata N. The utilization of concrete residue with electric arc furnace slag in the production of geopolymer bricks. Engineering Journal. 2018 22 (1): 1-14. https://doi.org/10.4186/ej.2018.22.1.1.

25. Sirikingkaew, S. and Supakata, N. Utilization of Fly Ash and Concrete Residue in the Production of Geopolymer Bricks. Journal of Green Building. 2017 12: 63-77.

26. Siriruekratana, S. and Supakata, N. Development of geopolymer bricks from synergistic use of bagasse ash and concrete residue as an alternative for industrial waste management. Naresuan Journal. 2017 25: 69-78.

27. Sagdinakiadtikul, T. and Supakata, N. The Application of Using Rice Straw Coconut Shell and Rice Husk for Briquette and Charcoal Production. International Journal of Energy, Environment, and Economics. 2017 24: 283-292.