งานวิจัยของคณาจารย์ด้านมลภาวะและการจัดการสิ่งแวดล้อม

รศ.ดร. พรไสว ไพรพิภัช

สาขาวิชาวิทยาศาสตร์สิ่งแวดล้อม
e-mail : pornprai@kku.ac.th
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ผลงานตีพิมพ์

    1. Sirijaree, T., and Praipipat, P*. 2023. Adsorption of Lead (II) Ions onto Goethite Chitosan Beads: Isotherms, Kinetics, and Mechanism Studies. ChemEngineering 7(3):52. DOI: 10.3390/chemengineering7030052. Q1, IF=3.18.

    2. Praipipat, P*., Jangkorn, S., and Ngamsurach, P. 2023. Powdered and beaded zeolite A from recycled coal fly ash with modified iron (III) oxide-hydroxide for lead adsorptions. Environmental Nanotechnology, Monitoring & Management. 20:100812. DOI: 10.1016/j.enmm.2023.100812. Q1, IF= 5.950.

    3. Praipipat, P*., Ngamsurach, P., and Pratumkaew, K. 2023. The synthesis, characterizations, and lead adsorption studies of chicken eggshell powder and chicken eggshell powder-doped iron (III) oxide-hydroxide. Arabian Journal of Chemistry. 16(5):104640. DOI: 10.1016/j.arabjc.2023.104640. Q1, IF= 6.212.

    4. Praipipat, P*., Ngamsurach, P., and Roopkhan, N. 2023. Zeolite A powder and beads from sugarcane bagasse fly ash modified with iron(III) oxide-hydroxide for lead adsorption. Scientific Reports. 13: 1873. DOI: 10.1038/s41598-023-29055-4. Tier1, Q1, IF= 4.996.

    5. Praipipat, P*., Ngamsurach, P., and Sanghuayprai, A. 2023.Modification of sugarcane bagasse with iron (III) oxide-hydroxide to improve its adsorption property for removing lead (II) ion. Scientific Reports. 13: 1467. DOI: 10.1038/s41598-023-28654-5. Tier1, Q1, IF= 4.996.

    6. Praipipat, P*., Ngamsurach, P., Kosumphan, S., and Mokkarat, J. 2023. Powdered and beaded sawdust materials modified iron (III) oxide-hydroxide for adsorption of lead (II) ion and reactive blue 4 dye. Scientific Reports. 13: 531. DOI: 10.1038/s41598-023-27789-9. Tier1, Q1, IF= 4.996.

    7. Praipipat, P*., Ngamsurach, P., Thanyahan, A., Sakda, A., and Nitayarat, J.2023. Dye removal efficacies of reactive blue 4 by bagasse and bagasse fly ash beads with modified with itanium dioxide (TiO2), magnesieum oxide (MgO), and aluminium oxide (Al2O3). Industrial Crops & Products. 191:115928. DOI: 10.1016/j.indcrop.2022.115928. Q1, IF= 6.449.

    8. Ngamsurach, P. and Praipipat, P.* 2022. Comparative antibacterial activities of Garcinia cowa and Piper sarmentosum extracts against Staphylococcus aureus and Escherichia coli with studying on disc diffusion assay, material characterizations, and batch experiments. Heliyon. 8(11): e11704. DOI: 10.1016/j.heliyon.2022.e11704. Q1, IF= 3.776.

    9. Praipipat, P.*, Ngamsurach, P., and Prasongdee, V. 2022. Comparative reactive blue 4 dye removals by lemon peel beads doping with iron (III) oxide-hydroxide and zinc oxide. ACS Omega. 7(45): 41744–41758. DOI: 10.1021/acsomega.2c05956. Q1, IF= 4.132.

    10. Ngamsurach, P., Namwongsa, N., and Praipipat, P.* 2022. Synthesis of powdered and beaded chitosan materials modified with ZnO for removing lead (II) ions. Scientific Reports. 12: 17184. DOI: 10.1038/s41598-022-22182-4. Tier1, Q1, IF= 4.996.

    11. Praipipat, P.*, Ngamsurach, P., Saekrathoka, C., and Phomtaia, S. 2022.Chicken and duck eggshell beads modified with iron (III) oxide-hydroxide and zinc oxide for reactive blue 4 dye removals. Arabian Journal of Chemistry. 15(11):104291.DOI: 10.1016/j.arabjc.2022.104291. Q1, IF= 6.212.

    12. Ngamsurach, P., Nemkhuntod, S., Chanaphan, P., and Praipipat, P.* 2022. Modified beaded materials from recycled wastes of bagasse and bagasse fly ash with iron (III) oxide-hydroxide and zinc oxide for the removal of reactive blue 4 dye in aqueous solution. ACS Omega. 7(39): 34839–34857. DOI: 10.1021/acsomega.2c03250. Q1, IF= 4.132.

    13. Ngamsurach, P. and Praipipat, P.* 2022. Antibacterial activities against Staphylococcus aureus and Escherichia coli of extracted Piper betle leaf materials by disc diffusion and batch experiments. RSC Advances. 12 (40): 26435-26454. DOI: 10.1039/D2RA04611C. Q1, IF= 4.036.

    14. Jangkorn, S and Praipipat, P.* 2022. Comparative non-acid wash and acid wash preparations for zeolite A synthesis from coal fly ash. EnvironmentAsia. 15(3): 152-161. DOI: 10.14456/ea.2022.57. Q3, IF=0.538.

    15. Threepanich, A. and Praipipat, P.* 2022. Efficacy study of recycling materials by lemon peels as novel lead adsorbents with comparing of material form effects and possibility of continuous flow experiment. Environmental Science and Pollution Research. 29(30). DOI: 10.1007/s11356-022-19131-z. Q1, IF= 5.190.

    16. Jangkorn, S, Youngme, S., and Praipipat, P.* 2022. Comparative lead adsorptions in synthetic wastewater by synthesized zeolite A of recycled industrial wastes from sugar factory and power plant. Heliyon 8(4): e09323. DOI: 10.1016/j.heliyon.2022.e09323. Q1, IF= 3.776.

    17. Ngamsurach, P. and Praipipat, P.* 2021. Modified alginate beads with ethanol extraction of Cratoxylum formosum and Polygonum odoratum for antibacterial activities. ACS Omega 6(47): 32215-32230. DOI: 10.1021/acsomega.1c05056. Q1, IF= 4.132.

    18. Threepanich, A. and Praipipat, P.* 2021. Powdered and beaded lemon peels-doped iron (III) oxide-hydroxide materials for lead removal applications: Synthesis, characterizations, and lead adsorption studies. Journal of Environmental Chemical Engineering. 9(5):106007. https://doi.org/10.1016/j.jece.2021.106007. Q1, IF= 7.968.

    19. Ngamsurach, P and Praipipat, P.* 2020. Antibacterial Activities against Staphylococcus aureus and Escherichia coli of the Plant Extracts. Pure and Applied Chemistry International Conference 2020 (PACCON 2020) on February 13-14, 2020 at IMPACT Forum, Muangthong Thani, Bangkok, Thailand (Proceeding paper).

    20. Threepanich, A and Praipipat, P.* 2020. Comparative lead removal efficiency between lemon peels and lemon peels with metal oxide in the aqueous solution. Pure and Applied Chemistry International Conference 2020 (PACCON 2020) on February 13-14, 2020 at IMPACT Forum, Muangthong Thani, Bangkok, Thailand (Proceeding paper).

    21. Foansoongnen, N., Ngeontae, W., and Praipipat, P.* 2018. Bacterial removal in wastewater by using silver nanoclusters materials. 2018. Pure and Applied Chemistry International Conference 2018 (PACCON 2018) on February 7-9, 2018 at International Convention Center (ICC Hat Yai), Hat Yai, SongKhla, Thailand (Proceeding paper).

    22. Rooblert, R., Youngme, S., and Praipipat, P.* 2018. The antibacterial activities of silver nanomaterials againt gram positive and gram negative bacteria. Pure and Applied Chemistry International Conference 2018 (PACCON 2018) on February 7-9, 2018 at International Convention Center (ICC Hat Yai), Hat Yai, SongKhla, Thailand (Proceeding paper).

    23. Puangpaka, S., Yatongchai, C., and Praipipat, P.* 2017. Synthesis of hydroxyapatite using lime mud by mechanochemical method. Pure and Applied Chemistry International Conference 2017 (PACCON 2017) on February 2-3, 2017 at Centra Government Complex Hotel & Convention Centre Chaeng Wattana, Bangkok, Thailand (Proceeding paper).

    24. Sangpara, V., Yatongchai, C., and Praipipat, P.* 2017. Synthesis of nano-sized hydroxyapatite from lime mud usung chemical precipitation technique. Pure and Applied Chemistry International Conference 2017 (PACCON 2017) on February 2-3, 2017 at Centra Government Complex Hotel & Convention Centre Chaeng Wattana, Bangkok, Thailand (Proceeding paper).

    25. Praipipat, P., Meng, Q.Y., Miskewitz, R.J., and Rdenburg, L.A. 2017. Source Apportionment of Atmospheric Polycholrinated Biphenyls in New Jersey 1997-2011. Environ.Sci.Technol. 51(3):1195-1202. DOI: 10.1021/acs.est.6b04572. Tier1, Q1, IF= 11.357.

    26. Praipipat, P., M. Mohamed El-Moselhy, K. Khuanmar, P. Weerayutsil, T. Thanh Nguyen, S. Padungthon, Enhanced Defluoridation using Reusable Strong Acid Cation Exchangers in Al3+ form (SAC-Al) Containing Hydrated Al (III) Oxide Nanoparticles, Chemical Engineering Journal. Vol.314, pp.192-201, 2017. DOI: 10.1016/j.cej.2016.12.122. Tier1, Q1, IF= 16.744.

    27. Padungthon, S., Chanthapon, N., El-Moselhy, M.M., and Praipipat, P.* 2017. Trace lead removal in drinking water using high capacity polymeric supported hydrated iron oxide nanoparticles. DOI: 10.4028/www.scientific.net/KEM.718.72. Key Engineering Material. Q4, IF= 0.49.

    28. Pranudta, A., Praipipat, P., El-Moselhy, M.M., and Padungthon, S. 2017. Binary Fe and Mn oxide nanoparticle supported polymeric anion exchanger for arsenic adsorption: role of oxides, supported materials, and preparation solvent. DOI: 10.4028/www.scientific.net/KEM.718.105. Key Engineering Material. Q4, IF= 0.49.

    29. Chanthapo, N., Praipipat, P., Sarkar, S, and Padungthon, S. 2017. Synthesis, characterization and performance validation of hybrid cation exchanger containing hydrated ferric oxide nanoparticles (HCIX-Fe) for lead removal from battery manufacturing wastewater. DOI: 10.4028/www.scientific.net/KEM.718.67. Key Engineering Material. Q4, IF= 0.49.

    30. Praipipat, P., Rodenburg, L.A., and Cavallo, G.J. 2013. Source Apportionment of Polychlorinated Biphenyls in the Sediments of the Delaware River. Environ.Sci.Technol. 47:4277-4283. DOI: 10.1021/es400375e. Tier1, Q1, IF=11.357.

รางวัลที่เคยได้รับ

    1. รางวัลวิทยานิพนธ์ระดับดีเด่น (ระดับทอง) โครงการวิทยานิพนธ์ดีเด่น ประจำปี 2565 เรื่อง การใช้สารสกัดจากพืชเพื่อใช้ในการยับยั้งเชื้อแบคทีเรียแกรมบวก (Staphylococcus aureus) และแกรมลบ (Escherichia coli) ในน้ำ (THE USE OF PLANT EXTRACT FOR INHIBITION OF GRAM POSITIVE (Staphylococcus aureus) AND GRAM NEGATIVE BACTERIA (Escherichia coli) IN THE WATER) โดย นางสาวพิมพลอย แง่มสุราช

    2. รางวัลวิทยานิพนธ์ระดับดีเด่น (ระดับทอง) โครงการวิทยานิพนธ์ดีเด่น ประจำปี 2565 เรื่อง การกำจัดตะกั่วในน้ำโดยใช้วัสดุพันธุ์ผสมจากเปลือกเลมอนและโลหะออกไซด์ (REMOVAL OF Pb(II) IN THE WATER BY USING THE HYBRID MATERIALS OF LEMON PEELS AND METAL OXIDE) โดย นางสาวอาภัสสร ตรีพานิชย์

งานวิจัยที่สนใจ

1. Environmental Monitoring, including Polychlorinated Biphenyls (PCBs)
2. Environmental Separation/ Water Chemistry: Sorption, Ion exchange, and trace contamination removal, e.g. heavy metals.
3. Water and Wastewater Treatments and Designs
4. Environmental Toxicology