ตุลวิทย์ สถาปนจารุ
รองศาสตราจารย์
ภาควิชาเทคโนโลยีและการจัดการสิ่งแวดล้อม คณะสิ่งแวดล้อม บางเขน
fscitus@ku.ac.th
0-2942-8036
EDUCATION
- Ph.D.(Natural Resource Science), University of Nebraska, USA
- วท.ม. (วิทยาศาสตร์สภาวะแวดล้อม), จุฬาลงกรณ์มหาวิทยาลัย , ไทย
- วท.บ. วิทยาศาสตร์สิ่งแวดล้อม), มหาวิทยาลัยธรรมศาสตร์ , ไทย
RESOURCE
แหล่งที่มา
ผลงาน
Works
INTEREST
ความสนใจ
Environmental Remediation, Non-point Source Pollution Control, Waste Mininization
Expertise Cloud
ความเชี่ยวชาญ
Person
Relationship
นักวิจัย
ที่มีผลงานมากที่สุด 10 คนแรก
Scopus
h-index
h-index: 20
| # | Document title | Authors | Year | Source | Cited by |
|---|---|---|---|---|---|
| 1 | Sorption of reactive dye from aqueous solution on biomass fly ash | Pengthamkeerati P., Satapanajaru T., Singchan O. | 2008 | Journal of Hazardous Materials, 153(3), pp. 1149-1156 | 188 |
| 2 | Chemical modification of coal fly ash for the removal of phosphate from aqueous solution | Pengthamkeerati P., Satapanajaru T., Chularuengoaksorn P. | 2008 | Fuel, 87(12), pp. 2469-2476 | 177 |
| 3 | Remediation of atrazine-contaminated soil and water by nano zerovalent iron | Satapanajaru T., Anurakpongsatorn P., Pengthamkeerati P., Boparai H. | 2008 | Water, Air, and Soil Pollution, 192(1-4), pp. 349-359 | 130 |
| 4 | Enhancing decolorization of Reactive Black 5 and Reactive Red 198 during nano zerovalent iron treatment | Satapanajaru T., Chompuchan C., Suntornchot P., Pengthamkeerati P. | 2011 | Desalination, 266(1-3), pp. 218-230 | 106 |
| 5 | Toxicity, bioaccumulation and biomagnification of silver nanoparticles in green algae (Chlorella sp.), water flea (Moina macrocopa), blood worm (Chironomus spp.) and silver barb (Barbonymus gonionotus) | Yoo-iam M., Chaichana R., Satapanajaru T. | 2014 | Chemical Speciation and Bioavailability, 26(4), pp. 257-265 | 84 |
| 6 | Green Rust and Iron Oxide Formation Influences Metolachlor Dechlorination during Zerovalent Iron Treatment | Satapanajaru T., Shea P., Comfort S., Roh Y. | 2003 | Environmental Science and Technology, 37(22), pp. 5219-5227 | 79 |
| 7 | Hexavalent chromium adsorption from aqueous solution using carbon nano-onions (CNOs) | Sakulthaew C., Chokejaroenrat C., Poapolathep A., Satapanajaru T., Poapolathep S. | 2017 | Chemosphere, 184, pp. 1168-1174 | 78 |
| 8 | Alkaline treatment of biomass fly ash for reactive dye removal from aqueous solution | Pengthamkeerati P., Satapanajaru T., Chatsatapattayakul N., Chairattanamanokorn P., Sananwai N. | 2010 | Desalination, 261(1-2), pp. 34-40 | 68 |
| 9 | Enhancing metolachlor destruction rates with aluminum and iron salts during zerovalent iron treatment | Satapanajaru T., Comfort S.D., Shea P.J. | 2003 | Journal of Environmental Quality, 32(5), pp. 1726-1734 | 59 |
| 10 | Effect of land cover composition and building configuration on land surface temperature in an urban-sprawl city, case study in Bangkok Metropolitan Area, Thailand | Adulkongkaew T., Satapanajaru T., Charoenhirunyingyos S., Singhirunnusorn W. | 2020 | Heliyon, 6(8), e04485 | 59 |
| 11 | Pilot-scale treatment of RDX-contaminated soil with zerovalent iron | Comfort S.D., Shea P.J., Machacek T.A., Satapanajaru T. | 2003 | Journal of Environmental Quality, 32(5), pp. 1717-1725 | 31 |
| 12 | Spatial distribution and risk assessment of As, Cd, Cu, Pb, and Zn in Topsoil at Rayong Province, Thailand | Simasuwannarong B., Satapanajaru T., Khuntong S., Pengthamkeerati P. | 2012 | Water, Air, and Soil Pollution, 223(5), pp. 1931-1943 | 31 |
| 13 | Remediation and Restoration of Petroleum Hydrocarbon Containing Alcohol-Contaminated Soil by Persulfate Oxidation Activated with Soil Minerals | Satapanajaru T., Chokejaroenrat C., Sakulthaew C., Yoo-iam M. | 2017 | Water, Air, and Soil Pollution, 228(9), 345 | 28 |
| 14 | UV-activated persulfate oxidation of 17?-estradiol: Implications for discharge water remediation | Angkaew A., Sakulthaew C., Satapanajaru T., Poapolathep A., Chokejaroenrat C. | 2019 | Journal of Environmental Chemical Engineering, 7(2), 102858 | 28 |
| 15 | Treating methyl orange in a two-dimensional flow tank by in situ chemical oxidation using slow-release persulfate activated with zero-valent iron | Chokejaroenrat C., Sakulthaew C., Satapanajaru T., Tikhamram T., Pho-Ong A., Mulseesuk T. | 2015 | Environmental Engineering Science, 32(12), pp. 1007-1015 | 27 |
| 16 | Remediating sulfadimethoxine-contaminated aquaculture wastewater using ZVI-activated persulfate in a flow-through system | Chokejaroenrat C., Sakulthaew C., Angkaew A., Satapanajaru T., Poapolathep A., Chirasatienpon T. | 2019 | Aquacultural Engineering, 84, pp. 99-105 | 27 |
| 17 | Remediating dicamba-contaminated water with zerovalent iron | Gibb C., Satapanajaru T., Comfort S.D., Shea P.J. | 2004 | Chemosphere, 54(7), pp. 841-848 | 27 |
| 18 | Remediating dinoseb-contaminated soil with zerovalent iron | Satapanajaru T., Onanong S., Comfort S., Snow D., Cassada D., Harris C. | 2009 | Journal of Hazardous Materials, 168(2-3), pp. 930-937 | 23 |
| 19 | Transformation of hexahydro-1,3,5-trinitro-1,3,5-triazine (RDX) by permanganate | Chokejaroenrat C., Comfort S., Harris C., Snow D., Cassada D., Sakulthaew C., Sakulthaew C., Satapanajaru T. | 2011 | Environmental Science and Technology, 45(8), pp. 3643-3649 | 22 |
| 20 | Using low-cost iron byproducts from automotive manufacturing to remediate DDT | Satapanajaru T., Anurakpongsatorn P., Songsasen A., Boparai H., Park J. | 2006 | Water, Air, and Soil Pollution, 175(1-4), pp. 361-374 | 21 |
| 21 | Abiotic transformation of high explosives by freshly precipitated iron minerals in aqueous FeII solutions | Boparai H.K., Comfort S.D., Satapanajaru T., Szecsody J.E., Grossl P.R., Shea P.J., Shea P.J. | 2010 | Chemosphere, 79(8), pp. 865-872 | 20 |
| 22 | Removal and reuse of phosphorus from aquaculture water using activated carbon-based CaO | Vijuksungsith P., Vijuksungsith P., Satapanajaru T., Chokejaroenrat C., Jarusutthirak C., Sakulthaew C., Kambhu A., Yoo-iam M., Boonprasert R. | 2023 | Environmental Technology and Innovation, 29, 102990 | 19 |
| 23 | Remediating oxytetracycline-contaminated aquaculture water using nano calcium peroxide (nCaO | Vijuksungsith P., Vijuksungsith P., Satapanajaru T., Chokejaroenrat C., Jarusutthirak C., Sakulthaew C., Kambhu A., Boonprasert R. | 2021 | Environmental Technology and Innovation, 24, 101861 | 18 |
| 24 | Removal of 17?-Estradiol Using Persulfate Synergistically Activated Using Heat and Ultraviolet Light | Sakulthaew C., Chokejaroenrat C., Satapanajaru T., Chirasatienpon T., Angkaew A. | 2020 | Water, Air, and Soil Pollution, 231(5), 247 | 17 |
| 25 | Developing persulfate-activator soft solid (PASS) as slow release oxidant to remediate phenol-contaminated groundwater | Yoo-iam M., Satapanajaru T., Chokejaroenrat C., Sakulthaew C., Comfort S., Kambhu A. | 2021 | Environmental Technology and Innovation, 22, 101396 | 15 |
| 26 | Decolorization of reactive black 5 and reactive red 198 using nanoscale zerovalent Iron | Chompuchan C., Satapanajaru T., Suntornchot P., Pengthamkeerati P. | 2009 | World Academy of Science, Engineering and Technology, 37, pp. 130-134 | 14 |
| 27 | Field-scale cleanup of atrazine and cyanazine contaminated soil with a combined chemical-biological approach | Waria M., Comfort S., Boparai H., Onanong S., Snow D., Cassada D., Satapanajaru T., Harris C. | 2009 | Journal of Environmental Quality, 38(5), pp. 1803-1811 | 13 |
| 28 | Practical use of response surface methodology for optimization of veterinary antibiotic removal using UV/H | Jutarvutikul K., Sakulthaew C., Chokejaroenrat C., Pattanateeradetch A., Imman S., Suriyachai N., Satapanajaru T., Kreetachat T. | 2021 | Aquacultural Engineering, 94, 102174 | 13 |
| 29 | Analysis and modeling of column operations on reactive dye removal onto alkaline-treated biomass fly ash | Pengthamkeerati P., Satapanajaru T. | 2015 | Desalination and Water Treatment, 54(1), pp. 227-234 | 13 |
| 30 | Decolorization of Reactive Black 5 by persulfate oxidation activated by ferrous ion and its optimization | Satapanajaru T., Yoo-iam M., Bongprom P., Pengthamkeerati P. | 2015 | Desalination and Water Treatment, 56(1), pp. 121-135 | 12 |
| 31 | Remediation of DDT-contaminated water and soil by using pretreated iron byproducts from the automotive industry | Satapanajaru T., Anurakpongsatorn P., Pengthamkeerati P. | 2006 | Journal of Environmental Science and Health - Part B Pesticides, Food Contaminants, and Agricultural Wastes, 41(8), pp. 1291-1303 | 12 |
| 32 | Persulfate activation using leonardite char-supported nano zero-valent iron composites for styrene-contaminated soil and water remediation | Angkaew A., Chokejaroenrat C., Angkaew M., Satapanajaru T., Sakulthaew C. | 2024 | Environmental Research, 240, 117486 | 9 |
| 33 | Performance of bioretention systems by umbrella plant (Cyperus alternifolius L.) and common reed (Phragmites australis) for removal of microplastics | Vijuksungsith P., Satapanajaru T., Muangkaew K., Boonprasert R. | 2024 | Environmental Technology and Innovation, 35, 103734 | 7 |
| 34 | Production of ?-amylase by Aspergillus oryzae from cassava bagasse and wastewater sludge under solid-state fermentation | Pengthamkeerati P., Numsomboon S., Satapanajaru T., Chairattanamanokorn P. | 2012 | Environmental Progress and Sustainable Energy, 31(1), pp. 122-129 | 7 |
| 35 | Enhanced Photo-Fenton Activity Using Magnetic Cu | Angkaew A., Sakulthaew C., Nimtim M., Imman S., Satapanajaru T., Suriyachai N., Kreetachat T., Comfort S., Chokejaroenrat C. | 2022 | Water (Switzerland), 14(22), 3717 | 6 |
| 36 | Green cleanup of styrene-contaminated soil by carbon-based nanoscale zero-valent iron and phytoremediation: Sunn hemp (Crotalaria juncea), zinnia (Zinnia violacea Cav.), and marigold (Tagetes erecta L.) | Kambhu A., Satapanajaru T., Somsamak P., Pengthamkeerati P., Chokejaroenrat C., Muangkaew K., Nonthamit K. | 2024 | Heliyon, 10(6), e27499 | 5 |
| 37 | Agricultural Land Suitability Mapping for Rice Cultivation in Severely Heavy Metal-Contaminated Land: Case Study of Mae Tao in Thailand | Srisawat L., Srisawat L., Satapanajaru T., Anurakpongsatorn P., Jarusutthirak C., Yoo-iam M. | 2021 | Water, Air, and Soil Pollution, 232(11), 460 | 4 |
| 38 | Remediating phenol-contaminated groundwater and aquifer using persulfate oxidation | Yoo-Iam M., Satapanajaru T., Chokejaroenrat C., Sakulthaew C., Comfort S. | 2020 | Desalination and Water Treatment, 208, pp. 159-171 | 4 |
| 39 | Removal of reactive black 5 and its degradation using combined treatment of nano-zerovalent iron activated persulfate and adsorption processes | Satapanajaru T., Chokejaroenrat C., Pengthamkeerati P. | 2018 | Desalination and Water Treatment, 102, pp. 300-311 | 2 |
| 40 | Assessment and Management of Air Pollutant Emissions from Vehicles in the Bangkok Metropolitan Region | Kuson M., Mahujchariyawong J., Satapanajaru T., Prueksasit T. | 2023 | Science and Technology Asia, 28(4), pp. 144-155 | 2 |
| 41 | Advancing Cassava Age Estimation in Precision Agriculture: Strategic Application of the BRAH Algorithm | Boonprong S., Satapanajaru T., Piolueang N. | 2024 | Agriculture (Switzerland), 14(7), 1075 | 0 |
| 42 | Adsorption of Phenol and Zinc as Dual Contaminants in Groundwater on Flood Plain Deposit Aquifer: Kinetic, Thermodynamic, and Column Operation Studies | Yoo-iam M., Kambhu A., Satapanajaru T. | 2023 | Water, Air, and Soil Pollution, 234(4), 261 | 0 |