{"id":835,"date":"2023-02-03T22:26:16","date_gmt":"2023-02-03T15:26:16","guid":{"rendered":"http:\/\/physics.sc.kku.ac.th\/?page_id=835"},"modified":"2023-03-29T10:24:46","modified_gmt":"2023-03-29T03:24:46","slug":"%e0%b8%a3%e0%b8%a8-%e0%b8%94%e0%b8%a3-%e0%b8%9b%e0%b8%a3%e0%b8%b0%e0%b8%aa%e0%b8%b4%e0%b8%97%e0%b8%98%e0%b8%b4%e0%b9%8c-%e0%b8%97%e0%b8%ad%e0%b8%87%e0%b9%83%e0%b8%9a","status":"publish","type":"page","link":"https:\/\/physics.sc.kku.ac.th\/?page_id=835","title":{"rendered":"\u0e28. \u0e14\u0e23.\u0e1b\u0e23\u0e30\u0e2a\u0e34\u0e17\u0e18\u0e34\u0e4c \u0e17\u0e2d\u0e07\u0e43\u0e1a"},"content":{"rendered":"<section class=\"wpb-content-wrapper\"><p>[vc_row][vc_column][vc_column_text animation=&#8221;bounceInDown&#8221;]<\/p>\r\n<div class=\"wp-block-columns is-layout-flex wp-container-core-columns-is-layout-9d6595d7 wp-block-columns-is-layout-flex\">\r\n<div class=\"wp-block-column is-layout-flow wp-block-column-is-layout-flow\" style=\"flex-basis: 25%;\">\r\n<figure class=\"wp-block-image size-large\"><img loading=\"lazy\" decoding=\"async\" width=\"748\" height=\"1024\" class=\"wp-image-239\" src=\"http:\/\/physics.sc.kku.ac.th\/wp-content\/uploads\/2023\/01\/Prasit-748x1024.png\" alt=\"\" srcset=\"https:\/\/physics.sc.kku.ac.th\/wp-content\/uploads\/2023\/01\/Prasit-748x1024.png 748w, https:\/\/physics.sc.kku.ac.th\/wp-content\/uploads\/2023\/01\/Prasit-219x300.png 219w, https:\/\/physics.sc.kku.ac.th\/wp-content\/uploads\/2023\/01\/Prasit-768x1051.png 768w, https:\/\/physics.sc.kku.ac.th\/wp-content\/uploads\/2023\/01\/Prasit-1122x1536.png 1122w, https:\/\/physics.sc.kku.ac.th\/wp-content\/uploads\/2023\/01\/Prasit-1496x2048.png 1496w, https:\/\/physics.sc.kku.ac.th\/wp-content\/uploads\/2023\/01\/Prasit.png 1600w\" sizes=\"auto, (max-width: 748px) 100vw, 748px\" \/><\/figure>\r\n<\/div>\r\n\r\n\r\n\r\n<div class=\"wp-block-column is-layout-flow wp-block-column-is-layout-flow\" style=\"flex-basis: 50%;\">\r\n\r\n\r\n<h2 class=\"wp-block-heading\">\u00a0<\/h2>\r\n<h2>\u0e1b\u0e23\u0e30\u0e27\u0e31\u0e15\u0e34<\/h2>\r\n\r\n\r\n\r\n<ul class=\"wp-block-list\">\r\n<li style=\"list-style-type: none;\">\r\n<ul>\r\n<li><strong>2544 <\/strong>\u0e27\u0e17.\u0e1a.\u00a0(\u0e1f\u0e34\u0e2a\u0e34\u0e01\u0e2a\u0e4c) \u0e21\u0e2b\u0e32\u0e27\u0e34\u0e17\u0e22\u0e32\u0e25\u0e31\u0e22\u0e02\u0e2d\u0e19\u0e41\u0e01\u0e48\u0e19<\/li>\r\n\r\n\r\n\r\n<li><strong>2549 <\/strong>\u0e27\u0e17.\u0e21. (\u0e1f\u0e34\u0e2a\u0e34\u0e01\u0e2a\u0e4c) \u0e21\u0e2b\u0e32\u0e27\u0e34\u0e17\u0e22\u0e32\u0e25\u0e31\u0e22\u0e02\u0e2d\u0e19\u0e41\u0e01\u0e48\u0e19<\/li>\r\n\r\n\r\n\r\n<li><strong>2553 <\/strong>\u0e1b\u0e23.\u0e14. \u00a0(\u0e1f\u0e34\u0e2a\u0e34\u0e01\u0e2a\u0e4c) \u0e21\u0e2b\u0e32\u0e27\u0e34\u0e17\u0e22\u0e32\u0e25\u0e31\u0e22\u0e02\u0e2d\u0e19\u0e41\u0e01\u0e48\u0e19<\/li>\r\n<\/ul>\r\n<\/li>\r\n<\/ul>\r\n\r\n<p><strong>\u0e2b\u0e49\u0e2d\u0e07\u0e17\u0e33\u0e07\u0e32\u0e19<\/strong> \u0e2d\u0e32\u0e04\u0e32\u0e23\u0e27\u0e34\u0e17\u0e22\u0e27\u0e34\u0e20\u0e32\u0e2a \u0e0a\u0e31\u0e49\u0e19 5 \u0e04\u0e13\u0e30\u0e27\u0e34\u0e17\u0e22\u0e32\u0e28\u0e32\u0e2a\u0e15\u0e23\u0e4c \u0e21\u0e2b\u0e32\u0e27\u0e34\u0e17\u0e22\u0e32\u0e25\u0e31\u0e22\u0e02\u0e2d\u0e19\u0e41\u0e01\u0e48\u0e19<\/p>\r\n\r\n<p><strong>E-mail<\/strong>: pthongbai@kku.ac.th<\/p>\r\n\r\n<p><strong>Download CV<\/strong><\/p>\r\n<\/div>\r\n\r\n\r\n\r\n<div class=\"wp-block-column is-layout-flow wp-block-column-is-layout-flow\" style=\"flex-basis: 25%;\">\u00a0<\/div>\r\n<\/div>\r\n\r\n<p>&nbsp;<\/p>\r\n<p>[\/vc_column_text][\/vc_column][\/vc_row][vc_row][vc_column][vc_tta_tabs][vc_tta_section title=&#8221;\u0e07\u0e32\u0e19\u0e27\u0e34\u0e08\u0e31\u0e22\u0e17\u0e35\u0e48\u0e2a\u0e19\u0e43\u0e08&#8221; tab_id=&#8221;1675437994547-44096c98-86c3&#8243;][vc_column_text animation=&#8221;bounceInDown&#8221;]<\/p>\r\n\r\n<ol class=\"wp-block-list\">\r\n<li>Giant\/colossal dielectric oxides<\/li>\r\n<li>Electronic materials; ceramic capacitors and varistor<\/li>\r\n<li>Polymer nanocomposites<\/li>\r\n<li>Fabrication of oxide nanoparticles and metal nanoparticles<\/li>\r\n<\/ol>\r\n<p><!-- \/wp:post-content -->[\/vc_column_text][\/vc_tta_section][vc_tta_section title=&#8221;\u0e1c\u0e25\u0e07\u0e32\u0e19\u0e27\u0e34\u0e08\u0e31\u0e22&#8221; tab_id=&#8221;1675437994558-3f4965f3-c64e&#8221;][vc_column_text animation=&#8221;bounceInDown&#8221;]<\/p>\r\n<p><strong>As a corresponding author<\/strong><\/p>\r\n<ol>\r\n<li>Thongbai P, Putasaeng B, Yamwong T, Maensiri S. Improved dielectric and non-ohmic properties of Ca<sub>2<\/sub>Cu<sub>2<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics prepared by a polymer pyrolysis method. <strong>Journal of Alloys and Compounds<\/strong> 2011; 509: 7416-7420.<\/li>\r\n<li>Thongbai P, Putasaeng B, Yamwong T, Maensiri S. Current\u2013voltage nonlinear and dielectric properties of CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics prepared by a simple thermal decomposition method. <strong>Journal of Materials Science: Materials in Electronics<\/strong> 2012; 23: 795-801.<\/li>\r\n<li>Thongbai P, Yamwong T, Maensiri S. Dielectric properties and electrical response of grain boundary of Na<sub>1\/2<\/sub>La<sub>1\/2<\/sub>Cu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics. <strong>Materials Research Bulletin<\/strong> 2012; 47: 432-437.<\/li>\r\n<li>Somphan W, Sangwong N, Yamwong T, Thongbai P. Giant dielectric and electrical properties of sodium yttrium copper titanate: Na<sub>1\/2<\/sub>Y<sub>1\/2<\/sub>Cu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub>. <strong>Journal of Materials Science: Materials in Electronics<\/strong> 2012; 23: 1229-1234.<\/li>\r\n<li>Jumpatam J, Thongbai P, Kongsook B, Yamwong T, Maensiri S. High permittivity, low dielectric loss, and high electrostatic potential barrier in Ca<sub>2<\/sub>Cu<sub>2<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics. <strong>Materials Letters<\/strong> 2012; 76: 40-42.<\/li>\r\n<li>Thongbai P, Jumpatam J, Yamwong T, Maensiri S. Effects of Ta<sup>5+<\/sup> doping on microstructure evolution, dielectric properties and electrical response in CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics. <strong>Journal of the European Ceramic Society<\/strong> 2012; 32: 2423-2430.<\/li>\r\n<li>Vangchangyia S, Swatsitang E, Thongbai P, Pinitsoontorn S, Yamwong T, Maensiri S, et al. Very Low Loss Tangent and High Dielectric Permittivity in Pure-CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> Ceramics Prepared by a Modified Sol-Gel Process. <strong>Journal of the American Ceramic Society<\/strong> 2012; 95: 1497-1500.<\/li>\r\n<li>Sangwong N, Somphan W, Thongbai P, Yamwong T, Meansiri S. Electrical responses and dielectric relaxations in giant permittivity NaCu<sub>3<\/sub>Ti<sub>3<\/sub>TaO<sub>12<\/sub> ceramics. <strong>Applied Physics A<\/strong> 2012; 108: 385-392.<\/li>\r\n<li>Thongbai P, Yamwong T, Maensiri S. Microstructure and modified giant dielectric response in Ga\u2010doped La<sub>1.5<\/sub>Sr<sub>0.5<\/sub>NiO<sub>4<\/sub> ceramics. <strong>Materials Letters<\/strong> 2012; 82: 244-247.<\/li>\r\n<li>Thongbai P, Putasaeng B, Yamwong T, Maensiri S. Modified giant dielectric properties of samarium doped CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics. <strong>Materials Research Bulletin<\/strong> 2012; 47: 2257-2263.<\/li>\r\n<li>Jumpatam J, Putasaeng B, Yamwong T, Thongbai P, Maensiri S. Enhancement of giant dielectric response in Ga-doped CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics. <strong>Ceramics International<\/strong> 2013; 39: 1057-1064.<\/li>\r\n<li>Thongbai P, Vangchangyia S, Swatsitang E, Amornkitbamrung V, Yamwong T, Maensiri S. Non-Ohmic and dielectric properties of Ba-doped CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics. <strong>Journal of Materials Science: Materials in Electronics<\/strong> 2013; 24: 875-883.<\/li>\r\n<li>Thongbai P, Pinitsoontorn S, Amornkitbamrung V, Yamwong T, Maensiri S, Chindaprasirt P. Reducing Loss Tangent by Controlling Microstructure and Electrical Responses in CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> Ceramics Prepared by a Simple Combustion Method. <strong>International Journal of Applied Ceramic Technology<\/strong> 2013; 10: E77-E87.<\/li>\r\n<li>Thongbai P, Jumpatam J, Putasaeng B, Yamwong T, Maensiri S. The origin of giant dielectric relaxation and electrical responses of grains and grain boundaries of W-doped CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics. <strong>Journal of Applied Physics<\/strong> 2012; 112: 114115.<\/li>\r\n<li>Thongbai P, Boonlakhorn J, Putasaeng B, Yamwong T, Maensiri S. Extremely Enhanced Nonlinear Current\u2013Voltage Properties of Tb-Doped CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> Ceramics. <strong>Journal of the American Ceramic Society<\/strong> 2013; 96: 379-381.<\/li>\r\n<li>Thongbai P, Yamwong T, Maensiri S. Non-Ohmic and dielectric properties of CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub>-MgO nanocomposites. <strong>Microelectronic Engineering<\/strong> 2013; 108: 177-181.<\/li>\r\n<li>Sangwong N, Thongbai P, Yamwong T, Maensiri S, Chindaprasirt P. Dielectric Responses and Electrical Properties of CaCu<sub>3<\/sub>Ti<sub>4-x<\/sub>V<sub>x<\/sub>O<sub>12<\/sub> Ceramics Prepared by a Simple Poly(ethylene glycol) Sol\u2013Gel Route. <strong>Japanese Journal of Applied Physics<\/strong> 2013; 52: 06GF05.<\/li>\r\n<li>Thongbai P, Jumpatam J, Yamwong T, Maensiri S. Effects of Ga Substitution for Cu on Microstructure and Giant Dielectric Response of CaGa<sub>x<\/sub>Cu<sub>3\u2212x<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> (x = 0, 0.01, and 0.05) Ceramics. <strong>Ferroelectrics<\/strong> 2013; 452: 91-100.<\/li>\r\n<li>Vangchangyia S, Yamwong T, Swatsitang E, Thongbai P, Maensiri S. Selectivity of doping ions to effectively improve dielectric and non-ohmic properties of CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics. <strong>Ceramics International<\/strong> 2013; 39: 8133-8139.<\/li>\r\n<li>Thongbai P, Meeporn K, Yamwong T, Maensiri S. Extreme effects of Na doping on microstructure, giant dielectric response and dielectric relaxation behavior in CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics. <strong>Materials Letters<\/strong> 2013; 106: 129-132.<\/li>\r\n<li>Sangwong N, Yamwong T, Thongbai P. Synthesis, characterization and giant dielectric properties of CaCu3Ti4O12 ceramics prepared by a polyvinyl pyrrolidone-dimethylformamide solution route. <strong>Journal of Electroceramics<\/strong> 2013.<\/li>\r\n<li>Somphan W, Thongbai P, Yamwong T, Maensiri S. High Schottky barrier at grain boundaries observed in Na<sub>1\/2<\/sub>Sm<sub>1\/2<\/sub>Cu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics. <strong>Materials Research Bulletin<\/strong> 2013; 48: 4087-4092.<\/li>\r\n<li>Thongbai P, Putasaeng B, Yamwong T, Amornkitbamrung V, Maensiri S. Liquid phase sintering behavior and improvement of giant dielectric properties by modifying microstructure and electrical response at grain boundaries of CaCu<sub>3<\/sub>Ti<sub>4\u2212x<\/sub>Mo<sub>x<\/sub>O<sub>12<\/sub> ceramics. <strong>Journal of Alloys and Compounds<\/strong> 2014; 582: 747-753.<\/li>\r\n<li>Tuichai W, Somjid S, Putasaeng B, Yamwong T, Chompoosor A, Thongbai P, et al. Dramatically enhanced non-Ohmic properties and maximum stored energy density in ceramic-metal nanocomposites: CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub>\/Au nanoparticles. <strong>Nanoscale Research Letters<\/strong> 2013; 8: 1-6.<\/li>\r\n<li>Thongbai P, Yamwong T, Maensiri S, Amornkitbamrung V, Chindaprasirt P. Improved Dielectric and Nonlinear Electrical Properties of Fine-Grained CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12 <\/sub>Ceramics Prepared by a Glycine-Nitrate Process. <strong>Journal of the American Ceramic Society<\/strong> 2014; 97: 1785\u20131790.<\/li>\r\n<li>Meeporn K, Yamwong T, Thongbai P. La<sub>1.7<\/sub>Sr<sub>0.3<\/sub>NiO<sub>4 <\/sub>nanocrystalline powders prepared by a combustion method using urea as fuel: Preparation, characterization, and their bulk colossal dielectric constants. <strong>Japanese Journal of Applied Physics<\/strong> 2014; 53: 06JF01.<\/li>\r\n<li>Jumpatam J, Putasaeng B, Yamwong T, Thongbai P, Maensiri S. A novel strategy to enhance dielectric performance and non-Ohmic properties in Ca<sub>2<\/sub>Cu<sub>2\u2212x<\/sub>Mg<sub>x<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub>. <strong>Journal of the European Ceramic Society<\/strong> 2014; 34: 2941-2950.<\/li>\r\n<li>Jumpatam J, Putasaeng B, Yamwong T, Thongbai P, Maensiri S. A Novel Route to Greatly Enhanced Dielectric Permittivity with Reduce Loss Tangent in CaCu<sub>3\u2212x<\/sub>Zn<sub>x<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub>\/CaTiO<sub>3 <\/sub>Composites. <strong>Journal of the American Ceramic Society<\/strong> 2014; 97: 2368-2371.<\/li>\r\n<li>Boonlakhorn J, Thongbai P, Putasaeng B, Yamwong T, Maensiri S. Very high-performance dielectric properties of Ca<sub>1\u22123x\/2<\/sub>Yb<sub>x<\/sub>Cu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics. <strong>Journal of Alloys and Compounds<\/strong> 2014; 612: 103-109.<\/li>\r\n<li>Tuichai W, Thongbai P, Amornkitbamrung V, Yamwong T, Maensiri S. Na<sub>0.5<\/sub>Bi<sub>0.5<\/sub>Cu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> nanocrystalline powders prepared by a glycine\u2013nitrate process: Preparation, characterization, and their dielectric properties. <strong>Microelectronic Engineering<\/strong> 2014; 126: 118-123.<\/li>\r\n<li>Meeporn K, Yamwong T, Pinitsoontorn S, Amornkitbamrung V, Thongbai P. Grain size independence of giant dielectric permittivity of CaCu<sub>3<\/sub>Ti<sub>4\u2212x<\/sub>Sc<sub>x<\/sub>O<sub>12<\/sub> ceramics. <strong>Ceramics International<\/strong> 2014; 40: 15897-15906.<\/li>\r\n<li>Thongbai P, Jumpatam J, Putasaeng B, Yamwong T, Amornkitbamrung V, Maensiri S. Effects of La3+ doping ions on dielectric properties and formation of Schottky barriers at internal interfaces in a Ca2Cu2Ti4O12 composite system. <strong>Journal of Materials Science: Materials in Electronics<\/strong> 2014; 25: 4657-4663.<\/li>\r\n<li>Thongbai P, Jumpatam J, Putasaeng B, Yamwong T, Maensiri S. Microstructural evolution and Maxwell\u2013Wagner relaxation in Ca<sub>2<\/sub>Cu<sub>2<\/sub>Ti<sub>4\u2212x<\/sub>Zr<sub>x<\/sub>O<sub>12<\/sub>: The important clue to achieve the origin of the giant dielectric behavior. <strong>Materials Research Bulletin<\/strong> 2014; 60: 695-703.<\/li>\r\n<li>Kum-onsa P, Thongbai P, Putasaeng B, Yamwong T, Maensiri S. Na<sub>1\/3<\/sub>Ca<sub>1\/3<\/sub>Bi<sub>1\/3<\/sub>Cu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub>: A new giant dielectric perovskite ceramic in ACu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> compounds. <strong>Journal of the European Ceramic Society<\/strong> 2015; 35: 1441-1447.<\/li>\r\n<li>Jumpatam J, Thongbai P, Yamwong T, Maensiri S. Effects of Bi<sup>3+<\/sup> doping on microstructure and dielectric properties of CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub>\/CaTiO<sub>3<\/sub> composite ceramics. <strong>Ceramics International<\/strong> 2015; 41, Supplement 1: S498-S503.<\/li>\r\n<li>Boonlakhorn J, Kidkhunthod P, Putasaeng B, Yamwong T, Thongbai P, Maensiri S. Effects of Y doping ions on microstructure, dielectric response, and electrical properties of Ca1\u22123x\/2Y x Cu3Ti4O12 ceramics. <strong>Journal of Materials Science: Materials in Electronics<\/strong> 2015; 26: 2329-2337.<\/li>\r\n<li>Silakaew K, Saijingwong W, Meeporn K, Maensiri S, Thongbai P. Effects of processing methods on dielectric properties of BaTiO<sub>3<\/sub>\/poly(vinylidene fluoride) nanocomposites. <strong>Microelectronic Engineering<\/strong> 2015; 146: 1-5.<\/li>\r\n<li>Boonlakhorn J, Thongbai P. Mg-doped CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> nanocrystalline powders prepared by a modified sol\u2013gel method: Preparation, characterization, and their giant dielectric response. <strong>Japanese Journal of Applied Physics<\/strong> 2015; 54: 06FJ06.<\/li>\r\n<li>Tuichai W, Srepusharawoot P, Swatsitang E, Danwittayakul S, Thongbai P. Giant dielectric permittivity and electronic structure in (Al + Sb) co-doped TiO<sub>2<\/sub> ceramics. <strong>Microelectronic Engineering<\/strong> 2015; 146: 32-37.<\/li>\r\n<li>Boonlakhorn J, Kidkhunthod P, Putasaeng B, Yamwong T, Thongbai P, Maensiri S. Giant dielectric behavior and electrical properties of Ca1\u22123x\/2Lu x Cu3Ti4O12 ceramics. <strong>Applied Physics A<\/strong> 2015; 120: 89-95.<\/li>\r\n<li>Boonlakhorn J, Thongbai P. Effect of Annealing in O<sub>2<\/sub> and Mechanisms Contributing to the Overall Loss Tangent of CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> Ceramics. <strong>Journal of Electronic Materials<\/strong> 2015; 44: 3687-3695.<\/li>\r\n<li>Boonlakhorn J, Kidkhunthod P, Thongbai P. A novel approach to achieve high dielectric permittivity and low loss tangent in CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics by co-doping with Sm<sup>3+<\/sup> and Mg<sup>2+<\/sup> ions. <strong>Journal of the European Ceramic Society<\/strong> 2015; 35: 3521-3528.<\/li>\r\n<li>Tuichai W, Danwittayakul S, Yamwong T, Thongbai P. Synthesis, dielectric properties, and influences oxygen vacancies have on electrical properties of Na<sub>1\/2<\/sub>Bi<sub>1\/2<\/sub>Cu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics prepared by a urea combustion method. <strong>Journal of Sol-Gel Science and Technology<\/strong> 2015; 76: 630-636.<\/li>\r\n<li>Boonlakhorn J, Putasaeng B, Kidkhunthod P, Thongbai P. Improved dielectric properties of (Y + Mg) co-doped CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics by controlling geometric and intrinsic properties of grain boundaries. <strong>Materials &amp; Design<\/strong> 2016; 92: 494-498.<\/li>\r\n<li>Tuichai W, Danwittayakul S, Maensiri S, Thongbai P. Investigation on temperature stability performance of giant permittivity (In + Nb) in co-doped TiO<sub>2<\/sub> ceramic: a crucial aspect for practical electronic applications. <strong>RSC Advances<\/strong> 2016; 6: 5582-5589.<\/li>\r\n<li>Jumpatam J, Putasaeng B, Yamwong T, Thongbai P, Maensiri S. Microstructural evolution and strongly enhanced dielectric response in Sn-doped CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub>\/CaTiO<sub>3<\/sub> ceramic composites. <strong>Materials Research Bulletin<\/strong> 2016; 77: 178-184.<\/li>\r\n<li>Meeporn K, Maensiri S, Thongbai P. Abnormally enhanced dielectric permittivity in poly(vinylidene fluoride)\/nanosized-La<sub>2<\/sub>NiO<sub>4\u2212<\/sub><sub>\u03b4<\/sub> films. <strong>Applied Surface Science<\/strong> 2016; 380: 67-72.<\/li>\r\n<li>Boonlakhorn J, Kidkhunthod P, Thongbai P, Maensiri S. Colossal dielectric permittivity and electrical properties of the grain boundary of Ca<sub>1\u22123<em>x<\/em>\/2<\/sub>Yb<em><sub>x<\/sub><\/em>Cu<sub>3\u2212<em>y<\/em><\/sub>Mg<em><sub>y<\/sub><\/em>Ti<sub>4<\/sub>O<sub>12<\/sub> (<em>x<\/em>=0.05, <em>y<\/em>=0.05 and 0.30). <strong>Ceramics International<\/strong> 2016; 42: 8467-8472.<\/li>\r\n<li>Kum-onsa P, Thongbai P, Maensiri S, Chindaprasirt P. Greatly enhanced dielectric permittivity in poly(vinylidene fluoride)-based polymeric composites induced by Na<sub>1\/3<\/sub>Ca<sub>1\/3<\/sub>Bi<sub>1\/3<\/sub>Cu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> nanoparticles. <strong>Journal of Materials Science: Materials in Electronics<\/strong> 2016; 27: 9650-9655.<\/li>\r\n<li>Jumpatam J, Thongbai P. Enhanced dielectric and non-ohmic properties in CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub>\/CaTiO<sub>3<\/sub> nanocomposites prepared by a chemical combustion method. <strong>Journal of Materials Science: Materials in Electronics<\/strong> 2016; 27: 12085-12090.<\/li>\r\n<li>Jumpatam J, Mooltang A, Putasaeng B, Kidkhunthod P, Chanlek N, Thongbai P, et al. Effects of Mg<sup>2+<\/sup> doping ions on giant dielectric properties and electrical responses of Na<sub>1\/2<\/sub>Y<sub>1\/2<\/sub>Cu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12 <\/sub>ceramics. <strong>Ceramics International<\/strong> 2016; 42: 16287-16295.<\/li>\r\n<li>Jumpatam J, Somphan W, Boonlakhorn J, Putasaeng B, Kidkhunthod P, Thongbai P, et al. Non-Ohmic Properties and Electrical Responses of Grains and Grain Boundaries of Na<sub>1\/2<\/sub>Y<sub>1\/2<\/sub>Cu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> Ceramics. <strong>Journal of the American Ceramic Society<\/strong> 2017; 100: 157-166.<\/li>\r\n<li>Nachaithong T, Thongbai P, Maensiri S. Colossal permittivity in (In<sub>1\/2<\/sub>Nb<sub>1\/2<\/sub>)<sub>x<\/sub>Ti<sub>1\u2212x<\/sub>O<sub>2<\/sub> ceramics prepared by a glycine nitrate process. <strong>Journal of the European Ceramic Society<\/strong> 2017; 37: 655-660.<\/li>\r\n<li>Meeporn K, Chanlek N, Thongbai P. Effects of DC bias on non-ohmic sample-electrode contact and grain boundary responses in giant-permittivity La<sub>1.7<\/sub>Sr<sub>0.3<\/sub>Ni<sub>1-x<\/sub>Mg<sub>x<\/sub>O<sub>4<\/sub> ceramics. <strong>RSC Advances<\/strong> 2016; 6: 91377-91385.<\/li>\r\n<li>Boonlakhorn J, Kidkhunthod P, Putasaeng B, Thongbai P. Significantly improved non-Ohmic and giant dielectric properties of CaCu<sub>3-x<\/sub>Zn<sub>x<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics by enhancing grain boundary response. <strong>Ceramics International<\/strong> 2017; 43: 2705-2711.<\/li>\r\n<li>Nachaithong T, Kidkhunthod P, Thongbai P, Maensiri S. Surface barrier layer effect in (In\u00a0+Nb) co-doped TiO<sub>2<\/sub> ceramics: An alternative route to design low dielectric loss. <strong>Journal of the American Ceramic Society<\/strong> 2017; 100: 1452-1459.<\/li>\r\n<li>Tuichai W, Danwittayakul S, Chanlek N, Srepusharawoot P, Thongbai P, Maensiri S. Origin(s) of the apparent colossal permittivity in (In<sub>1\/2<\/sub>Nb<sub>1\/2<\/sub>)<sub>x<\/sub>Ti<sub>1-x<\/sub>O<sub>2<\/sub>: clarification on the strongly induced Maxwell-Wagner polarization relaxation by DC bias. <strong>RSC Advances<\/strong> 2017; 7: 95-105.<\/li>\r\n<li>Boonlakhorn J, Kidkhunthod P, Chanlek N, Thongbai P. Effects of DC bias on dielectric and electrical responses in (Y\u00a0+Zn) co-doped CaCu3Ti4O12 perovskite oxides. <strong>Journal of Materials Science: Materials in Electronics<\/strong> 2017; 28: 4695-4701.<\/li>\r\n<li>Jumpatam J, Putasaeng B, Chanlek N, Kidkhunthod P, Thongbai P, Maensiri S, et al. Improved giant dielectric properties of CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> via simultaneously tuning the electrical properties of grains and grain boundaries by F<sup>\u2212<\/sup> substitution. <strong>RSC Advances<\/strong> 2017; 7: 4092-4101.<\/li>\r\n<li>Tuichai W, Danwittayakul S, Chanlek N, Thongbai P, Maensiri S. High-performance giant-dielectric properties of rutile TiO<sub>2<\/sub> co-doped with acceptor-Sc<sup>3+<\/sup> and donor-Nb<sup>5+<\/sup> ions. <strong>Journal of Alloys and Compounds<\/strong> 2017; 703: 139-147.<\/li>\r\n<li>Jumpatam J, Somphan W, Putasaeng B, Chanlek N, Kidkhunthod P, Thongbai P, et al. Nonlinear electrical properties and giant dielectric response in Na<sub>1\/3<\/sub>Ca<sub>1\/3<\/sub>Y<sub>1\/3<\/sub>Cu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramic. <strong>Materials Research Bulletin<\/strong> 2017; 90: 8-14.<\/li>\r\n<li>Boonlakhorn J, Thongbai P, Putasaeng B, Kidkhunthod P, Maensiri S, Chindaprasirt P. Microstructural evolution, non-Ohmic properties, and giant dielectric response in CaCu<sub>3<\/sub>Ti<sub>4\u2212x<\/sub>Ge<sub>x<\/sub>O<sub>12<\/sub> ceramics. <strong>Journal of the American Ceramic Society<\/strong> 2017; 100: 3478-3487.<\/li>\r\n<li>Tuichai W, Thongyong N, Danwittayakul S, Chanlek N, Srepusharawoot P, Thongbai P, et al. Very low dielectric loss and giant dielectric response with excellent temperature stability of Ga<sup>3+<\/sup> and Ta<sup>5+<\/sup> co-doped rutile-TiO<sub>2<\/sub> ceramics. <strong>Materials &amp; Design<\/strong> 2017; 123: 15-23.<\/li>\r\n<li>Meeporn K, Thongbai P, Yamwong T, Maensiri S. Greatly enhanced dielectric permittivity in La<sub>1.7<\/sub>Sr<sub>0.3<\/sub>NiO<sub>4<\/sub>\/poly(vinylidene fluoride) nanocomposites that retained a low loss tangent. <strong>RSC Advances<\/strong> 2017; 7: 17128-17136.<\/li>\r\n<li>Nachaithong T, Thongbai P. Preparation, characterization, electrical properties and giant dielectric response in (In\u2009+\u2009Nb) co-doped TiO<sub>2<\/sub> ceramics synthesized by a urea chemical-combustion method. <strong>Journal of Materials Science: Materials in Electronics<\/strong> 2017; 28: 10914-10920.<\/li>\r\n<li>Meeporn K, Thongbai P, Maensiri S, Chindaprasirt P. Improved dielectric properties of PVDF composites by employing Mg-doped La<sub>1.9<\/sub>Sr<sub>0.1<\/sub>NiO<sub>4<\/sub> particles as a filler. <strong>Journal of Materials Science: Materials in Electronics<\/strong> 2017; 28: 11762-11768.<\/li>\r\n<li>Nachaithong T, Tuichai W, Kidkhunthod P, Chanlek N, Thongbai P, Maensiri S. Preparation, characterization, and giant dielectric permittivity of (Y<sup>3+<\/sup> and Nb<sup>5+<\/sup>) co\u2013doped TiO<sub>2<\/sub> ceramics. <strong>Journal of the European Ceramic Society<\/strong> 2017; 37: 3521-3526.<\/li>\r\n<li>Tuichai W, Danwittayakul S, Srepusharawoot P, Thongbai P, Maensiri S. Giant dielectric permittivity and electronic structure in (A<sup>3+<\/sup>, Nb<sup>5+<\/sup>) co-doped TiO<sub>2<\/sub> (A = Al, Ga and In). <strong>Ceramics International<\/strong> 2017; 43: S265-S269.<\/li>\r\n<li>Jumpatam J, Moontang A, Putasaeng B, Kidkhunthod P, Chanlek N, Thongbai P. Preparation, characterization, and dielectric properties of CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub>-related (Na<sub>1\/3<\/sub>Ca<sub>1\/3<\/sub>Y<sub>1\/3<\/sub>)Cu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics using a simple sol\u2013gel method. <strong>Journal of Materials Science: Materials in Electronics<\/strong> 2017; 28: 14839-14847.<\/li>\r\n<li>Boonlakhorn J, Thongbai P. Enhanced non\u2212Ohmic properties and giant dielectric response of (Sm+Zn) co\u2212doped CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics. <strong>Ceramics International<\/strong> 2017; 43: 12736-12741.<\/li>\r\n<li>Tuichai W, Danwittayakul S, Chanlek N, Thongbai P. Effects of sintering temperature on microstructure and giant dielectric properties of (V\u00a0+Ta) co\u2013doped TiO<sub>2<\/sub> ceramics. <strong>Journal of Alloys and Compounds<\/strong> 2017; 725: 310-317.<\/li>\r\n<li>Thongyong N, Tuichai W, Chanlek N, Thongbai P. Effect of Zn<sup>2+<\/sup> and Nb<sup>5+<\/sup> co-doping ions on giant dielectric properties of rutile-TiO<sub>2<\/sub> ceramics. <strong>Ceramics International<\/strong> 2017; 43: 15466-15471.<\/li>\r\n<li>Boonlakhorn J, Kidkhunthod P, Chanlek N, Thongbai P. (Al<sup>3+<\/sup>, Nb<sup>5+<\/sup>) co\u2013doped CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub>: An extended approach for acceptor\u2013donor heteroatomic substitutions to achieve high\u2013performance giant\u2013dielectric permittivity. <strong>Journal of the European Ceramic Society<\/strong> 2018; 38: 137-143.<\/li>\r\n<li>Siriya P, Tuichai W, Danwittayakul S, Chanlek N, Thongbai P. Surface layer characterizations and sintering time effect on electrical and giant dielectric properties of (In0.05Nb0.05)Ti0.9O2 ceramics. <strong>Ceramics International<\/strong> 2018; 44: 7234-7239.<\/li>\r\n<li>Tuichai W, Danwittayakul S, Thongbai P. Significantly enhanced dielectric permittivity and suppressed dielectric loss in Na<sub>1\/2<\/sub>Bi<sub>1\/2<\/sub>Cu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub>\/poly(vinylidene fluoride) nanocomposites. <strong>Ceramics International<\/strong> 2018; 44: S133-S136.<\/li>\r\n<li>Boonlakhorn J, Putasaeng B, Thongbai P. Origin of significantly enhanced dielectric response and nonlinear electrical behavior in Ni<sup>2+<\/sup>-doped CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub>: Influence of DC bias on electrical properties of grain boundary and associated giant dielectric properties. <strong>Ceramics International<\/strong> 2019; 45: 6944-6949.<\/li>\r\n<li>Jumpatam J, Chanlek N, Thongbai P. Giant dielectric response, electrical properties and nonlinear current-voltage characteristic of Al<sub>2<\/sub>O<sub>3<\/sub>-CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> nanocomposites. <strong>Applied Surface Science<\/strong> 2019; 476: 623-631.<\/li>\r\n<li>Meeporn K, Thongbai P. Improved dielectric properties of poly(vinylidene fluoride) polymer nanocomposites filled with Ag nanoparticles and nickelate ceramic particles. <strong>Applied Surface Science<\/strong> 2019; 481: 1160-1166.<\/li>\r\n<li>Tuichai W, Danwittayakul S, Chanlek N, Thongbai P. Nonlinear current-voltage and giant dielectric properties of Al<sup>3+<\/sup> and Ta<sup>5+<\/sup> co-doped TiO<sub>2<\/sub> ceramics. <strong>Materials Research Bulletin<\/strong> 2019; 116: 137-142.<\/li>\r\n<li>Silakaew K, Thongbai P. Suppressed loss tangent and conductivity in high-permittivity Ag-BaTiO<sub>3<\/sub>\/PVDF nanocomposites by blocking with BaTiO3 nanoparticles. <strong>Applied Surface Science<\/strong> 2019; 492: 683-689.<\/li>\r\n<li>Silakaew K, Thongbai P. Significantly improved dielectric properties of multiwall carbon nanotube-BaTiO<sub>3<\/sub>\/PVDF polymer composites by tuning the particle size of the ceramic filler. <strong>RSC Advances<\/strong> 2019; 9: 23498-23507.<\/li>\r\n<li>Boonlakhorn J, Thongbai P. Substantially enhanced varistor properties and dielectric response in (Zn<sup>2+<\/sup>, Sn<sup>4+<\/sup>) co-doped CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics. <strong>Ceramics International<\/strong> 2019; 45: 22596-22602.<\/li>\r\n<li>Boonlakhorn J, Kidkhunthod P, Thongbai P. Significantly improved giant dielectric response in giant dielectric response in CaCu<sub>2.95<\/sub>Ni<sub>0.05<\/sub>Ti<sub>4-x<\/sub>Ge<sub>x<\/sub>O<sub>12<\/sub> (x\u202f=\u202f0.05, 0.10) ceramics. <strong>Materials Today Communications<\/strong> 2019; 21: 100633.<\/li>\r\n<li>Boonlakhorn J, Thongbai P. Dielectric properties, nonlinear electrical response and microstructural evolution of CaCu<sub>3<\/sub>Ti<sub>4-x<\/sub>Sn<sub>x<\/sub>O<sub>12<\/sub> ceramics prepared by a double ball-milling process. <strong>Ceramics International<\/strong> 2020; 46: 4952-4958.<\/li>\r\n<li>Boonlakhorn J, Chanlek N, Thongbai P. Giant dielectric permittivity of CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> via a green solution-egg white method. <strong>Journal of Sol-Gel Science and Technology<\/strong> 2020; 93: 643-649.<\/li>\r\n<li>Jumpatam J, Chanlek N, Takesada M, Thongbai P. Giant dielectric behavior of monovalent cation\/anion (Li<sup>+<\/sup>, F<sup>\u2212<\/sup>) co-doped CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics. <strong>Journal of the American Ceramic Society<\/strong> 2020; 103: 1871-1880.<\/li>\r\n<li>Otatawong S, Boonlakhorn J, Danwittayakul S, Thongbai P. CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub>\/In<sub>0.05<\/sub>Nb<sub>0.05<\/sub>Ti<sub>0.90<\/sub>O<sub>12<\/sub> composite ceramics: An effectively improved method to reduce the dielectric loss tangent and retain high dielectric permittivity. <strong>Materials Research Bulletin<\/strong> 2020; 122: 110700.<\/li>\r\n<li>Boonlakhorn J, Srepusharawoot P, Thongbai P. Distinct roles between complex defect clusters and insulating grain boundary on dielectric loss behaviors of (In<sup>3+<\/sup>\/Ta<sup>5+<\/sup>) co-doped CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics. <strong>Results in Physics<\/strong> 2020; 16: 102886.<\/li>\r\n<li>Saengvong P, Boonlakhorn J, Chanlek N, Putasaeng B, Thongbai P. Giant dielectric permittivity with low loss tangent and excellent non\u2212Ohmic properties of the (Na<sup>+<\/sup>, Sr<sup>2+<\/sup>, Y<sup>3+<\/sup>)Cu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramic system. <strong>Ceramics International<\/strong> 2020; 46: 9780-9785.<\/li>\r\n<li>Meeporn K, Thongbai P. Flexible La<sub>1.5<\/sub>Sr<sub>0.5<\/sub>NiO<sub>4<\/sub>\/Poly(vinylidene fluoride) composites with an ultra high dielectric constant: A comparative study. <strong>Composites Part B: Engineering<\/strong> 2020; 184: 107738.<\/li>\r\n<li>Meeporn K, Chanlek N, Thongbai P. Significant enhancement of dielectric permittivity and percolation behaviour of La<sub>2\u2212x<\/sub>Sr<sub>x<\/sub>NiO<sub>4<\/sub>\/poly(vinylidene fluoride) composites with different Sr doping concentrations. <strong>RSC Advances<\/strong> 2020; 10: 2747-2756.<\/li>\r\n<li>Boonlakhorn J, Kidkhunthod P, Thongbai P. Investigation of the dielectric properties and nonlinear electrical response of CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics prepared by a chemical combustion method. <strong>Journal of Materials Science: Materials in Electronics<\/strong> 2020; 31: 4511-4519.<\/li>\r\n<li>Kum-onsa P, Chanlek N, Putasaeng B, Thongbai P. Improvement in dielectric properties of poly(vinylidene fluoride) by incorporation of Au\u2013BiFeO<sub>3<\/sub> hybrid nanoparticles. <strong>Ceramics International<\/strong> 2020; 46: 17272-17279.<\/li>\r\n<li>Phromviyo N, Sirikamalat S, Chanlek N, Thongbai P, Amornkitbamrung V, Chindaprasirt P. Significantly improved non-ohmic and giant dielectric response in CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics by incorporating Portland cement. <strong>Materials Research Express<\/strong> 2020; 7: 066301.<\/li>\r\n<li>Boonlakhorn J, Chanlek N, Srepusharawoot P, Thongbai P. Improved dielectric properties of CaCu<sub>3\u2212x<\/sub>Sn<sub>x<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics with high permittivity and reduced loss tangent. <strong>Journal of Materials Science: Materials in Electronics<\/strong> 2020; 31: 15599-15607.<\/li>\r\n<li>Kum-onsa P, Phromviyo N, Thongbai P. Na<sub>1\/3<\/sub>Ca<sub>1\/3<\/sub>Bi<sub>1\/3<\/sub>Cu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub>\u2013Ni@NiO\/poly(vinylidene fluoride): Three\u2013phase polymer composites with high dielectric permittivity and low loss tangent. <strong>Results in Physics<\/strong> 2020; 18: 103312.<\/li>\r\n<li>Kum\u2212onsa P, Thongbai P. Na<sub>1\/3<\/sub>Ca<sub>1\/3<\/sub>Bi<sub>1\/3<\/sub>Cu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub>\/poly(vinylidene fluoride) composites with high dielectric permittivity and low dielectric loss. <strong>Materials Chemistry and Physics<\/strong> 2020; 256: 123664.<\/li>\r\n<li>Jumpatam J, Putasaeng B, Chanlek N, Boonlakhorn J, Thongbai P, Phromviyo N, et al. Significantly improving the giant dielectric properties of CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics by co-doping with Sr<sup>2+<\/sup> and F<sup>&#8211;<\/sup> ions. <strong>Materials Research Bulletin<\/strong> 2021; 133: 111043.<\/li>\r\n<li>Kum-onsa P, Thongbai P. Improved Dielectric Properties of Poly(vinylidene fluoride) Composites Incorporating Na<sub>1\/2<\/sub>Y<sub>1\/2<\/sub>Cu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> Particles. <strong>Materials Today Communications<\/strong> 2020; 25: 101654.<\/li>\r\n<li>Boonlakhorn J, Chanlek N, Srepusharawoot P, Thongbai P. Controlling microstructure and significantly increased dielectric permittivity with largely reduced dielectric loss in CaCu<sub>3\u2212x<\/sub>Ge<sub>x<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics. <strong>Applied Physics A<\/strong> 2020; 126: 897.<\/li>\r\n<li>Kum-onsa P, Phromviyo N, Thongbai P. Suppressing loss tangent with significantly enhanced dielectric permittivity of poly(vinylidene fluoride) by filling with Au\u2013Na<sub>1\/2<\/sub>Y<sub>1\/2<\/sub>Cu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> hybrid particles. <strong>RSC Advances<\/strong> 2020; 10: 40442-40449.<\/li>\r\n<li>Tuichai W, Danwittayakul S, Chanlek N, Takesada M, Pengpad A, Srepusharawoot P, et al. High-Performance Giant Dielectric Properties of Cr<sup>3+<\/sup>\/Ta<sup>5+<\/sup> Co-Doped TiO<sub>2<\/sub> Ceramics. <strong>ACS Omega<\/strong> 2021; 6: 1901-1910.<\/li>\r\n<li>Boonlakhorn J, Chanlek N, Manyam J, Krongsuk S, Srepusharawoot P, Thongbai P. Ge<sup>4+<\/sup> doped CaCu<sub>2.95<\/sub>Zn<sub>0.05<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics: Two-step reduction of loss tangent. <strong>Ceramics International<\/strong> 2021; 47: 17099-17108.<\/li>\r\n<li>Jumpatam J, Putasaeng B, Chanlek N, Thongbai P. Influences of Sr<sup>2+<\/sup> Doping on Microstructure, Giant Dielectric Behavior, and Non-Ohmic Properties of CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub>\/CaTiO<sub>3<\/sub> Ceramic Composites. <strong>Molecules<\/strong> 2021; 26: 1994.<\/li>\r\n<li>Boonlakhorn J, Putasaeng B, Kidkhunthod P, Manyam J, Krongsuk S, Srepusharawoot P, et al. First-principles calculations and experimental study of enhanced nonlinear and dielectric properties of Sn<sup>4+<\/sup>-doped CaCu<sub>2.95<\/sub>Mg<sub>0.05<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics. <strong>Journal of the European Ceramic Society<\/strong> 2021; 41: 5176-5183.<\/li>\r\n<li>Kum\u2212onsa P, Thongbai P. Dielectric properties of poly(vinylidene fluoride)-based nanocomposites containing a LaFeO<sub>3<\/sub> nanoparticle filler. <strong>Journal of Materials Science: Materials in Electronics<\/strong> 2021; 32: 13985-13993.<\/li>\r\n<li>Boonlakhorn J, Chanlek N, Manyam J, Srepusharawoot P, Thongbai P. Simultaneous two-step enhanced permittivity and reduced loss tangent in Mg\/Ge-Doped CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics. <strong>Journal of Alloys and Compounds<\/strong> 2021; 877: 160322.<\/li>\r\n<li>Boonlakhorn J, Chanlek N, Manyam J, Srepusharawoot P, Krongsuk S, Thongbai P. Enhanced giant dielectric properties and improved nonlinear electrical response in acceptor-donor (Al<sup>3+<\/sup>, Ta<sup>5+<\/sup>)-substituted CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics. <strong>Journal of Advanced Ceramics<\/strong> 2021; 10: 1243\u20131255.<\/li>\r\n<li>Nachaithong T, Chanlek N, Moontragoon P, Thongbai P. The Primary Origin of Excellent Dielectric Properties of (Co, Nb) Co-Doped TiO<sub>2<\/sub> Ceramics: Electron-Pinned Defect Dipoles vs. Internal Barrier Layer Capacitor Effect. <strong>Molecules<\/strong> 2021; 26: 3230.<\/li>\r\n<li>Tuichai W, Kum-onsa P, Danwittayakul S, Manyam J, Harnchana V, Thongbai P, et al. Significantly Enhanced Dielectric Properties of Ag-Deposited (In<sub>1\/2<\/sub>Nb<sub>1\/2<\/sub>)<sub>0.1<\/sub>Ti<sub>0.9<\/sub>O<sub>2<\/sub>\/PVDF Polymer Composites. <strong>Polymers<\/strong> 2021; 13: 1788.<\/li>\r\n<li>Boonlakhorn J, Manyam J, Srepusharawoot P, Krongsuk S, Thongbai P. Effects of Charge Compensation on Colossal Permittivity and Electrical Properties of Grain Boundary of CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> Ceramics Substituted by Al<sup>3+<\/sup> and Ta<sup>5+<\/sup>\/Nb<sup>5+<\/sup>. <strong>Molecules<\/strong> 2021; 26: 3294.<\/li>\r\n<li>Silakaew K, Chanlek N, Manyam J, Thongbai P. Highly enhanced frequency- and temperature-stability permittivity of three-phase poly(vinylidene-fluoride) nanocomposites with retaining low loss tangent and high permittivity. <strong>Results in Physics<\/strong> 2021: 104410.<\/li>\r\n<li>Kum-onsa P, Chanlek N, Manyam J, Thongbai P, Harnchana V, Phromviyo N, et al. Gold-Nanoparticle-Deposited TiO<sub>2<\/sub> Nanorod\/Poly(Vinylidene Fluoride) Composites with Enhanced Dielectric Performance. <strong>Polymers<\/strong> 2021; 13: 2064.<\/li>\r\n<li>Jumpatam J, Putasaeng B, Chanlek N, Manyam J, Srepusharawoot P, Krongsuk S, et al. Influence of Sn and F dopants on giant dielectric response and Schottky potential barrier at grain boundaries of CCTO ceramics. <strong>Ceramics International<\/strong> 2021.<\/li>\r\n<li>Kum-Onsa P, Chanlek N, Thongbai P. Largely enhanced dielectric properties of TiO<sub>2<\/sub>-nanorods\/poly(vinylidene fluoride) nanocomposites driven by enhanced interfacial areas. <strong>Nanocomposites<\/strong> 2021; 7: 123-131.<\/li>\r\n<li>Tuichai W, Danwittayakul S, Manyam J, Chanlek N, Takesada M, Thongbai P. Giant dielectric properties of Ga<sup>3+<\/sup>\u2013Nb<sup>5+<\/sup>Co-doped TiO<sub>2<\/sub> ceramics driven by the internal barrier layer capacitor effect. <strong>Materialia<\/strong> 2021; 18: 101175.<\/li>\r\n<li>Kum-onsa P, Chanlek N, Takesada M, Srepusharawoot P, Thongbai P. (La3+, Mg2+) codoped BiFeO3 nanopowders: Synthesis, characterizations, and giant dielectric relaxations. <strong>Engineering and Applied Science Research<\/strong> 2021; 48: 766-772.<\/li>\r\n<li>Saengvong P, Chanlek N, Putasaeng B, Pengpad A, Harnchana V, Krongsuk S, et al. Significantly Improved Colossal Dielectric Properties and Maxwell\u2014Wagner Relaxation of TiO<sub>2<\/sub>\u2014Rich Na<sub>1\/2<\/sub>Y<sub>1\/2<\/sub>Cu<sub>3<\/sub>Ti<sub>4+x<\/sub>O<sub>12<\/sub> Ceramics. <strong>Molecules<\/strong> 2021; 26: 6043.<\/li>\r\n<li>Kum-onsa P, Putasaeng B, Manyam J, Thongbai P. Significantly improved dielectric properties of poly(vinylidene fluoride) polymer nanocomposites by the addition of nAu\u2212LaFeO<sub>3<\/sub> hybrid particles. <strong>Materials Research Bulletin<\/strong> 2022; 146: 111603.<\/li>\r\n<li>Silakaew K, Thongbai P. Effects of Sub-Micro Sized BaTiO3 Blocking Particles and Ag-Deposited Nano-Sized BaTiO<sub>3<\/sub> Hybrid Particles on Dielectric Properties of Poly(vinylidene-fluoride) Polymer. <strong>Polymers<\/strong> 2021; 13: 3641.<\/li>\r\n<li>Sreejivungsa K, Phromviyo N, Swatsitang E, Thongbai P. Characterizations and Significantly Enhanced Dielectric Properties of PVDF Polymer Nanocomposites by Incorporating Gold Nanoparticles Deposited on BaTiO<sub>3<\/sub> Nanoparticles. <strong>Polymers<\/strong> 2021; 13: 4144.<\/li>\r\n<li>Thongyong N, Chanlek N, Srepusharawoot P, Thongbai P. Origins of Giant Dielectric Properties with Low Loss Tangent in Rutile (Mg<sub>1\/3<\/sub>Ta<sub>2\/3<\/sub>)<sub>0.01<\/sub>Ti<sub>0.99<\/sub>O<sub>2<\/sub> Ceramic. <strong>Molecules<\/strong> 2021; 26: 6952.<\/li>\r\n<li>Thanamoon N, Chanlek N, Srepusharawoot P, Swatsitang E, Thongbai P. Microstructural Evolution and High-Performance Giant Dielectric Properties of Lu<sup>3+<\/sup>\/Nb<sup>5+<\/sup> Co-Doped TiO<sub>2<\/sub> Ceramics. <strong>Molecules<\/strong> 2021; 26: 7041.<\/li>\r\n<li>Silakaew K, Thongbai P. Continually enhanced dielectric constant of Poly(vinylidene fluoride) with BaTiO<sub>3<\/sub>@Poly(vinylidene fluoride) core-shell nanostructure filling. <strong>Ceramics International<\/strong> 2022; 48: 7005-7012.<\/li>\r\n<li>Saengvong P, Chanlek N, Srepusharawoot P, Harnchana V, Thongbai P. Enhancing giant dielectric properties of Ta<sup>5+<\/sup>-doped Na<sub>1\/2<\/sub>Y<sub>1\/2<\/sub>Cu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics by engineering grain and grain boundary. <strong>Journal of the American Ceramic Society<\/strong>; DOI: 10.1111\/jace.18330.<\/li>\r\n<li>Siriya P, Pengpad A, Srepusharawoot P, Chanlek N, Thongbai P. Improved microstructure and significantly enhanced dielectric properties of Al<sup>3+<\/sup>\/Cr<sup>3+<\/sup>\/Ta<sup>5+<\/sup> triple-doped TiO<sub>2<\/sub> ceramics by Re-balancing charge compensation. <strong>RSC Advances<\/strong> 2022; 12: 4946-4954.<\/li>\r\n<li>Siriya P, Chanlek N, Srepusharawoot P, Harnchana V, Thongbai P. Triple-doping of (Ga<sub>1\/2<\/sub>Nb<sub>1\/2<\/sub>)<sub>x<\/sub>Ti<sub>1-x<\/sub>O<sub>2<\/sub> ceramics with Al<sup>3+<\/sup> for enhanced giant dielectric response with simultaneous decrease in dielectric loss. <strong>Journal of the European Ceramic Society<\/strong> 2022; <a href=\"https:\/\/doi.org\/10.1016\/j.jeurceramsoc.2022.01.063\">https:\/\/doi.org\/10.1016\/j.jeurceramsoc.2022.01.063<\/a>.<\/li>\r\n<li>Prachamon J, Boonlakhorn J, Chanlek N, Phromviyo N, Harnchana V, Srepusharawoot P, et al. Enhanced dielectric response and non-Ohmic properties of Ge-doped CaTiO<sub>3<\/sub>\/CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub>. Journal of Asian Ceramic Societies 2022, 10; 473-481.<\/li>\r\n<li>Silakaew K, Swatsitang E, Thongbai P. Novel polymer composites of RuO<sub>2<\/sub>@nBaTiO<sub>3<\/sub>\/PVDF with a high dielectric constant. Ceramics International 2022, 48; 18925-18932.<\/li>\r\n<li>Siriya P, Chanlek N, Srepusharawoot P, Thongbai P. Excellent giant dielectric properties over wide temperatures of (Al, Sc)<sup>3+<\/sup> and Nb<sup>5+<\/sup> doped TiO<sub>2<\/sub>. Results in Physics 2022, 36; 105458.<\/li>\r\n<li>Jumpatam J, Prachamon J, Boonlakhorn J, Phromviyo N, Chanlek N, Thongbai P. Giant dielectric behavior and non-ohmic properties in Mg<sup>2+<\/sup>+F<sup>\u2212<\/sup> co-doped CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics. Journal of Asian Ceramic Societies 2022, 10; 414-423.<\/li>\r\n<li>Thanamoon N, Chanlek N, Moontragoon P, Srepusharawoot P, Thongbai P. Microstructure, low loss tangent, and excellent temperature stability of Tb+Sb-doped TiO<sub>2<\/sub> with high dielectric permittivity. Results in Physics 2022, 37; 105536.<\/li>\r\n<li>Thanamoon N, Chanlek N, Srepusharawoot P, Thongbai P. Origin of colossal dielectric performance of rutile-TiO<sub>2<\/sub> by substitution with Y<sup>3+<\/sup>+Ta<sup>5+<\/sup> dopants: DFT calculations and experimental study. Materialia 2022, 22; 101432.<\/li>\r\n<li>Mingmuang Y, Chanlek N, Thongbai P. Ultra\u2013low loss tangent and giant dielectric permittivity with excellent temperature stability of TiO<sub>2<\/sub> co-doped with isovalent-Zr<sup>4+<\/sup>\/pentavalent-Ta<sup>5+<\/sup> ions. Journal of Materiomics 2022, 8; 1269-1277.<\/li>\r\n<li>Jumpatam J, Boonlakhorn J, Phromviyo N, Chanlek N, Thongbai P. Electrical responses and dielectric properties of (Zn<sup>2+<\/sup>+\u00a0F<sup>\u2212<\/sup>) co\u2013doped CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics. Materialia 2022, 23; 101441.<\/li>\r\n<li>Thongyong N, Chanlek N, Srepusharawoot P, Takesada M, Cann DP, Thongbai P. Experimental study and DFT calculations of improved giant dielectric properties of Ni<sup>2+<\/sup>\/Ta<sup>5+ <\/sup>co-doped TiO<sub>2<\/sub> by engineering defects and internal interfaces. Journal of the European Ceramic Society 2022, 42; 4944-4952.<\/li>\r\n<li>Silakaew K, Thongbai P. Silver nanoparticles\u2013deposited sub-micro sized BaTiO<sub>3<\/sub>\/PVDF composites: greatly increased enhanced constant and effectively suppressed dielectric loss. Nanocomposites 2022, 8; 125-135.<\/li>\r\n<li>Mingmuang Y, Chanlek N, Srepusharawoot P, Thongbai P. Origin of excellent giant dielectric performance of rutile\u2013TiO<sub>2<\/sub> ceramics codoped with isovalent\/pentavalent dopants. Materials Research Bulletin 2022, 155; 111964.<\/li>\r\n<li>Mingmuang Y, Chanlek N, Moontragoon P, Srepusharawoot P, Thongbai P. Significantly improved dielectric properties of tin and niobium co-doped rutile TiO<sub>2<\/sub> driven by Maxwell-Wagner polarization. Journal of Alloys and Compounds 2022, 923; 166371.<\/li>\r\n<li>Saengvong P, Boonlakhorn J, Chanlek N, Phromviyo N, Harnchana V, Moontragoon P, et al. Effects of Sintering Conditions on Giant Dielectric and Nonlinear Current&amp;ndash;Voltage Properties of TiO<sub>2<\/sub>-Excessive Na<sub>1\/2<\/sub>Y<sub>1\/2<\/sub>Cu<sub>3<\/sub>Ti<sub>4.1<\/sub>O<sub>12 <\/sub>Ceramics. Molecules 2022, 27; 5311.<\/li>\r\n<li>Mingmuang Y, Chanlek N, Harnchana V, Thongbai P. Effect of Sn4+\u2013Isovalent doping concentration on giant dielectric properties of SnxTa<sub>0.025<\/sub>Ti<sub>0.975-x<\/sub>O<sub>2<\/sub> ceramics. Ceramics International 2023, 49; 188-193.<\/li>\r\n<li>Siriya P, Moontragoon P, Srepusharawoot P, Thongbai P. Giant Dielectric Properties of W<sup>6+<\/sup>-Doped TiO<sub>2<\/sub> Ceramics. Molecules 2022, 27; 6529.<\/li>\r\n<li>Mingmuang Y, Chanlek N, Moontragoon P, Srepusharawoot P, Thongbai P. Effects of Sn<sup>4+<\/sup> and Ta<sup>5+ <\/sup>dopant concentration on dielectric and electrical properties of TiO<sub>2<\/sub>: Internal barrier layer capacitor effect. Results in Physics 2022, 42; 106029.<\/li>\r\n<li>Thanamoon N, Chanlek N, Srepusharawoot P, Moontragoon P, Thongbai P. Giant dielectric properties of terbium and niobium co-doped TiO<sub>2<\/sub> ceramics driven by intrinsic and extrinsic effects. Journal of Alloys and Compounds 2023, 935; 168095.<\/li>\r\n<li>Thongyong N, Chanlek N, Takesada M, Thongbai P. Origins of high\u2013performance giant dielectric properties in TiO<sub>2<\/sub> co-doped with aliovalent ions via broadband dielectric spectroscopy. Results in Physics 2023, 44; 106210.<\/li>\r\n<li>Meeporn K, Chanlek N, Srepusharawoot P, Thongbai P. Extremely reduced loss tangent with retaining ultra high dielectric permittivity in Mg<sup>2+<\/sup>-doped La<sub>1.9<\/sub>Sr<sub>0.1<\/sub>NiO<sub>4<\/sub> ceramics. Heliyon 2023, 9.<\/li>\r\n<\/ol>\r\n<p><strong>As a co-author<\/strong><\/p>\r\n<ol>\r\n<li>Maensiri S, Thongbai P, Yamwong T. Giant dielectric response in (Li, Ti)-doped NiO ceramics synthesized by the polymerized complex method. <strong>Acta Materialia<\/strong> 2007; 55: 2851-2861.<\/li>\r\n<li>Maensiri S, Thongbai P, Yamwong T. Giant dielectric permittivity observed in CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub>\u2215(Li,Ti)-doped NiO composites. <strong>Applied Physics Letters<\/strong> 2007; 90: 202908.<\/li>\r\n<li>Thongbai P, Pongha S, Yamwong T, Maensiri S. Effects of Fe, Ti, and V doping on the microstructure and electrical properties of grain and grain boundary of giant dielectric NiO-based ceramics. <strong>Applied Physics Letters<\/strong> 2009; 94: 022908.<\/li>\r\n<li>Thongbai P, Yamwong T, Maensiri S. Electrical responses in high permittivity dielectric (Li, Fe)-doped NiO ceramics. <strong>Applied Physics Letters<\/strong> 2009; 94: 152905.<\/li>\r\n<li>Thongbai P, Maensiri S, Yamwong T, Yimnirun R. Giant dielectric properties of CaCu[sub 3]Ti[sub 4]O[sub 12]\u2215(Li,Ti)-doped NiO composites subjected to postsintering annealing and compressive stress. <strong>Journal of Applied Physics<\/strong> 2008; 103: 114107.<\/li>\r\n<li>Thongbai P, Maensiri S, Yamwong T. Effects of grain, grain boundary, and dc electric field on giant dielectric response in high purity CuO ceramics. <strong>Journal of Applied Physics<\/strong> 2008; 104: 036107.<\/li>\r\n<li>Thongbai P, Yamwong T, Maensiri S. The sintering temperature effects on the electrical and dielectric properties of Li<sub>0.05<\/sub>Ti<sub>0.0<\/sub>Ni<sub>0.93<\/sub>O ceramics prepared by a direct thermal decomposition method. <strong>Journal of Applied Physics<\/strong> 2008; 104: 074109.<\/li>\r\n<li>Thongbai P, Tangwancharoen S, Yamwong T, Maensiri S. Dielectric relaxation and dielectric response mechanism in (Li, Ti)-doped NiO ceramics. <strong>Journal of Physics: Condensed Matter<\/strong> 2008; 20: 395227.<\/li>\r\n<li>Thongbai P, Masingboon C, Maensiri S, Yamwong T, Wongsaenmai S, Yimnirun R. Giant dielectric behaviour of CaCu3Ti4O12 subjected to post-sintering annealing and uniaxial stress. <strong>Journal of Physics: Condensed Matter<\/strong> 2007; 19: 236208.<\/li>\r\n<li>Tangwancharoen S, Thongbai P, Yamwong T, Maensiri S. Dielectric and electrical properties of giant dielectric (Li, Al)-doped NiO ceramics. <strong>Materials Chemistry and Physics<\/strong> 2009; 115: 585-589.<\/li>\r\n<li>Thongbai P, Yamwong T, Maensiri S. Effects of Li and Fe doping on dielectric relaxation behavior in (Li, Fe)-doped NiO ceramics. <strong>Materials Chemistry and Physics<\/strong> 2010; 123: 56-61.<\/li>\r\n<li>Pongha S, Thongbai P, Yamwong T, Maensiri S. Giant dielectric response and polarization relaxation mechanism in (Li,V)-doped NiO ceramics. <strong>Scripta Materialia<\/strong> 2009; 60: 870-873.<\/li>\r\n<li>Thongbai P, Yamwong T, Maensiri S. Correlation between giant dielectric response and electrical conductivity of CuO ceramic. <strong>Solid State Communications<\/strong> 2008; 147: 385-387.<\/li>\r\n<li>Masingboon C, Thongbai P, Maensiri S, Yamwong T. Nanocrystalline CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> powder by PVA sol\u2013gel route: synthesis, characterization and its giant dielectric constant. <strong>Applied Physics A<\/strong> 2009; 96: 595-602.<\/li>\r\n<li>Hunpratub S, Thongbai P, Yamwong T, Yimnirun R, Maensiri S. Dielectric relaxations and dielectric response in multiferroic BiFeO<sub>3<\/sub> ceramics. <strong>Applied Physics Letters<\/strong> 2009; 94: 062904.<\/li>\r\n<li>Masingboon C, Thongbai P, Maensiri S, Yamwong T, Seraphin S. Synthesis and giant dielectric behavior of CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics prepared by polymerized complex method. <strong>Materials Chemistry and Physics<\/strong> 2008; 109: 262-270.<\/li>\r\n<li>Putjuso T, Manyum P, Yamwong T, Thongbai P, Maensiri S. Effect of annealing on electrical responses of electrode and surface layer in giant-permittivity CuO ceramic. <strong>Solid State Sciences<\/strong> 2011; 13: 2007-2010.<\/li>\r\n<li>Putjuso T, Manyum P, Yimnirun R, Yamwong T, Thongbai P, Maensiri S. Giant dielectric behavior of solution-growth CuO ceramics subjected to dc bias voltage and uniaxial compressive stress. <strong>Solid State Sciences<\/strong> 2011; 13: 158-162.<\/li>\r\n<li>Unruan M, Sareein T, Chandarak S, Hunpratub S, Thongbai P, Maensiri S, et al. Aging and stress-dependent dielectric properties of multiferroic bismuth ferrite ceramics. <strong>Materials Letters<\/strong> 2012; 70: 185-188.<\/li>\r\n<li>Laokul P, Thongbai P, Yamwong T, Maensiri S. High Dielectric Permittivity and Maxwell\u2013Wagner Polarization in Magnetic Ni<sub>0.5<\/sub>Cu<sub>0.3<\/sub>Zn<sub>0.2<\/sub>Fe<sub>2<\/sub>O<sub>4<\/sub> Ceramics. <strong>Journal of Superconductivity and Novel Magnetism<\/strong> 2012; 25: 1195-1201.<\/li>\r\n<li>Hunpratub S, Thongbai P, Yamwong T, Yimnirun R, Maensiri S. Effects of Mn Doping on the Dielectric Relaxations and Dielectric Response in Multiferroic BiFeO<sub>3<\/sub> Ceramics. <strong>Journal of Superconductivity and Novel Magnetism<\/strong> 2012; 25: 1619-1622.<\/li>\r\n<li>Moontragoon P, Pinitsoontorn S, Thongbai P. Mn-doped ZnO nanoparticles: Preparation, characterization, and calculation of electronic and magnetic properties. <strong>Microelectronic Engineering<\/strong> 2013; 108: 158-162.<\/li>\r\n<li>Masingboon C, Eknapakul T, Suwanwong S, Buaphet P, Nakajima H, Mo SK, et al. Anomalous change in dielectric constant of CaCu3Ti4O12 under violet-to-ultraviolet irradiation. <strong>Applied Physics Letters<\/strong> 2013; 102: 202903.<\/li>\r\n<li>Prasoetsopha N, Pinitsoontorn S, Thongbai P, Yamwong T. Giant dielectric behavior observed in Ca<sub>3<\/sub>Co<sub>4<\/sub>O<sub>9<\/sub> ceramic. <strong>Electronic Materials Letters<\/strong> 2013; 9: 347-351.<\/li>\r\n<li>Hanjitsuwan S, Hunpratub S, Thongbai P, Maensiri S, Sata V, Chindaprasirt P. Effects of NaOH concentrations on physical and electrical properties of high calcium fly ash geopolymer paste. <strong>Cement and Concrete Composites<\/strong> 2014; 45: 9-14.<\/li>\r\n<li>Kasian P, Yamwong T, Thongbai P, Rujirawat S, Yimnirun R, Maensiri S. Co-doped titanate nanotubes: Synthesis, characterization, and properties. <strong>Japanese Journal of Applied Physics<\/strong> 2014; 53: 06JG12.<\/li>\r\n<li>Yotburut B, Yamwong T, Thongbai P, Maensiri S. Synthesis and characterization of coprecipitation-prepared La-doped BiFeO3nanopowders and their bulk dielectric properties. <strong>Japanese Journal of Applied Physics<\/strong> 2014; 53: 06JG13.<\/li>\r\n<li>Kasian P, Thongbai P, Yamwong T, Rujirawat S, Yimnirun R, Maensiri S. The DC Bias Voltage Effect and Non-Linear Dielectric Properties of Titanate Nanotubes. <strong>Journal of Nanoscience and Nanotechnology<\/strong> 2015; 15: 9197-9202.<\/li>\r\n<li>Jittabut P, Pinitsoontorn S, Thongbai P, Amornkitbamrung V, Chindaprasirt P. Effect of nano-silica addition on the mechanical properties and thermal conductivity of cement composites. <strong>Chiang Mai Journal of Science<\/strong> 2016; 43: 1160-1170.<\/li>\r\n<li>Sikam P, Moontragoon P, Jumpatam J, Pinitsoontorn S, Thongbai P, Kamwanna T. Structural, Optical, Electronic and Magnetic Properties of Fe-Doped ZnO Nanoparticles Synthesized by Combustion Method and First-Principle Calculation. <strong>Journal of Superconductivity and Novel Magnetism<\/strong> 2016; 29: 3155-3166.<\/li>\r\n<li>Payakaniti P, Pinitsoontorn S, Thongbai P, Amornkitbamrung V, Chindaprasirt P. Electrical conductivity and compressive strength of carbon fiber reinforced fly ash geopolymeric composites. <strong>Construction and Building Materials<\/strong> 2017; 135: 164-176.<\/li>\r\n<li>Yotburut B, Thongbai P, Yamwong T, Maensiri S. Electrical and nonlinear current-voltage characteristics of La-doped BiFeO<sub>3<\/sub> ceramics. <strong>Ceramics International<\/strong> 2017; 43: 5616-5627.<\/li>\r\n<li>Yotburut B, Thongbai P, Yamwong T, Maensiri S. Synthesis and characterization of multiferroic Sm-doped BiFeO<sub>3<\/sub> nanopowders and their bulk dielectric properties. <strong>Journal of Magnetism and Magnetic Materials<\/strong> 2017; 437: 51-61.<\/li>\r\n<li>Kornphom C, Udeye T, Thongbai P, Bongkarn T. Phase structures, PPT region and electrical properties of new lead-free KNLNTS-BCTZ ceramics fabricated via the solid-state combustion technique. <strong>Ceramics International<\/strong> 2017; 43: S182-S192.<\/li>\r\n<li>Rattanathrum P, Taddee C, Chanlek N, Thongbai P, Kamwanna T. Structural and physical properties of Ge-doped CuCrO<sub>2<\/sub> delafossite oxide. <strong>Ceramics International<\/strong> 2017; 43: S417-S422.<\/li>\r\n<li>Phromviyo N, Thongbai P, Maensiri S. High dielectric permittivity and suppressed loss tangent in PVDF polymer nanocomposites using gold nanoparticle\u2013deposited BaTiO<sub>3<\/sub> hybrid particles as fillers. <strong>Applied Surface Science<\/strong> 2018; 446: 236-242.<\/li>\r\n<li>Phromviyo N, Chanlek N, Thongbai P, Maensiri S. Enhanced dielectric permittivity with retaining low loss in poly(vinylidene fluoride) by incorporating with Ag nanoparticles synthesized via hydrothermal method. <strong>Applied Surface Science<\/strong> 2018; 446: 59-65.<\/li>\r\n<li>Sikam P, Moontragoon P, Sararat C, Karaphun A, Swatsitang E, Pinitsoontorn S, et al. DFT calculation and experimental study on structural, optical and magnetic properties of Co-doped SrTiO<sub>3<\/sub>. <strong>Applied Surface Science<\/strong> 2018; 446: 92-113.<\/li>\r\n<li>Nachaithong T, Tuichai W, Moontragoon P, Chanlek N, Thongbai P. Giant dielectric permittivity and dielectric relaxation behaviour in (Fe<sub>1\/2<\/sub>Nb<sub>1\/2<\/sub>)<sub>x<\/sub>Ti<sub>1-x<\/sub>O<sub>2<\/sub> ceramics. <strong>Ceramics International<\/strong> 2018; 44: S186-S188.<\/li>\r\n<li>Thongyong N, Srepusharawoot P, Tuichai W, Chanlek N, Amornkitbamrung V, Thongbai P. Electronic structure of colossal permittivity (Mg<sub>1\/3<\/sub>Nb<sub>2\/3<\/sub>)<sub>0.05<\/sub>Ti<sub>0.95<\/sub>O<sub>2<\/sub> ceramics. <strong>Ceramics International<\/strong> 2018; 44: S145-S147.<\/li>\r\n<li>Phromviyo N, Thongbai P, Ratchaphonsaenwong K, Chanlek N, Chindaprasirt P. Dielectric and electrical properties of nano-Ag\/C<sub>3<\/sub>AH<sub>6<\/sub> nanocomposites. <strong>Applied Surface Science<\/strong> 2019; 483: 294-301.<\/li>\r\n<li>Sikam P, Moontragoon P, Ikonic Z, Kaewmaraya T, Thongbai P. The study of structural, morphological and optical properties of (Al, Ga)-doped ZnO: DFT and experimental approaches. <strong>Applied Surface Science<\/strong> 2019; 480: 621-635.<\/li>\r\n<li>Payakaniti P, Pinitsoonthorn S, Thongbai P, Amornkitbamrung V, Chindaprasirt P. Effects of carbon fiber on mechanical and electrical properties of fly ash geopolymer composite. <strong>Materials Today: Proceedings<\/strong> 2018; 5: 14017-14025.<\/li>\r\n<li>Waree K, Pangza K, Jangsawang N, Thongbai P, Buranurak S. Dielectric properties of poly (vinylidene fluoride)\/barium titanate nanocomposites under gamma irradiation. <strong>Radiation Protection Dosimetry<\/strong> 2019; 184: 342-346.<\/li>\r\n<li>Nachaithong T, Moontragoon P, Chanlek N, Thongbai P. Fe<sup>3+<\/sup>\/Nb<sup>5+ <\/sup>Co-doped rutile-TiO<sub>2 <\/sub>nanocrystalline powders prepared by a combustion process: Preparation and characterization and their giant dielectric response. <strong>RSC Advances<\/strong> 2020; 10: 24784-24794.<\/li>\r\n<li>Kum-onsa P, Chanlek N, Thongbai P, Srepusharawoot P. Effect of complex defects on the origin of giant dielectric properties of Mg<sup>2+<\/sup>\u2212doped BiFeO<sub>3<\/sub> ceramics prepared by a precipitation method. <strong>Ceramics International<\/strong> 2020; 46: 25017-25023.<\/li>\r\n<li>Traiphop S, Thongbai P, Kamwanna T. Effect of synthesis method on magnetic and dielectric properties of CuBO<sub>2<\/sub> delafossite oxide. <strong>Journal of the Australian Ceramic Society<\/strong> 2020; 56: 499-505.<\/li>\r\n<li>Boonlakhorn J, Chanlek N, Thongbai P, Srepusharawoot P. Strongly Enhanced Dielectric Response and Structural Investigation of (Sr<sup>2+<\/sup>, Ge<sup>4+<\/sup>) Co-Doped CCTO Ceramics. <strong>Journal of Physical Chemistry C<\/strong> 2020; 124: 20682-20692.<\/li>\r\n<li>Boonlakhorn J, Prachamon J, Manyam J, Thongbai P, Srepusharawoot P. Origins of a liquid-phase sintering mechanism and giant dielectric properties of Ni+Ge co-doped CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12 <\/sub>ceramics. <strong>Ceramics International<\/strong> 2021; 47: 13415-13422.<\/li>\r\n<li>Boonlakhorn J, Chanlek N, Manyam J, Krongsuk S, Thongbai P, Srepusharawoot P. Structural and dielectric properties, and nonlinear electrical response of the CaCu<sub>3-x<\/sub>Zn<sub>x<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics: Experimental and computational studies. <strong>Ceramics International<\/strong> 2021.<\/li>\r\n<li>Suphasorn P, Appamato I, Harnchana V, Thongbai P, Chanthad C, Siriwong C, et al. Ag Nanoparticle-Incorporated Natural Rubber for Mechanical Energy Harvesting Application. <strong>Molecules<\/strong> 2021; 26: 2720.<\/li>\r\n<li>Prada T, Harnchana V, Lakhonchai A, Chingsungnoen A, Poolcharuansin P, Chanlek N, et al. Enhancement of output power density in a modified polytetrafluoroethylene surface using a sequential O<sub>2<\/sub>\/Ar plasma etching for triboelectric nanogenerator applications. <strong>Nano Research<\/strong> 2021.<\/li>\r\n<li>Boonlakhorn J, Prachamon J, Manyam J, Krongsuk S, Thongbai P, Srepusharawoot P. Colossal dielectric permittivity, reduced loss tangent and the microstructure of Ca<sub>1\u2212x<\/sub>Cd<sub>x<\/sub>Cu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12\u22122y<\/sub>F<sub>2y<\/sub> ceramics. <strong>RSC Advances<\/strong> 2021; 11: 16396-16403.<\/li>\r\n<li>Boonlakhorn J, Manyam J, Krongsuk S, Thongbai P, Srepusharawoot P. Enhanced dielectric properties with a significantly reduced loss tangent in (Mg<sup>2+<\/sup>, Al<sup>3+<\/sup>) co-doped CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramics: DFT and experimental investigations. <strong>RSC Advances<\/strong> 2021; 11: 25038-25046.<\/li>\r\n<li>Nachaithong T, Sikam P, Moontragoon P, Thongbai P, Kaewmaraya T, Ikonic Z. The study of optical and colossal dielectric properties of (Cu, Ga)-doped ZnO nanoparticles. <strong>Engineering and Applied Science Research<\/strong> 2021; 48: 759-765.<\/li>\r\n<li>Phromviyo N, Boonlakhorn J, Posi P, Thongbai P, Chindaprasirt P. Dielectric and Mechanical Properties of CTAB-Modified Natural Rubber Latex&amp;ndash;Cement Composites. <strong>Polymers<\/strong> 2022; 14: 320.<\/li>\r\n<li>Boonlakhorn J, Prachamon J, Jumpatam J, Krongsuk S, Thongbai P, Srepusharawoot P. Dielectric characteristics of a (Cd<sup>2+<\/sup>, F<sup>&#8211;<\/sup>) co-doped CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub>\/CaTiO<sub>3<\/sub> binary system improved with increased dielectric permittivity and decreased dielectric loss tangent. <strong>Results in Physics<\/strong> 2022; 34: 105275.<\/li>\r\n<li>Boonlakhorn J, Chanlek N, Krongsuk S, Thongbai P, Srepusharawoot P. Giant dielectric properties of Mg doped CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> fabricated using a chemical combustion method: Theoretical and experimental approaches. <strong>Materials Research Bulletin<\/strong> 2022; 150: 111749.<\/li>\r\n<li>Boonlakhorn J, Nijpanich S, Thongbai P, Srepusharawoot P. High dielectric permittivity and dielectric relaxation behavior in a Y<sub>2\/3<\/sub>Cu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> ceramic prepared by a modified Sol\u2212Gel route. <strong>Ceramics International<\/strong> 2022; https:\/\/doi.org\/10.1016\/j.ceramint.2022.02.074<\/li>\r\n<\/ol>\r\n<p>[\/vc_column_text][\/vc_tta_section][vc_tta_section title=&#8221;\u0e23\u0e32\u0e07\u0e27\u0e31\u0e25&#8221; tab_id=&#8221;1675438012155-0977c426-aa8a&#8221;][vc_column_text animation=&#8221;bounceInDown&#8221;]<\/p>\r\n<ol>\r\n<li><strong>\u0e23\u0e32\u0e07\u0e27\u0e31\u0e25\u0e19\u0e31\u0e01\u0e27\u0e34\u0e17\u0e22\u0e32\u0e28\u0e32\u0e2a\u0e15\u0e23\u0e4c\u0e23\u0e38\u0e48\u0e19\u0e43\u0e2b\u0e21\u0e48 \u0e2a\u0e32\u0e02\u0e32\u0e1f\u0e34\u0e2a\u0e34\u0e01\u0e2a\u0e4c \u0e1b\u0e23\u0e30\u0e08\u0e33\u0e1b\u0e35 \u0e1e.\u0e28. 2556\u00a0 <\/strong>\u0e21\u0e39\u0e25\u0e19\u0e34\u0e18\u0e34\u0e2a\u0e48\u0e07\u0e40\u0e2a\u0e23\u0e34\u0e21\u0e27\u0e34\u0e17\u0e22\u0e32\u0e28\u0e32\u0e2a\u0e15\u0e23\u0e4c\u0e41\u0e25\u0e30\u0e40\u0e17\u0e04\u0e42\u0e19\u0e42\u0e25\u0e22\u0e35\u0e43\u0e19\u0e1e\u0e23\u0e30\u0e1a\u0e23\u0e21\u0e23\u0e32\u0e0a\u0e39\u0e1b\u0e16\u0e31\u0e21\u0e20\u0e4c \u0e40\u0e21\u0e37\u0e48\u0e2d\u0e27\u0e31\u0e19\u0e17\u0e35\u0e48 2 \u0e2a\u0e34\u0e07\u0e2b\u0e32\u0e04\u0e21 2556<\/li>\r\n<li><strong>\u0e23\u0e32\u0e07\u0e27\u0e31\u0e25 <\/strong><strong>TRF-CHE-Scopus Young Researcher Awards 2013 \u0e2a\u0e32\u0e02\u0e32<\/strong>\u00a0<strong>Physical Sciences<\/strong><strong>\u00a0 <\/strong>\u0e2a\u0e33\u0e19\u0e31\u0e01\u0e07\u0e32\u0e19\u0e01\u0e2d\u0e07\u0e17\u0e38\u0e19\u0e2a\u0e19\u0e31\u0e1a\u0e2a\u0e19\u0e38\u0e19\u0e01\u0e32\u0e23\u0e27\u0e34\u0e08\u0e31\u0e22 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<\/strong><strong>201<\/strong><strong>7 <\/strong><strong>The World Academy of Sciences (<\/strong><strong>TWAS) \u0e2a\u0e32\u0e02\u0e32\u0e1f\u0e34\u0e2a\u0e34\u0e01\u0e2a\u0e4c <\/strong>\u0e2a\u0e33\u0e19\u0e31\u0e01\u0e07\u0e32\u0e19\u0e04\u0e13\u0e30\u0e01\u0e23\u0e23\u0e21\u0e01\u0e32\u0e23\u0e27\u0e34\u0e08\u0e31\u0e22\u0e41\u0e2b\u0e48\u0e07\u0e0a\u0e32\u0e15\u0e34 (\u0e27\u0e0a.) \u0e01\u0e31\u0e1a TWAS <strong>for the advancement of science in developing countries <\/strong>\u0e40\u0e21\u0e37\u0e48\u0e2d\u0e27\u0e31\u0e19\u0e17\u0e35\u0e48 2 \u0e01\u0e38\u0e21\u0e20\u0e32\u0e1e\u0e31\u0e19\u0e18\u0e4c 2561<\/li>\r\n<li><strong>\u0e23\u0e32\u0e07\u0e27\u0e31\u0e25\u0e1c\u0e25\u0e07\u0e32\u0e19\u0e27\u0e34\u0e08\u0e31\u0e22 <\/strong><strong>\u0e23\u0e32\u0e07\u0e27\u0e31\u0e25\u0e23\u0e30\u0e14\u0e31\u0e1a\u0e14\u0e35\u0e40\u0e14\u0e48\u0e19<\/strong> <strong>\u0e2a\u0e32\u0e02\u0e32\u0e27\u0e34\u0e17\u0e22\u0e32\u0e28\u0e32\u0e2a\u0e15\u0e23\u0e4c\u0e01\u0e32\u0e22\u0e20\u0e32\u0e1e\u0e41\u0e25\u0e30\u0e04\u0e13\u0e34\u0e15\u0e28\u0e32\u0e2a\u0e15\u0e23<\/strong><strong>\u0e4c \u0e1b\u0e23\u0e30\u0e08\u0e33\u0e1b\u0e35 \u0e52\u0e55\u0e55\u0e57 <\/strong>\u0e1c\u0e25\u0e07\u0e32\u0e19\u0e27\u0e34\u0e08\u0e31\u0e22\u0e40\u0e23\u0e37\u0e48\u0e2d\u0e07 \u201c<em>\u0e01\u0e32\u0e23\u0e1b\u0e23\u0e31\u0e1a\u0e1b\u0e23\u0e38\u0e07\u0e2a\u0e21\u0e1a\u0e31\u0e15\u0e34\u0e17\u0e32\u0e07\u0e44\u0e1f\u0e1f\u0e49\u0e32\u0e41\u0e25\u0e30\u0e2a\u0e21\u0e1a\u0e31\u0e15\u0e34\u0e17\u0e32\u0e07\u0e2d\u0e34\u0e40\u0e25\u0e47\u0e01\u0e15\u0e23\u0e34\u0e01\u0e02\u0e2d\u0e07\u0e27\u0e31\u0e2a\u0e14\u0e38\u0e40\u0e0b\u0e23\u0e32\u0e21\u0e34\u0e01 <\/em><em>CaCu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12<\/sub> 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\u201c<em>\u0e01\u0e32\u0e23\u0e1b\u0e23\u0e30\u0e14\u0e34\u0e29\u0e10\u0e4c\u0e27\u0e31\u0e2a\u0e14\u0e38\u0e40\u0e0b\u0e23\u0e32\u0e21\u0e34\u0e01\u0e01\u0e25\u0e38\u0e48\u0e21 <\/em><em>ACu<sub>3<\/sub>Ti<sub>4<\/sub>O<sub>12 <\/sub>\u0e42\u0e04\u0e23\u0e07\u0e2a\u0e23\u0e49\u0e32\u0e07\u0e1e\u0e34\u0e40\u0e28\u0e29\u0e40\u0e1e\u0e37\u0e48\u0e2d\u0e1e\u0e35\u0e12\u0e19\u0e32\u0e40\u0e1b\u0e47\u0e19\u0e27\u0e31\u0e2a\u0e14\u0e38\u0e44\u0e14\u0e2d\u0e34\u0e40\u0e25\u0e47\u0e01\u0e15\u0e23\u0e34\u0e01\u0e1b\u0e23\u0e30\u0e2a\u0e34\u0e17\u0e18\u0e34\u0e20\u0e32\u0e1e\u0e2a\u0e39\u0e07<\/em>\u201d \u0e08\u0e32\u0e01\u0e2a\u0e33\u0e19\u0e31\u0e01\u0e07\u0e32\u0e19\u0e04\u0e13\u0e30\u0e01\u0e23\u0e23\u0e21\u0e01\u0e32\u0e23\u0e27\u0e34\u0e08\u0e31\u0e22\u0e41\u0e2b\u0e48\u0e07\u0e0a\u0e32\u0e15\u0e34 (\u0e27\u0e0a.) \u0e27\u0e31\u0e19\u0e17\u0e35\u0e48 2 \u0e01\u0e38\u0e21\u0e20\u0e32\u0e1e\u0e31\u0e19\u0e18\u0e4c 2566<\/li>\r\n<li><strong>\u0e23\u0e32\u0e07\u0e27\u0e31\u0e25\u0e28\u0e34\u0e29\u0e22\u0e4c\u0e40\u0e01\u0e48\u0e32<\/strong><strong>\u0e1a\u0e31\u0e13\u0e11\u0e34\u0e15\u0e28\u0e36\u0e01\u0e29\u0e32<\/strong><strong>\u0e14\u0e35\u0e40\u0e14\u0e48\u0e19 <\/strong><strong>\u0e1a\u0e31\u0e13\u0e11\u0e34\u0e15\u0e28\u0e36\u0e01\u0e29\u0e32<\/strong> <strong>\u0e21\u0e2b\u0e32\u0e27\u0e34\u0e17\u0e22\u0e32\u0e25\u0e31\u0e22\u0e02\u0e2d\u0e19\u0e41\u0e01\u0e48\u0e19 \u0e14\u0e49\u0e32\u0e19\u0e27\u0e34\u0e0a\u0e32\u0e01\u0e32\u0e23\u0e41\u0e25\u0e30\u0e27\u0e34\u0e08\u0e31\u0e22 \u0e1b\u0e23\u0e30\u0e08\u0e33\u0e1b\u0e35 2557 <\/strong>\u0e1a\u0e31\u0e13\u0e11\u0e34\u0e15\u0e27\u0e34\u0e17\u0e22\u0e32\u0e25\u0e31\u0e22 \u0e21\u0e2b\u0e32\u0e27\u0e34\u0e17\u0e22\u0e32\u0e25\u0e31\u0e22\u0e02\u0e2d\u0e19\u0e41\u0e01\u0e48\u0e19 \u0e40\u0e21\u0e37\u0e48\u0e2d\u0e27\u0e31\u0e19\u0e17\u0e35\u0e48 27 \u0e21\u0e35\u0e19\u0e32\u0e04\u0e21 2558<\/li>\r\n<li><strong>\u0e23\u0e32\u0e07\u0e27\u0e31\u0e25\u0e19\u0e31\u0e01\u0e27\u0e34\u0e08\u0e31\u0e22\u0e23\u0e38\u0e48\u0e19\u0e43\u0e2b\u0e21\u0e48\u0e17\u0e35\u0e48\u0e21\u0e35\u0e1c\u0e25\u0e07\u0e32\u0e19\u0e27\u0e34\u0e08\u0e31\u0e22\u0e23\u0e30\u0e14\u0e31\u0e1a\u0e14\u0e35\u0e40\u0e22\u0e35\u0e48\u0e22\u0e21 \u0e21\u0e2b\u0e32\u0e27\u0e34\u0e17\u0e22\u0e32\u0e25\u0e31\u0e22\u0e02\u0e2d\u0e19\u0e41\u0e01\u0e48\u0e19 \u0e1b\u0e23\u0e30\u0e08\u0e33\u0e1b\u0e35 2556<\/strong> <strong>\u0e2a\u0e32\u0e02\u0e32\u0e27\u0e34\u0e17\u0e22\u0e32\u0e28\u0e32\u0e2a\u0e15\u0e23\u0e4c\u0e01\u0e32\u0e22\u0e20\u0e32\u0e1e <\/strong>\u0e21\u0e2b\u0e32\u0e27\u0e34\u0e17\u0e22\u0e32\u0e25\u0e31\u0e22\u0e02\u0e2d\u0e19\u0e41\u0e01\u0e48\u0e19 \u0e40\u0e21\u0e37\u0e48\u0e2d\u0e27\u0e31\u0e19\u0e17\u0e35\u0e48 13 \u0e1e\u0e24\u0e28\u0e08\u0e34\u0e01\u0e32\u0e22\u0e19 2556<\/li>\r\n<li><strong>\u0e23\u0e32\u0e07\u0e27\u0e31\u0e25\u0e19\u0e31\u0e01\u0e27\u0e34\u0e08\u0e31\u0e22\u0e23\u0e38\u0e48\u0e19\u0e43\u0e2b\u0e21\u0e48\u0e17\u0e35\u0e48\u0e21\u0e35\u0e1c\u0e25\u0e07\u0e32\u0e19\u0e27\u0e34\u0e08\u0e31\u0e22\u0e23\u0e30\u0e14\u0e31\u0e1a\u0e14\u0e35\u0e40\u0e22\u0e35\u0e48\u0e22\u0e21 \u0e21\u0e2b\u0e32\u0e27\u0e34\u0e17\u0e22\u0e32\u0e25\u0e31\u0e22\u0e02\u0e2d\u0e19\u0e41\u0e01\u0e48\u0e19 \u0e1b\u0e23\u0e30\u0e08\u0e33\u0e1b\u0e35 2557<\/strong> <strong>\u0e2a\u0e32\u0e02\u0e32\u0e27\u0e34\u0e17\u0e22\u0e32\u0e28\u0e32\u0e2a\u0e15\u0e23\u0e4c\u0e01\u0e32\u0e22\u0e20\u0e32\u0e1e <\/strong>\u0e21\u0e2b\u0e32\u0e27\u0e34\u0e17\u0e22\u0e32\u0e25\u0e31\u0e22\u0e02\u0e2d\u0e19\u0e41\u0e01\u0e48\u0e19 \u0e40\u0e21\u0e37\u0e48\u0e2d\u0e27\u0e31\u0e19\u0e17\u0e35\u0e48 10 \u0e01\u0e38\u0e21\u0e20\u0e32\u0e1e\u0e31\u0e19\u0e18\u0e4c 2558<\/li>\r\n<li><strong>\u0e23\u0e32\u0e07\u0e27\u0e31\u0e25\u0e19\u0e31\u0e01\u0e27\u0e34\u0e08\u0e31\u0e22\u0e14\u0e35\u0e40\u0e14\u0e48\u0e19 (<\/strong><strong>Excellent Research Award) \u0e23\u0e32\u0e07\u0e27\u0e31\u0e25\u0e19\u0e31\u0e01\u0e27\u0e34\u0e08\u0e31\u0e22\u0e23\u0e30\u0e14\u0e31\u0e1a\u0e40\u0e2b\u0e23\u0e35\u0e22\u0e0d\u0e40\u0e07\u0e34\u0e19 (Silver Medal Research Award) <\/strong>\u0e21\u0e2b\u0e32\u0e27\u0e34\u0e17\u0e22\u0e32\u0e25\u0e31\u0e22\u0e02\u0e2d\u0e19\u0e41\u0e01\u0e48\u0e19 \u0e40\u0e21\u0e37\u0e48\u0e2d\u0e27\u0e31\u0e19\u0e17\u0e35\u0e48 10 \u0e01\u0e38\u0e21\u0e20\u0e32\u0e1e\u0e31\u0e19\u0e18\u0e4c 2558<\/li>\r\n<li><strong>\u0e23\u0e32\u0e07\u0e27\u0e31\u0e25\u0e19\u0e31\u0e01\u0e27\u0e34\u0e08\u0e31\u0e22\u0e14\u0e35\u0e40\u0e14\u0e48\u0e19 (<\/strong><strong>Excellent Research Award) \u0e23\u0e32\u0e07\u0e27\u0e31\u0e25\u0e19\u0e31\u0e01\u0e27\u0e34\u0e08\u0e31\u0e22\u0e23\u0e30\u0e14\u0e31\u0e1a\u0e17\u0e2d\u0e07 (Gold Research Award) <\/strong>\u0e21\u0e2b\u0e32\u0e27\u0e34\u0e17\u0e22\u0e32\u0e25\u0e31\u0e22\u0e02\u0e2d\u0e19\u0e41\u0e01\u0e48\u0e19 \u0e40\u0e21\u0e37\u0e48\u0e2d\u0e27\u0e31\u0e19\u0e17\u0e35\u0e48 3 \u0e40\u0e21\u0e29\u0e32\u0e22\u0e19 2560<\/li>\r\n<li><strong>\u0e23\u0e32\u0e07\u0e27\u0e31\u0e25\u0e19\u0e31\u0e01\u0e27\u0e34\u0e08\u0e31\u0e22\u0e14\u0e35\u0e40\u0e14\u0e48\u0e19 (<\/strong><strong>Excellent Research Award) \u0e23\u0e32\u0e07\u0e27\u0e31\u0e25\u0e19\u0e31\u0e01\u0e27\u0e34\u0e08\u0e31\u0e22\u0e23\u0e30\u0e14\u0e31\u0e1a\u0e40\u0e1e\u0e0a\u0e23 (Diamond Research Award) <\/strong>\u0e21\u0e2b\u0e32\u0e27\u0e34\u0e17\u0e22\u0e32\u0e25\u0e31\u0e22\u0e02\u0e2d\u0e19\u0e41\u0e01\u0e48\u0e19 \u0e40\u0e21\u0e37\u0e48\u0e2d\u0e27\u0e31\u0e19\u0e17\u0e35\u0e48 5 \u0e21\u0e34\u0e16\u0e38\u0e19\u0e32\u0e22\u0e19 2561<\/li>\r\n<li><strong>\u0e23\u0e32\u0e07\u0e27\u0e31\u0e25\u0e19\u0e31\u0e01\u0e27\u0e34\u0e08\u0e31\u0e22\u0e14\u0e35\u0e40\u0e14\u0e48\u0e19 (<\/strong><strong>Excellent Research Award) \u0e23\u0e32\u0e07\u0e27\u0e31\u0e25\u0e19\u0e31\u0e01\u0e27\u0e34\u0e08\u0e31\u0e22\u0e40\u0e01\u0e35\u0e22\u0e23\u0e15\u0e34\u0e04\u0e38\u0e13\u0e2a\u0e32\u0e23\u0e2a\u0e34\u0e19 (Sarasin Honorable Research Award) <\/strong>\u0e21\u0e2b\u0e32\u0e27\u0e34\u0e17\u0e22\u0e32\u0e25\u0e31\u0e22\u0e02\u0e2d\u0e19\u0e41\u0e01\u0e48\u0e19 \u0e1b\u0e23\u0e30\u0e08\u0e33\u0e1b\u0e35 2563<\/li>\r\n<li><strong>\u0e23\u0e32\u0e07\u0e27\u0e31\u0e25 \u0e1a\u0e38\u0e04\u0e25\u0e32\u0e01\u0e23\u0e14\u0e35\u0e40\u0e14\u0e48\u0e19\u0e04\u0e19\u0e14\u0e35\u0e28\u0e23\u0e35\u0e08\u0e33\u0e1b\u0e32 \u0e14\u0e49\u0e32\u0e19\u0e01\u0e32\u0e23\u0e27\u0e34\u0e08\u0e31\u0e22 \u0e04\u0e13\u0e30\u0e27\u0e34\u0e17\u0e22\u0e32\u0e28\u0e32\u0e2a\u0e15\u0e23\u0e4c \u0e21\u0e2b\u0e32\u0e27\u0e34\u0e17\u0e22\u0e32\u0e25\u0e31\u0e22\u0e02\u0e2d\u0e19\u0e41\u0e01\u0e48\u0e19 \u0e1b\u0e23\u0e30\u0e08\u0e33\u0e1b\u0e35 2561 <\/strong><\/li>\r\n<li><strong>The MSc Thesis Award of the Year 2007, <\/strong>Khon Kaen University, Khon Kaen, Thailand<\/li>\r\n<li><strong>Thailand Graduate Institute of Science and Technology (TGIST) Scholarship Outstanding Student Award of the Year 2008, <\/strong>National Science and Technology Development Agency (NSTDA)<\/li>\r\n<li><strong>The PhD Thesis Award of the Year 2010, <\/strong>Khon Kaen University, Khon Kaen, Thailand<\/li>\r\n<li><strong>The PhD Thesis Award of the Year 2011<\/strong>, National Research Council of Thailand (NRCT)<\/li>\r\n<li><strong>\u0e23\u0e32\u0e07\u0e27\u0e31\u0e25\u0e01\u0e32\u0e23\u0e28\u0e36\u0e01\u0e29\u0e32\u0e22\u0e2d\u0e14\u0e40\u0e22\u0e35\u0e48\u0e22\u0e21\u0e2d\u0e31\u0e19\u0e14\u0e31\u0e1a\u0e17\u0e35\u0e48 <\/strong><strong>1 \u0e02\u0e31\u0e49\u0e19\u0e27\u0e34\u0e17\u0e22\u0e32\u0e28\u0e32\u0e2a\u0e15\u0e23\u0e14\u0e38\u0e29\u0e0e\u0e35\u0e1a\u0e31\u0e13\u0e11\u0e34\u0e15 \u0e2a\u0e32\u0e02\u0e32\u0e1f\u0e34\u0e2a\u0e34\u0e01\u0e2a\u0e4c <\/strong>\u0e21\u0e39\u0e25\u0e19\u0e34\u0e18\u0e34\u0e28\u0e32\u0e2a\u0e15\u0e23\u0e32\u0e08\u0e32\u0e23\u0e22\u0e4c \u0e14\u0e23.\u0e41\u0e16\u0e1a \u0e19\u0e35\u0e25\u0e30\u0e19\u0e34\u0e18\u0e34 \u0e1b\u0e23\u0e30\u0e08\u0e33\u0e1b\u0e35\u0e01\u0e32\u0e23\u0e28\u0e36\u0e01\u0e29\u0e32 2552<\/li>\r\n<\/ol>\r\n<p>[\/vc_column_text][\/vc_tta_section][\/vc_tta_tabs][\/vc_column][\/vc_row]<\/p><\/section>","protected":false},"excerpt":{"rendered":"<p>[vc_row][vc_column][vc_column_text animation=&#8221;bou 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