{"id":91,"date":"2016-01-12T16:10:20","date_gmt":"2016-01-12T22:10:20","guid":{"rendered":"http:\/\/www.engineering.iastate.edu\/people\/profile\/xtan\/"},"modified":"2026-05-27T20:05:29","modified_gmt":"2026-05-28T01:05:29","slug":"xtan","status":"publish","type":"profile","link":"https:\/\/www.engineering.iastate.edu\/people\/profile\/xtan\/","title":{"rendered":"Tan, Xiaoli"},"author":3,"template":"","affiliation":[4],"department":[9,1158],"group":[],"interest":[389,387,388,384,385,386],"class_list":["post-91","profile","type-profile","status-publish","hentry","affiliation-faculty","department-mse","department-mse-faculty","interest-electrical-capacitors","interest-materials-for-energy-harvesting","interest-mechanical-properties","interest-piezoelectric-ceramics","interest-smart-materials","interest-transmission-electron-microscopy"],"firstname":"Xiaoli","key_research_area":["Advanced Materials & Manufacturing"],"netid":"xtan","isu_title":"Professor [M S E]","email":"xtan@iastate.edu","external_link":"","hide_isu_title":"1","nickname":"","info":"<h4 id=\"links-header\" class=\"dir-header\">Links<\/h4>\r\n<ul>\r\n<li><a href=\"http:\/\/www.researcherid.com\/rid\/C-3376-2013\">ResearcherID Webpage<\/a><\/li>\r\n<li><a href=\"http:\/\/scholar.google.com\/citations?user=17OBwvMAAAAJ&amp;hl=en\">Google Scholar Citations<\/a><\/li>\r\n<\/ul>\r\n<div><strong>Academic Experience<\/strong>\r\n<ul>\r\n<li>2013-present - Professor, Iowa State University<\/li>\r\n<li>2008-2013- Associate Professor, Iowa State University<\/li>\r\n<li>2002-2008 - Assistant Professor, Iowa State University<\/li>\r\n<\/ul>\r\n<strong>Teaching<\/strong>\r\n<ul>\r\n<li>Mat E 215 Introduction to Materials Science and Engineering I<\/li>\r\n<li>Mat E 216L Introduction to Materials Science and Engineering II - Lab<\/li>\r\n<li>Mat E 272 Principles of Materials Science and Engineering<\/li>\r\n<li>Mat E 319 Mechanics of Structure and Materials<\/li>\r\n<li>Mat E 321 Introduction to Ceramic Science<\/li>\r\n<li>Mat E 418 Mechanical Behavior of Materials<\/li>\r\n<li>Mat E 433 Advanced Ceramics and Electronic Materials<\/li>\r\n<li>MSE 590 Ferroelectric and Piezoelectric Ceramics<\/li>\r\n<li>MSE 630 Physical Properties of Materials<\/li>\r\n<\/ul>\r\n<strong>Honors and Awards<\/strong>\r\n<ul>\r\n<li>2023: Schafer 2050 Challenge Professorship (01\/2023 - 12\/2027), College of Engineering, ISU&nbsp;<\/li>\r\n<li>2021: Graduate student Pratyasha Mohapatra received the ISU Research Excellence Award<\/li>\r\n<li>2020: Postdoc Xinchun Tian received the ISU Postdoctoral Research Excellence Award<\/li>\r\n<li>2020: Graduate student Zhongming Fan received the Zaffarano Prize for Graduate Student Research, the highest research award at ISU<\/li>\r\n<li>2019:&nbsp;<em>Applied Physics Letters<\/em> cover graphics of May 27, 2019, issue<\/li>\r\n<li>2018:&nbsp;<em>Journal of the American Ceramic Society<\/em> outstanding journal reviewer<\/li>\r\n<li>2018: Graduate student Zhongming Fan received the Research Excellence Award, ISU<\/li>\r\n<li>2016: Graduate student Xiaoming Liu received MSE Rohit K. Trivedi Best Paper Award, ISU<\/li>\r\n<li>2015: Graduate student Xiaoming Liu received the Research Excellence Award, ISU<\/li>\r\n<li>2015: Graduate student, Hanzheng Guo, received the Zaffarano Prize for Graduate Student Research, the highest research award at ISU<\/li>\r\n<li>2014: Graduate student Hanzheng Guo received the MSE Rohit K. Trivedi Best Paper Award, ISU<\/li>\r\n<li>2014: Graduate student Hanzheng Guo received Research Excellence Award, ISU<\/li>\r\n<li>2013: Graduate student, Hanzheng Guo, received the Go-For-The-Gold Award at MSE, ISU<\/li>\r\n<li>2013: Graduate student, Cheng Ma, received The Zaffarano Prize for Graduate Student Research, the highest research award at ISU<\/li>\r\n<li>2012:&nbsp;<em>Journal of the American Ceramic Society<\/em> Associate Editor Recognition for outstanding contributions<\/li>\r\n<li>2012: Graduate student, Cheng Ma, received Research Excellence Award, ISU<\/li>\r\n<li>2011:&nbsp;<em>Journal of the American Ceramic Society<\/em> Associate Editor Recognition for outstanding contributions<\/li>\r\n<li>2011: Graduate student Joshua Frederick was the winner of the ISU competition for the Midwestern Association of Graduate Schools Distinguished Master Thesis<\/li>\r\n<li>2011: Graduate student Cheng Ma received MSE Rohit K. Trivedi Best Paper Award, ISU<\/li>\r\n<li>2011: IEEE Senior Member<\/li>\r\n<li>2010:&nbsp;<em>Journal of the American Ceramic Society<\/em> Associate Editor Recognition for outstanding contributions<\/li>\r\n<li>2008: Graduate student Xiaohui Zhao received MSE Rohit K. Trivedi Best Paper Award, ISU<\/li>\r\n<li>2008: ISU Award for Early Achievement in Research, ISU<\/li>\r\n<li>2007: Young Engineering Faculty Research Award, College of Engineering, ISU<\/li>\r\n<li>2007: MSE Excellence in Research Award, Mater. Sci. &amp; Eng., ISU<\/li>\r\n<li>2004: NSF CAREER Award<\/li>\r\n<li>2001: Phi Kappa Phi<\/li>\r\n<\/ul>\r\n<\/div>\r\n<h4 id=\"education-header\" class=\"dir-header\">Education<\/h4>\r\n<div>\r\n<ul>\r\n<li>Ph. D. Materials Science and Engineering, University of Illinois at Urbana-Champaign, 2002<\/li>\r\n<\/ul>\r\n<\/div>\r\n<h4 id=\"interest-header&quot;\" class=\"dir-header\">Interest Areas<\/h4>\r\n<div>\r\n<ul>\r\n<li>Electric field <em>in-situ<\/em> TEM technique<\/li>\r\n<li>Lead-free piezoelectric crystals and ceramics<\/li>\r\n<li>Phase transformation in ferroelectrics<\/li>\r\n<li>Electrocaloric and pyroelectric ceramics<\/li>\r\n<li>Ferroelectric thin films<\/li>\r\n<li>Iron powder fuel<\/li>\r\n<li>Magnetoelectric multiferroic compounds<\/li>\r\n<\/ul>\r\n<\/div>","middle_name":"","isu_office":"2220bh Hoover $ 528 Bissell Rd. # Ames, IA 500111096","uid":[],"hide_isu_office":"0","lastname":"Tan","publications":"<p><strong>*=Corresponding Author<\/strong><\/p>\r\n<ul>\r\n<li>173. <span style=\"font-size: 12.0pt; font-family: 'Arial',sans-serif; mso-fareast-font-family: 'Times New Roman'; mso-font-kerning: 0pt; mso-ligatures: none; mso-ansi-language: EN-US; mso-fareast-language: EN-US; mso-bidi-language: AR-SA;\">O. Taylor, A. Hoyt, and <strong>X. Tan<a name=\"_Hlk180751452\"><\/a>*<\/strong>. Aliovalent substitution of Pb with (Li<sub>1\/2<\/sub>Bi<sub>1\/2<\/sub>) in PbZrO<sub>3<\/sub> model system. <strong><em>Journal of the American Ceramic Society<\/em><\/strong> 108 (8), e20520 (2025). DOI: 10.1111\/jace.20520<\/span>. <span style=\"font-size: 11.0pt; font-family: 'Times New Roman',serif; mso-fareast-font-family: 'Times New Roman'; mso-font-kerning: 0pt; mso-ligatures: none; mso-ansi-language: EN-US; mso-fareast-language: EN-US; mso-bidi-language: AR-SA;\">&nbsp;<\/span><\/li>\r\n<li>172.&nbsp;<span style=\"font-size: 12.0pt; font-family: 'Arial',sans-serif; mso-fareast-font-family: 'Times New Roman'; mso-font-kerning: 0pt; mso-ligatures: none; mso-ansi-language: EN-US; mso-fareast-language: EN-US; mso-bidi-language: AR-SA;\">Y. Son, S. Udovenko, A. Gaur, J. Cui, <strong>X. Tan<\/strong>, S. Trolier-McKinstry. PbZrO<sub>3<\/sub>-based thin film capacitors with high energy storage efficiency. <strong><em>Applied Physics Letters<\/em><\/strong> 125, 212905\/1-5 (2024). DOI: 10.1063\/5.0237948.<\/span><\/li>\r\n<li>171.&nbsp;<span style=\"font-family: arial, helvetica, sans-serif; font-size: 12pt;\">O. Taylor, E. Chaffee, X.C. Tian, C. Zhao, L. Zhou, and <strong>X. Tan*<\/strong>, &ldquo;CaTiO<sub>3<\/sub>-rich precipitates and their impacts on ferroelectric domains during heating in (Ba,Ca)TiO<sub>3<\/sub> ceramics.&rdquo; <strong><em>Journal of Materials Science: Materials in Electronics<\/em><\/strong> 35, 1808\/1-9 (2024). DOI: 10.1007\/s10854-024-13530-3.<\/span><\/li>\r\n<li>170.&nbsp;<span style=\"font-family: arial, helvetica, sans-serif; font-size: 12pt;\">O. Taylor, E. Chaffee, B.Z. Liu, C. Zhao, J. R&ouml;del, L. Zhou, and <strong>X. Tan*<\/strong>, &ldquo;Electric field response of ferroelectric domains near non-polar precipitates in BaTiO<sub>3<\/sub>-based ceramics.&rdquo; <strong><em>Applied Physics Letters<\/em><\/strong> 124, 212904\/1-5 (2024). DOI: 10.1063\/5.0211248.<\/span><\/li>\r\n<li>169.&nbsp;<span style=\"font-family: arial, helvetica, sans-serif; font-size: 12pt;\">A. Gaur, R. Choudhary, B.Z. Liu, Y. Mudryk, D. Johnson, J. Cui, and <strong>X. Tan*<\/strong>, &ldquo;Antiferroelectric ceramics for energy-efficient capacitors by theory-guided discovery.&rdquo; <strong><em>Advanced Materials<\/em><\/strong> 36, 2312856\/1-8 (2024). DOI: 10.1002\/adma.202312856.<\/span><\/li>\r\n<li>168.&nbsp;<span style=\"font-family: arial, helvetica, sans-serif; font-size: 12pt;\">B.Z. Liu, A.P. Gaur, J. Cui, and <strong>X. Tan*<\/strong>, &ldquo;Substitution of Pb with <a name=\"_Hlk142071965\"><\/a>(Li<sub>1\/2<\/sub>Bi<sub>1\/2<\/sub>) in PbZrO<sub>3<\/sub>-based antiferroelectric ceramics.&rdquo; <strong><em>Journal of Advanced Dielectrics<\/em><\/strong> 14, 2350022\/1-8 (2024). DOI: 10.1142\/S2010135X23500224.<\/span><\/li>\r\n<li>167.&nbsp;<span style=\"font-family: arial, helvetica, sans-serif; font-size: 12pt;\">D. Hu, Z.M. Fan, W. Sawyer, M. Henderson, D. Luo, X.M. Liu, H. Gu, <strong>X. Tan*<\/strong>, J. Wen, &ldquo;Hierarchical domain structures associated with oxygen octahedra tilting patterns in lead-free (Bi<sub>1\/2<\/sub>Na<sub>1\/2<\/sub>)TiO<sub>3<\/sub>.&rdquo; <strong><em>Nanotechnology<\/em><\/strong> 34, 075702\/1-9 (2023). DOI: 10.1088\/1361-6528\/aca030.<\/span><\/li>\r\n<li>166.&nbsp;<span style=\"font-size: 12pt; font-family: arial, helvetica, sans-serif;\">F.P. Zhuo, X. Zhou, S. Gao, M. H&ouml;fling, F. Dietrich, P.B. Groszewicz, L. Fulanovi\u0107, P. Breckner, A. Wohninsland, B.X. Xu, H.J. Kleebe, <strong>X. Tan<\/strong>, J. Koruza, D. Damjanovic, and J. R&ouml;del, &ldquo;Anisotropic dislocation-domain wall interactions in ferroelectrics.&rdquo; <strong><em>Nature Communications<\/em><\/strong> 13, 6676\/1-11 (2022). DOI: 10.1038\/s41467-022-34304-7.<\/span><\/li>\r\n<li>165.&nbsp;<span style=\"font-size: 12pt; font-family: arial, helvetica, sans-serif;\">C.H. Zhao, S. Gao, H.J. Kleebe, <strong>X. Tan<\/strong>, J. Koruza, and J. R&ouml;del, &ldquo;Coherent precipitates with strong domain wall pinning in alkaline niobate ferroelectrics.&rdquo; <strong><em>Advanced Materials<\/em><\/strong> 34, 2202379\/1-12 (2022). DOI: 10.1002\/adma.202202379.<\/span><\/li>\r\n<li>164.&nbsp;<span style=\"font-family: arial, helvetica, sans-serif; font-size: 12pt;\">B.Z. Liu, L. Li, S.T. Zhang, L. Zhou, and <strong>X. Tan*<\/strong>, &ldquo;<em>In situ<\/em> TEM observation on the ferroelectric-antiferroelectric transition in Pb(Nb,Zr,Sn,Ti)O<sub>3<\/sub>\/ZnO.&rdquo; <strong><em>Journal of the American Ceramic Society<\/em><\/strong> 105, 794-800 (2022). DOI: 10.1111\/jace.18148.<\/span><\/li>\r\n<li>163.&nbsp;<span style=\"font-family: arial, helvetica, sans-serif; font-size: 12pt;\">P. Mohapatra, D.D. Johnson, J. Cui, and <strong>X. Tan*<\/strong>, &ldquo;Effect of electric hysteresis on fatigue behavior in antiferroelectric bulk ceramics under bipolar loading.&rdquo; <strong><em>Journal of Materials Chemistry C<\/em><\/strong> 9, 15542-15551 (2021). DOI: 10.1039\/d1tc03520g.<\/span><\/li>\r\n<li>162.&nbsp;<span style=\"font-size: 12pt; font-family: arial, helvetica, sans-serif;\">C. Zhao, S. Gao, T. Yang, M. Scherer, J. Schulthei&szlig;, D. Meier, <strong>X. Tan<\/strong>, H.J. Kleebe, L.Q. Chen, J. Koruza, and J. R&ouml;del, &ldquo;Precipitation hardening in ferroelectrics ceramics.&rdquo; <strong><em>Advanced Materials<\/em><\/strong> 33, 2102421\/1-10 (2021). DOI: 10.1002\/adma.202102421.<\/span><\/li>\r\n<li>161.&nbsp;<span style=\"font-size: 12pt; font-family: arial, helvetica, sans-serif;\">M. H&ouml;fling, X. Zhou, E. Bruder, B. Liu, L. Zhou, L. Riemer, P. Groszewicz, B. Xu, K. Durst, <strong>X. Tan<\/strong>, D. Damjanovic, J. Koruza, and J. R&ouml;del, &ldquo;Control of polarization in bulk ferroelectrics by mechanical dislocation imprint.&rdquo; <strong><em>Science<\/em><\/strong> 372, 961-964 (2021). DOI: 10.1126\/science.abe3810.<\/span><\/li>\r\n<li>160.&nbsp;<span style=\"font-family: arial, helvetica, sans-serif; font-size: 12pt;\">B.Z. Liu and <strong>X. Tan*<\/strong>, &ldquo;Structure, ferroelectric and dielectric properties of (Na<sub>1-2x<\/sub>Ca<sub>x<\/sub>)NbO<sub>3<\/sub> ceramics.&rdquo; <strong><em>Journal of Materials Research<\/em><\/strong> 36, 1076-1085 (2021). DOI: 10.1557\/s43578-020-00020-5.<\/span><\/li>\r\n<li>159.&nbsp;<span style=\"font-family: arial, helvetica, sans-serif; font-size: 12pt;\">X.C. Tian, G. Caruntu, B. Kavey, and <strong>X. Tan*<\/strong>, &ldquo;<em>In-situ<\/em> TEM measurement of electrical properties of individual BaTiO<sub>3<\/sub> nanocubes.&rdquo; <strong><em>Applied Physics Letters<\/em><\/strong> 118, 192901\/1-5 (2021). DOI: 10.1063\/5.0049477.<\/span><\/li>\r\n<li>158.&nbsp;<span style=\"font-family: arial, helvetica, sans-serif; font-size: 12pt;\">X.C. Tian, G. Brennecka, and <strong>X. Tan*<\/strong>, &ldquo;Structural instability in electrically stressed, oxygen deficient BaTiO<sub>3<\/sub> nanocrystals.&rdquo; <strong><em>Advanced Functional Materials<\/em><\/strong> 30, 2004607\/1-9 (2020). DOI: 10.1002\/adfm.202004607.<\/span><\/li>\r\n<li>157.&nbsp;<span style=\"font-family: arial, helvetica, sans-serif; font-size: 12pt;\">B.Z. Liu, X.C. Tian, L. Zhou, and <\/span><strong>X. Tan*<\/strong><span style=\"font-family: arial, helvetica, sans-serif; font-size: 12pt;\">, &ldquo;Motion of phase boundary during the antiferroelectric-ferroelectric transition in a PbZrO<sub>3<\/sub>-based ceramic.&rdquo; <strong><em>Physical Review Materials<\/em><\/strong> 4, 104417\/1-9 (2020). DOI: 10.1103\/PhysRevMaterials.4.104417.<\/span><\/li>\r\n<li>156. X.C. Tian, S. Yazdanparast, G. Brennecka, and <strong>X. Tan*<\/strong>, &ldquo;<em>In situ<\/em> TEM study of dielectric breakdown in copper oxides.&rdquo; <strong><em>IEEE Transactions on Devices and Materials Reliability<\/em><\/strong> 20, 609-612 (2020). DOI: 10.1109\/TDMR.2020.3015398.<\/li>\r\n<li>155. X.C. Tian, G. Brennecka, and <strong>X. Tan*<\/strong>, &ldquo;Direct observations of dielectric breakdown in TiO<sub>2<\/sub> single nanocrystals.&rdquo; <strong><em>ACS Nano<\/em><\/strong> 14, 8328-8334 (2020). DOI: 10.1021\/acsnano.0c02346.<\/li>\r\n<li>154. D. Wang, Z.M. Fan, G. Rao, G. Wang, Y. Liu, C. Yuan, T. Ma, D. Li, <strong>X. Tan<\/strong>, Z. Lu, A. Feteira, S. Liu, C. Zhou, S.J. Zhang, &ldquo;Ultrahigh piezoelectricity in lead-free piezoceramics by synergistic design.&rdquo; <strong><em>Nano Energy<\/em><\/strong> 76, 104944\/1-9 (2020). DOI: 10.1016\/j.nanoen.2020.104944.<\/li>\r\n<li>153. Z.M. Fan, T. Ma, J. Wei, T.Q. Yang, L. Zhou, and <strong>X. Tan*<\/strong>, &ldquo;TEM investigation of the domain structure in PbHfO3 and PbZrO3 antiferroelectric perovskites.&rdquo; <em><strong>Journal of Materials Science<\/strong><\/em> 55, 4953-4961 (2020). DOI: 10.1007\/s10853-020-04361-8.<\/li>\r\n<li>152. Z.M. Fan, S.J. Zhang, and <strong>X. Tan*<\/strong>, &ldquo;Phase-composition dependent domain responses in (K0.5Na0.5)NbO3-based piezoceramics.&rdquo; <em><strong>Journal of the European Ceramic Society<\/strong><\/em> 40, 1217-1222 (2020). DOI: 10.1016\/j.jeurceramsoc.2019.11.046.<\/li>\r\n<li>151. Z.M. Fan and <strong>X. Tan*<\/strong>, &ldquo;A comparative study of the polarization degradation mechanisms during electric cycling in (Bi1\/2Na1\/2)TiO3-based relaxors.&rdquo; <em><strong>Scripta Materialia<\/strong><\/em> 178, 334-338 (2020). DOI: 10.1016\/j.scriptamat.2019.11.061.<\/li>\r\n<li>150. H. Liu, L.L. Fan, S.D. Sun, K. Lin, Y. Ren, <strong>X. Tan<\/strong>, X. Xing, and J. Chen, &ldquo;Electric-field-induced structure and domain texture evolution in PbZrO3-based antiferroelectric by in-situ high-energy synchrotron X-ray diffraction.&rdquo; <em><strong>Acta Materialia<\/strong><\/em> 184, 41-49 (2020). DOI: 10.1016\/j.actamat.2019.11.050.<\/li>\r\n<li>149. X.C. Tian, C. Cook, W. Hong, T. Ma, G. Brennecka, and <strong>X. Tan*<\/strong>, &ldquo;In situ TEM study of the amorphous-to-crystalline transition during dielectric breakdown in TiO2 film.&rdquo; <em><strong>ACS Applied Materials &amp; Interfaces<\/strong><\/em> 11, 40726-40733 (2019). DOI: 10.1021\/acsami.9b08146.<\/li>\r\n<li>148. C.H. Hong, H.Z. Guo, <strong>X. Tan<\/strong>, J.E. Daniels, and W. Jo, &ldquo;Polarization reversal via a transient relaxor state in nonergodic relaxors near freezing temperature.&rdquo; <em><strong>Journal of Materiomics<\/strong><\/em> 5, 634-640 (2019). DOI: 10.1016\/j.jmat.2019.06.004.<\/li>\r\n<li>147. T. Ma, Z.M. Fan, B. Xu, T.H. Kim, P. Lu, L. Bellaiche, M.J. Kramer, <strong>X. Tan*<\/strong>, and L. Zhou, &ldquo;Uncompensated polarization in incommensurate modulations of perovskite antiferroelectrics.&rdquo; <em><strong>Physical Review Letters<\/strong> <\/em>123, 217602 (2019). DOI: 10.1103\/PhysRevLett.123.217602.<\/li>\r\n<li>146. T. Ma, Z.M. Fan, <strong>X. Tan<\/strong>, and L. Zhou, &ldquo;Atomically resolved domain boundary structure in PbZrO3-based antiferroelectric ceramics.&rdquo; <em><strong>Applied Physics Letters<\/strong><\/em> 115, 122902 (2019). DOI: 10.1063\/1.5115039.<\/li>\r\n<li>145. P. Mohapatra, Z.M. Fan, J. Cui, and <strong>X. Tan*<\/strong>, &ldquo;Relaxor antiferroelectrics with ultrahigh efficiency for energy storage applications.&rdquo; <em><strong>Journal of the European Ceramic Society<\/strong><\/em> 39, 4735-4742 (2019). DOI: 10.1016\/j.jeurceramsoc.2019.07.050.<\/li>\r\n<li>144. Y. Yousry, K. Yao, <strong>X. Tan<\/strong>, A.M. Moahmed, Y. Wang, S. Chen, and S. Ramakrishna, &ldquo;Structure and high-performance of lead-free (K0.5Na0.5)NbO3 piezoelectric nanofibers with surface-induced crystallization at lowered temperature.&rdquo; <em><strong>ACS Applied Materials &amp; Interfaces<\/strong><\/em> 11, 23503-23511 (2019). DOI: 10.1021\/acsami.9b05898.<\/li>\r\n<li>143. G. Wang, Z.M. Fan, S. Murakami, Z. Lu, D.A. Hall, D.C. Sinclair, A. Feteira, <strong>X. Tan<\/strong>, J.L. Jones, A. Kleppe, D. Wang, and I.M. Reaney, &ldquo;Origin of the large electrostrain in BiFeO3&ndash;BaTiO3 based lead-free ceramics.&rdquo; <em><strong>Journal of Materials Chemistry<\/strong><\/em> A 7, 21254-21263 (2019). DOI: 10.1039\/c9ta07904a.<\/li>\r\n<li>142. X.C. Tian, T. Ma, L. Zhou, G. Brennecka, and <strong>X. Tan*<\/strong>, &ldquo;In situ TEM study of the transitions between crystalline Si and nonstoichiometric amorphous oxide under bipolar voltage bias.&rdquo; <em><strong>Journal of Applied Physics<\/strong> <\/em>125, 245304 (2019). DOI: 10.1063\/1.5100310.<\/li>\r\n<li>141. Z.M. Fan, F. Xue, G. Tutuncu, L.Q. Chen, <strong>X. Tan*<\/strong>, &ldquo;Interaction dynamics between ferroelectric and antiferroelectric domains in a PbZrO3-based ceramic.&rdquo; <em><strong>Physical Review Applied<\/strong><\/em> 11, 064050 (2019). DOI: 10.1103\/PhysRevApplied.11.064050.<\/li>\r\n<li>140. Z.M. Fan and <strong>X. Tan<\/strong>*, &ldquo;Dual-stimuli in-situ TEM study on the nonergodic\/ergodic crossover in the 0.75(Bi1\/2Na1\/2)TiO3&ndash;0.25SrTiO3 relaxor.&rdquo; <em><strong>Applied Physics Letters<\/strong><\/em> 114, 212901 (2019). DOI: 10.1063\/1.5093510. Cover graphics article of May 27 issue, 2019.<\/li>\r\n<li>139. M.M. Vopson, <strong>X. Tan<\/strong>, E. Namvar, M. Belusky, S.P. Thompson, V. Kuncser, F. Plazaola, I. Unzueta, and C.C. Tang, &ldquo;Sub-lattice polarization states in antiferroelectrics and their relaxation process.&rdquo; <em><strong>Current Applied Physics<\/strong><\/em> 19, 651-656 (2019). DOI: 10.1016\/j.cap.2019.03.009.<\/li>\r\n<li>138. Z.M. Fan, L. Zhou, T.H. Kim, J. Zhang, S.T. Zhang, and <strong>X. Tan<\/strong>*, &ldquo;Mechanisms of enhanced thermal stability of polarization in lead-free (Bi1\/2Na1\/2)0.94Ba0.06TiO3\/ZnO ceramic composites,&rdquo; <em><strong>Physical Review Materials<\/strong><\/em> 3, 024402\/1-10 (2019). DOI: 10.1103\/PhysRevMaterials.3.024402.<\/li>\r\n<li>137. G. Wang, J. Li, X. Zhang, Z.M. Fan, F. Yang, A. Feteira, D. Zhou, D.C. Sinclair, T. Ma, <strong>X. Tan<\/strong>, D. Wang, and I.M. Reaney, &ldquo;Ultrahigh energy storage density lead-free multilayers by controlled electrical homogeneity,&rdquo; <em><strong>Energy &amp; Environmental Science<\/strong><\/em>, published online, 2019. DOI: 10.1039\/c8ee03287d.<\/li>\r\n<li>136. C.H. Hong, Z.M. Fan, <strong>X. Tan<\/strong>, C.W. Ahn, Y. Shin, and W. Jo, &ldquo;Role of sodium deficiency on the relaxor properties of Bi1\/2Na1\/2TiO3&ndash;BaTiO3,&rdquo; <em><strong>Journal of the European Ceramic Society<\/strong><\/em> 38, 5375-5381 (2018). DOI: 10.1016\/j.jeurceramsoc.2018.08.006.<\/li>\r\n<li>135. D. Wang, Z.M. Fan, W. Li, D. Zhou, A. Feteira, G. Wang, S. Murakami, S. Sun, Q. Zhao, <strong>X. Tan<\/strong>, and I.M. Reaney, &ldquo;High energy storage density and large strain in Bi(Zn2\/3Nb1\/3)O3-doped BiFeO3&ndash;BaTiO3 ceramics,&rdquo; <em><strong>ACS Applied Energy Materials<\/strong><\/em> 1, 4403-4412 (2018). DOI: 10.1021\/acsaem.8b01099.<\/li>\r\n<li>134. S. Murakami, D. Wang, A. Mostaed, A. Khesro, A. Feteira, D.C. Sinclair, Z.M. Fan, <strong>X. Tan<\/strong>, and I.M. Reaney, &ldquo;High strain (0.4%) Bi(Mg2\/3Nb1\/3)O3&ndash;BaTiO3&ndash;BiFeO3 lead-free piezoelectric ceramics and multilayers,&rdquo; <strong><em>Journal of the American Ceramic Society<\/em><\/strong> 101, 5428-5442 (2018). DOI: 10.1111\/jace.15749.<\/li>\r\n<li>133. A. Patterson, H. Nagata, <strong>X. Tan<\/strong>, J.E. Daniels, M. Hinterstein, R. Ranjan, P. Groszewicz, W. Jo, and J.L. Jones, &ldquo;Relaxor-ferroelectric transitions: sodium bismuth titanate derivatives,&rdquo; <em><strong>MRS Bulletin<\/strong><\/em> 43, 600-606 (2018). DOI: https:\/\/doi.org\/10.1557\/mrs.2018.156.<\/li>\r\n<li>132. S. Trolier-McKinstry, S.J. Zhang, A.J. Bell, and <strong>X. Tan<\/strong>, &ldquo;High-performance piezoelectric crystals, ceramics and films,&rdquo; <strong><em>Annual Reviews of Materials Research<\/em><\/strong> 48, (2018). DOI: 10.1146\/annurev-matsci-070616-124023.<\/li>\r\n<li>131. Z.M. Fan and <strong>X. Tan<\/strong>*, &ldquo;<em>In-situ<\/em> TEM study of the aging micromechanisms in a BaTiO3-based lead-free piezoelectric ceramic,&rdquo; <strong><em>Journal of the European Ceramic Society<\/em><\/strong> 38, 3472-3477 (2018). DOI: 10.1016\/j.jeurceramsoc.2018.03.049.<\/li>\r\n<li>130. Z.M. Fan, J. Koruza, J. R&ouml;del, and <strong>X. Tan*<\/strong>, &ldquo;An ideal amplitude window against electric fatigue in BaTiO3-based lead-free piezoelectric materials,&rdquo; <strong><em>Acta Materialia<\/em><\/strong> 151, 253-259 (2018). DOI: 10.1016\/j.actamat.2018.03.067<\/li>\r\n<li>129. D. Wang, Z.M. Fan, D. Zhou, A. Khesro, S. Murakami, A. Feteira, Q. Zhao, <strong>X. Tan<\/strong>, and I.M. Reaney, &ldquo;Bismuth ferrite-based lead-free ceramics and multilayers with high recoverable energy density,&rdquo; <strong><em>Journal of Materials Chemistry A<\/em><\/strong> 6, 4133-4144 (2018). DOI: 10.1039\/c7ta09857j.<\/li>\r\n<li>128. N. Novak, F. Weyland, S. Patel, H. Guo, <strong>X. Tan<\/strong>, J. R&ouml;del, and J. Koruza, &ldquo;Interplay of conventional with inverse electrocaloric response in (Pb,Nb)(Zr,Sn,Ti)O3 antiferroelectric materials,&rdquo; <strong><em>Physical Review B<\/em><\/strong> 97, 094113 (2018). DOI: 10.1103\/PhysRevB.97.094113.<\/li>\r\n<li>127. S. Patel, F. Weyland, <strong>X. Tan<\/strong>, and N. Novak, &ldquo;Tunable pyroelectricity around the ferroelectric\/antiferroelectric transition,&rdquo; <strong><em>Energy Technology<\/em><\/strong>, online 2017. DOI: 10.1002\/ente.201700411.<\/li>\r\n<li>126. <strong>X. Tan<\/strong>*, Z.P. Xu, X.M. Liu, and Z.M. Fan, &ldquo;Double hysteresis loops at room temperature in NaNbO3-based lead-free antiferroelectric ceramics,&rdquo; <strong><em>Materials Research Letters<\/em><\/strong> <strong>6<\/strong>, 159-164 (2018). DOI: 10.1080\/21663831.2017.1419994.<\/li>\r\n<li>125. Z.M. Fan, C. Zhou, X.B. Ren, and <strong>X. Tan<\/strong>*, &ldquo;Domain disruption and defect accumulation during unipolar electric fatigue in a BZT-BCT ceramic,&rdquo; <strong><em>Applied Physics Letters<\/em><\/strong> <strong>111<\/strong>, 252902 (2017). DOI: 10.1063\/1.5008619.<\/li>\r\n<li>124. M.M. Vopson and <strong>X. Tan<\/strong>, &ldquo;Nonequilibrium polarization dynamics in antiferroelectrics,&rdquo; <strong><em>Physical Review B<\/em><\/strong> <strong>96<\/strong>, 014104 (2017). DOI: 10.1103\/PhysRevB.96.014104.<\/li>\r\n<li>123. Z.M. Fan, X.M. Liu, and <strong>X. Tan<\/strong>*, &ldquo;Large electrocaloric responses in [Bi1\/2(Na,K)1\/2]TiO3-based ceramics with giant electro-strains,&rdquo; <strong><em>Journal of the American Ceramic Society<\/em> 100<\/strong>, 2088-2097 (2017). DOI: 10.1111\/jace.14777.<\/li>\r\n<li>122. T.Y. Li, X.J. Lou, X.Q. Ke, S.D. Cheng, S.B. Mi, X.J. Wang, J. Shi, X. Liu, G.Z. Dong, H.Q. Fan, Y.Z. Wang, and <strong>X. Tan<\/strong>, &ldquo;Giant strain with low hysteresis in A-site-deficient (Bi0.5Na0.5)TiO3-based lead-free piezoceramics,&rdquo; <strong><em>Acta Materialia<\/em><\/strong> <strong>128<\/strong>, 337-344 (2017). DOI: 10.1016\/j.actamat.2017.02.037.<\/li>\r\n<li>121. Z.P. Xu, Z.M. Fan, X.M. Liu, and <strong>X. Tan<\/strong>*, &ldquo;Impact of phase transition sequence on the electrocaloric effect in Pb(Nb,Zr,Sn,Ti)O3 ceramics,&rdquo; <strong><em>Applied Physics Letters<\/em><\/strong> <strong>110,<\/strong> 082901\/1-4 (2017). DOI: 10.1063\/1.4976827.<\/li>\r\n<li>120. M.M. Vopson, G. Caruntu, and <strong>X. Tan<\/strong>, &ldquo;Polarization reversal and memory effect in anti-ferroelectric materials,&rdquo; <strong><em>Scripta Materialia<\/em><\/strong> <strong>128<\/strong>, 61-64 (2017). DOI: 10.1016\/j.scriptamat.2016.10.004.<\/li>\r\n<li>119. M.M. Vopson and <strong>X. Tan<\/strong>, &ldquo;Four-state anti-ferroelectric random access memory,&rdquo; <strong><em>IEEE Electron Device Letters<\/em><\/strong>, 37, 1551-1554 (2016). DOI: 10.1109\/LED.2016.2614841.<\/li>\r\n<li>118. X.M. Liu and <strong>X. Tan*<\/strong>, &ldquo;Giant strain with low cycling degradation in Ta-doped [Bi1\/2(Na0.8K0.2)1\/2]TiO3 lead-free ceramics,&rdquo; <strong><em>Journal of<\/em><\/strong> <strong><em>Applied Physics<\/em><\/strong> <strong>120<\/strong>, 034102 (2016). DOI: 10.1063\/1.4958853.<\/li>\r\n<li>117. H.Z. Guo, X.M. Liu, F. Xue, L.Q. Chen, W. Hong, and <strong>X. Tan<\/strong>*, &ldquo;Disrupting long-range polar order with an electric field,&rdquo;<strong> <em>Physical Review B<\/em><\/strong> 93, 174114\/1-9 (2016). DOI: 10.1103\/PhysRevB.93.174114.<\/li>\r\n<li>116. X.M. Liu and <strong>X. Tan<\/strong>*, &ldquo;Giant strains in non-textured (Bi1\/2Na1\/2)TiO3-based lead-free ceramics,&rdquo; <strong><em>Advanced Materials<\/em><\/strong> 28, 574-578 (2016). DOI: 10.1002\/adma.201503768.<\/li>\r\n<li>115. W.X. Sun, H.C. Wu,&nbsp;<strong>X. Tan<\/strong>, M.R. Kessler, and N. Bowler, \"Silanized-silicon\/epoxy nanocomposites for structural capacitors with enhanced electrical energy storage capability,\"&nbsp;<em><strong>Composites Science and Technology <\/strong><\/em><strong>121<\/strong>, 34-40 (2015). DOI:&nbsp;10.1016\/j.compscitech.2015.10.022.<\/li>\r\n<li>114. X.M. Liu, and&nbsp;<strong>X. Tan*<\/strong>, \"Suppression of the antiferroelectric phase during polarization cycling of an induced ferroelectric phase,\"&nbsp;<em><strong>Applied Physics Letters&nbsp;<\/strong><\/em><strong>107<\/strong>,&nbsp;072908 (2015). DOI: 10.1063\/1.4929322.<\/li>\r\n<li>113. M. Zakhozheva, L.A. Schmitt, M. Acosta, H.Z. Guo, W. Jo, R. Schierholz, H-J Kleebe, and&nbsp;<strong>X. Tan<\/strong>, \"Wide compositional range <em>in situ<\/em> electric field investigations on lead-free &nbsp;Ba(Zr0.2Ti0.8)O3-<em>x<\/em>(Ba0.7Ca0.3)TiO3 piezoceramic,\"&nbsp;<em><strong>Physical Review Applied&nbsp;<\/strong><\/em><strong>3<\/strong>,&nbsp;064018 (2015). DOI: 10.1103\/PhysRevApplied.3.064018.<\/li>\r\n<li>112. H.Z. Guo and&nbsp;<strong>X. Tan*<\/strong>, \"Direct observation of the recovery of an antiferroelectric phase during polarization reversal of an induced ferroelectric phase,\"<em><strong> Physical Review B<\/strong><\/em> <strong>91<\/strong>, 144101\/1-6 (2015). DOI: 10.1103\/PhysRevB.91.144104.<\/li>\r\n<li>111. H.Z. Guo,&nbsp;<strong>X. Tan*<\/strong>, and S.J. Zhang, \"<em>In situ<\/em> TEM study on the microstructural evolution during electric fatigue in 0.7Pb(Mg1\/3Nb2\/3)O3--0.3PbTiO3 ceramic,\" Focus Issue on In-situ and Operando Characterization of Materials in <strong>Journal of Materials Research<\/strong> 30, 364-372 (2015). DOI: 10.1557\/jmr.2014.228.<\/li>\r\n<li>110. H.Z. Guo, X.M. Liu, J. R&ouml;del, and <strong>X. Tan*<\/strong>, &ldquo;Nanofragmentation of ferroelectric domains during polarization fatigue,&rdquo;<strong> <em>Advanced Functional Materials<\/em><\/strong> 25, 270-277 (2015). DOI: 10.1002\/adfm.201402740.<\/li>\r\n<li>109.&nbsp;B.K. Voas, T.M. Usher, X.M. Liu, S. Li, J.L. Jones, <strong>X. Tan<\/strong>, V.R. Cooper, and S.P. Beckman, &ldquo;Special quasirandom structures to study the (K0.5Na0.5)NbO3 random alloy.&rdquo; <strong><em>Physical Review B<\/em><\/strong> 90, 024105\/1-6 (2014). DOI: 10.1103\/PhysRevB.90.024105.<\/li>\r\n<li>108.&nbsp;H.Z. Guo, B.K. Voas, S.J. Zhang, C. Zhou, X.B. Ren, S.P. Beckman, and <strong>X. Tan*<\/strong>, &ldquo;Polarization alignment, phase transition and piezoelectricity development in polycrystalline 0.5Ba(Zr0.2Ti0.8)O3&ndash;0.5(Ba0.7Ca0.3)TiO3,&rdquo;<strong> <em>Physical Review B<\/em><\/strong> 90, 014103\/1-10 (2014). DOI: 10.1103\/PhysRevB.90.014103.<\/li>\r\n<li>107.&nbsp;X.M. Liu, H.Z. Guo, and <strong>X. Tan*<\/strong>, &ldquo;Evolution of structure and electrical properties with lanthanum content in [(Bi1\/2Na1\/2)0.95Ba0.05]1-<em>x<\/em>La<em>x<\/em>TiO3,&rdquo; <strong><em>Journal of the European&nbsp;Ceramic Society 34, 2997-3006 (2014). DOI: 10.1016\/j.jeurceramsoc.2014.03.017.&nbsp;<\/em><\/strong><\/li>\r\n<li>106. H.Z. Guo, C. Zhou, X.B. Ren, and <strong>X. Tan*<\/strong>, &ldquo;Unique single-domain state in a polycrystalline ferroelectric ceramic,&rdquo;<strong> <em>Physical Review B - Rapid Communications<\/em><\/strong> 89, 100104(R) (2014). DOI: 10.1103\/PhysRevB.89.100104.<\/li>\r\n<li>105. C.S. Daily, W.X. Sun, M.R. Kessler, <strong>X. Tan<\/strong>, and N. Bowler, &ldquo;Modeling the interphase of a polymer-based nanodielectric,&rdquo; <strong><em>IEEE Transactions on Dielectrics and Electrical Insulation<\/em><\/strong> 21, 488-496 (2014).<\/li>\r\n<li>104. Y.H. Xu, W. Hong, Y.J. Feng, and <strong>X. Tan*<\/strong>, &ldquo;Antiferroelectricity induced by electric field in NaNbO3-based lead-free ceramics,&rdquo;<strong> <em>Applied Physics Letters<\/em><\/strong> 104, 052903 (2014). DOI: 10.1063\/1.4863850.<\/li>\r\n<li>103. S.E. Young, H.Z. Guo, C. Ma, M.R. Kessler, and <strong>X. Tan*<\/strong>, &ldquo;Thermal analysis of phase transitions in perovskite electroceramics,&rdquo; <strong><em>Journal of Thermal Analysis and Calorimetry<\/em><\/strong> 115, 587-593 (2014). DOI: 10.1007\/s10973-013-3363-1.<\/li>\r\n<li>102. Y.H. Xu, H.Z. Guo, X.M. Liu, Y.J. Feng, and <strong>X. Tan*<\/strong>, &ldquo;Effect of Ba content on the stress-sensitivity of the antiferroelectric to ferroelectric phase transition in (Pb,La,Ba,)(Zr,Sn,Ti)O3 ceramics,&rdquo;<strong> <em>Journal of the American Ceramic Society<\/em><\/strong> 97, 206-212 (2014). DOI: 10.1111\/jace.12585.<\/li>\r\n<li>101. <strong>X. Tan*<\/strong>, S.E. Young, Y.H. Seo, J.Y. Zhang, W. Hong, and K.G. Webber, &ldquo;Transformation toughening in an antiferroelectric ceramic,&rdquo; <strong><em>Acta Materialia<\/em><\/strong> 62, 114-121 (2014). DOI: 10.1016\/j.actamat.2013.09.038.<\/li>\r\n<li>100. C. Ma*, H.Z. Guo, and <strong>X. Tan*<\/strong>, &ldquo;A new phase boundary in (Bi1\/2Na1\/2)TiO3&ndash;BaTiO3 revealed via a novel method of electron diffraction analysis,&rdquo; <strong><em>Advanced Functional Materials<\/em><\/strong> 23, 5261-5266 (2013). DOI: 10.1002\/adfm.201300640.<\/li>\r\n<li>99. X.M. Liu, and <strong>X. Tan*<\/strong>, &ldquo;Crystal structure and electrical properties of lead-free (1-<em>x<\/em>)BaTiO3&ndash;<em>x<\/em>(Bi1\/2A1\/2)TiO3 (A = Ag, Li, Na, K, Rb, Cs) ceramics,&rdquo; <strong><em>Journal of the American Ceramic Society<\/em><\/strong> 96, 3425-3429 (2013). DOI: 10.1111\/jace.12494.<\/li>\r\n<li>98. <strong>X. Tan*<\/strong>, S.E. Young, Y.H. Seo, J.Y. Zhang, W. Hong, and K.G. Webber, &ldquo;Transformation toughening in an antiferroelectric ceramic,&rdquo; <strong><em>Acta Materialia<\/em><\/strong> 62, 114-121 (2014). DOI: 10.1016\/j.actamat.2013.09.038.<\/li>\r\n<li>97. H.Z. Guo, S.J. Zhang, S.P. Beckman, and <strong>X. Tan*<\/strong>, &ldquo;Microstructural origin for the piezoelectricity evolution in (K0.5Na0.5)NbO3-based lead-free ceramics,&rdquo;<strong> <em>Journal of Applied<\/em> <\/strong><strong><em>Physics<\/em><\/strong> 114, 154102\/1-8 (2013). DOI: 10.1063\/1.4825213.<\/li>\r\n<li>96. X.C. Pang, Y.J. He, B.B. Jiang, J. Iocozzia, L. Zhao, H.Z. Guo, J. Liu, M. Akinc, N. Bowler, <strong>X. Tan<\/strong>, and Zhiqun Lin, &ldquo;Block copolymer\/ferroelectric nanoparticle nanocomposites,&rdquo; <strong><em>Nanoscale<\/em><\/strong> 5, 8695-8702 (2013). DOI: 10.1039\/C3NR03036A.<\/li>\r\n<li>95. Y.G. Yao, Z.M. Sun, Y.C. Ji, Y.D. Yang, <strong>X. Tan<\/strong> and X.B. Ren, &ldquo;Evolution of the tetragonal to rhombohedral transition in (1-<em>x<\/em>)(Bi1\/2Na1\/2)TiO3&ndash;<em>x<\/em>BaTiO3 (<em>x<\/em> &pound; 7%),&rdquo; <strong><em>Science and Technology of Advanced Materials<\/em><\/strong> 14, 035008\/1-8 (2013). DOI: 10.1088\/1468-6996\/14\/3\/035008.<\/li>\r\n<li>94. W.X. Sun, W.Z. Sun, M.R. Kessler, N. Bowler, K.W. Dennis, R.W. McCallum, Q. Li, and <strong>X. Tan*<\/strong>, &ldquo;Multifunctional properties of cyanate ester composites with SiO2 coated Fe3O4 fillers,&rdquo; <strong><em>ACS Applied Materials &amp; Interfaces<\/em><\/strong> 5, 1636-1642 (2013). DOI: 10.1021\/am302520e.<\/li>\r\n<li>93. H.Z. Guo, C. Ma, X.M. Liu, and <strong>X. Tan*<\/strong>, &ldquo;Electrical poling below coercive field for large piezoelectricity,&rdquo; <strong><em>Applied Physics Letters<\/em><\/strong> 102, 092902\/1-4 (2013). DOI: 10.1063\/1.4794866.<\/li>\r\n<li>92. R. Dittmer, K.G. Webber, E. Aulbach, W. Jo, <strong>X. Tan<\/strong>, and J. R&ouml;del, &ldquo;Electric field-induced polarization and strain in 0.94(Bi1\/2Na1\/2)TiO3&ndash;0.06BaTiO3 under uniaxial stress,&rdquo; <strong><em>Acta Materialia<\/em><\/strong> 61, 1350-1358 (2013). DOI: 10.1016\/j.actamat.2012.11.012.<\/li>\r\n<li>91. S.E. Young, J.Y. Zhang, W. Hong, and <strong>X. Tan*<\/strong>, &ldquo;Mechanical self-confinement to enhance energy storage density of antiferroelectric capacitors,&rdquo; <strong><em>Journal of Applied Physics<\/em><\/strong> 113, 054101\/1-6 (2013). DOI: 10.1063\/1.4790135.<\/li>\r\n<li>90. R. Dittmer, K.G. Webber, E. Aulbach, W. Jo, <strong>X. Tan<\/strong>, and J. R&ouml;del, &ldquo;Optimal working regime of lead-zirconate-titanate for actuation applications,&rdquo; <strong><em>Sensors and Actuators A<\/em><\/strong> 189, 187-194 (2013). DOI: 10.1016\/j.sna.2012.09.015.<\/li>\r\n<li>89. J. Liu, N. Bowler, H. Guo, X. Pang, <strong>X. Tan<\/strong>, M. Akinc, and Z. Lin, &ldquo;Dynamics of polystyrene-<em>block<\/em>-poly(methylmethacrylate) (PS-b-PMMA) diblock copolymers and PS\/PMMA blends: A dielectric study,&rdquo; <strong><em>Journal of Non-Crystalline Solids<\/em><\/strong> 359, 27-32 (2013). DOI: 10.1016\/j.jnoncrysol.2012.09.015.<\/li>\r\n<li>88. H.Z. Guo, Ya. Mudryk, M.I. Ahmad, X.C. Pang, L. Zhao, M. Akinc, V.K. Pecharsky, N. Bowler, Z.Q. Lin, and <strong>X. Tan*<\/strong>, &ldquo;Structure evolution and dielectric behavior of polystyrene capped barium titanate nanoparticles,&rdquo; <strong><em>Journal of Materials<\/em> <em>Chemistry<\/em><\/strong> 22, 23944-23951 (2012). DOI: 10.1039\/c2jm35600g.<\/li>\r\n<li>87. C. Ma, H. Guo, S.P. Beckman, and <strong>X. Tan*<\/strong>, &ldquo;Creation and destruction of morphotropic phase boundaries through electrical poling: A case study of lead-free (Bi1\/2Na1\/2)TiO3&ndash;BaTiO3 piezoelectrics,&rdquo; <strong><em>Physical Review Letters<\/em><\/strong> 109, 107602\/1-5 (2012). DOI: 10.1103\/PhysRevLett.109.107602.<\/li>\r\n<li>86. W. Sun, J.E. De Le&oacute;n, C. Ma, <strong>X. Tan*<\/strong>, and M.R. Kessler, &ldquo;Novel Si\/cyanate ester nanocomposites with multifunctional properties,&rdquo; <strong><em>Composites Science and Technology<\/em><\/strong>, 72, 1692-1696 (2012). DOI: 10.1016\/j.compscitech.2012.06.023.<\/li>\r\n<li>85. <strong>X. Tan*<\/strong>, &ldquo;Chapter 14: <em>In situ<\/em> TEM with electrical bias on ferroelectric oxides,&rdquo; in <strong><em>In-Situ Electron Microscopy<\/em><\/strong>, G. Dehm, J. Howe, and J. Zweck, eds. Wiley-VCH, Weinheim, Germany, 2012. ISBN: 978-3-527-31982-4.<\/li>\r\n<li>84. M. Marsilius, J. Frederick, W. Hu, <strong>X. Tan*<\/strong>, T. Granzow, and P. Han, &ldquo;Mechanical confinement: An effective way of tuning properties of piezoelectric crystals,&rdquo; <strong><em>Advanced Functional Materials<\/em><\/strong> 22, 797-802 (2012). DOI: 10.1002\/adfm.201101301.<\/li>\r\n<li>83. T. Sareein, W. Hu, <strong>X. Tan<\/strong>*, and R. Yimnirun, &ldquo;The morphotropic phase boundary in the (1-<em>x<\/em>)PbZrO3&ndash;<em>x<\/em>[0.3Bi(Zn1\/2Ti1\/2)O3&ndash;0.7PbTiO3] perovskite solid solution,&rdquo; <strong><em>Journal of Materials Science<\/em><\/strong> <strong>47<\/strong>, 1774-1779 (2012). DOI 10.1007\/s10853-011-5961-2.<\/li>\r\n<li>82. T. Sareein, P. Baipaywad, W. Chaiammad, A. Ngamjarurojana, S. Ananta, <strong>X. Tan<\/strong>, and R. Yimnirun, &ldquo;Dielectric aging behavior in A-site hybrid-doped BaTiO3 ceramics,&rdquo; <strong><em>Current Applied Physics<\/em><\/strong> <strong>11<\/strong>, S90-S94 (2011). DOI: 10.1016\/j.cap.2011.03.018.<\/li>\r\n<li>81. W. Hu, <strong>X. Tan*<\/strong>, and K. Rajan, &ldquo;Piezoelectric ceramics with compositions at the morphotropic phase boundary in the BiFeO3&ndash;PbZrO3&ndash;PbTiO3 ternary system,&rdquo; <strong><em>Journal of the American Ceramic Society<\/em><\/strong> <strong>94<\/strong>, 4358-4363 (2011). DOI: 10.1111\/j.1551-2916.2011.04715.x.<\/li>\r\n<li>80. <strong>X. Tan<\/strong>*, C. Ma, J. Frederick, S. Beckman, and K. Webber, &ldquo;The antiferroelectric &laquo; ferroelectric phase transition in lead-containing and lead-free perovskite ceramics,&rdquo; invited feature article in the <strong><em>Journal of the American Ceramic Society<\/em><\/strong> <strong>94<\/strong>, 4091-4107 (2011). DOI: 10.1111\/j.1551-2916.2011.04917.x.<\/li>\r\n<li>79. C. Ma, and <strong>X. Tan*<\/strong>, &ldquo;<em>In situ<\/em> transmission electron microscopy study on the phase transitions in lead-free (1-<em>x<\/em>)(Bi1\/2Na1\/2)TiO3&ndash;<em>x<\/em>BaTiO3 ceramics,&rdquo; <strong><em>Journal of the American Ceramic Society<\/em><\/strong> <strong>94<\/strong>, 4040-4044 (2011). DOI: 10.1111\/j.1551-2916.2011.04670.x.<\/li>\r\n<li>78. S.J. Zhang, H.J. Lee, C. Ma, and <strong>X. Tan<\/strong>, &ldquo;Sintering effect on microstructure and properties of (K,Na)NbO3 ceramics,&rdquo; <strong><em>Journal of the American Ceramic Society<\/em><\/strong> <strong>94<\/strong>, 3659-3665 (2011). DOI: 10.1111\/j.1551-2916.2011.04833.x.<\/li>\r\n<li>77. E.A. Stefanescu, <strong>X. Tan<\/strong>, Z. Lin, N. Bowler, and M.R. Kessler, &ldquo;Multifunctional fiberglass-reinforced PMMA-BaTiO3 structural\/dielectric composites,&rdquo; <strong><em>Polymer<\/em><\/strong> <strong>52<\/strong>, 2016-2024 (2011). DOI: 10.1016\/j.polymer.2011.02.050.<\/li>\r\n<li>76. J. Frederick, <strong>X. Tan*<\/strong>, and W. Jo, &ldquo;Strains and polarization during antiferroelectric-ferroelectric phase switching in Pb0.99Nb0.02[(Zr0.57Sn0.43)1-yTiy]0.98O3 ceramics,&rdquo; <strong><em>Journal of the American Ceramic Society<\/em><\/strong> <strong>94<\/strong>, 1149-1155 (2011). DOI: 10.1111\/j.1551-2916.2010.04194.x.<\/li>\r\n<li>75. X. Zhao, and <strong>X. Tan*<\/strong>, &ldquo;Dielectric and ferroelectric properties of&nbsp; (1-<em>x<\/em>)Pb(Mg1\/3Nb2\/3)O3&ndash;<em>x<\/em>PbZrO3 ceramics with cation order,&rdquo; <strong><em>Journal of Advanced Dielectrics<\/em><\/strong> <strong>1<\/strong>, 99-106 (2011). DOI: 10.1142\/S2010135X11000136.<\/li>\r\n<li>74. A.A. Bokov, B.J. Rodriguez, X. Zhao, J.-H. Ko, S. Jesse, X. Long, W. Qu, T.H. Kim, J.D. Budai, A.N. Morozovska, S. Kojima, <strong>X. Tan<\/strong>, S.V. Kalinin, and Z.-G. Ye, &ldquo;Compositional disorder, polar nanoregions and dipole dynamics in Pb(Mg1\/3Nb2\/3)O3-based relaxor ferroelectrics,&rdquo; an invited review article in <strong><em>Zeitschrift fuer Kristallographie<\/em><\/strong> <strong>226<\/strong>, 99-107 (2011). DOI: 10.1524\/zkri.2011.1299.<\/li>\r\n<li>73. W. Hu, <strong>X. Tan*<\/strong>, and K. Rajan, &ldquo;BiFeO3&ndash;PbZrO3&ndash;PbTiO3 ternary system for high Curie temperature piezoceramics,&rdquo; <strong><em>Journal of the European Ceramic Society<\/em><\/strong> <strong>31<\/strong>, 801-807 (2011). DOI:10.1016\/j.jeurceramsoc.2010.11.015<\/li>\r\n<li>72. W. Jo, J.E. Daniels, J.L. Jones, <strong>X. Tan<\/strong>, P.A. Thomas, D. Damjanovic, and J. R&ouml;del, &ldquo;Evolving morphotropic phase boundary in lead-free (Bi1\/2Na1\/2)TiO3-BaTiO3 piezoceramics,&rdquo;<em> Journal of Applied Physics<\/em> 109, 014110 (2011). DOI: 10.1063\/1.3530737.<\/li>\r\n<li>71. <strong>X. Tan*<\/strong>, J. Frederick, C. Ma, W. Jo, and J. R&ouml;del, &ldquo;Can electric field induce an antiferroelectric phase out of a ferroelectric phase?&rdquo;<strong> <em>Physical Review Letters<\/em><\/strong><strong>105<\/strong>, 255702\/1-4 (2010). DOI: 10.1103\/PhysRevLett.105.255702.<\/li>\r\n<li>70. C. Ma, <strong>X. Tan*<\/strong>, E. Dul'kin, and M. Roth, &ldquo;Domain structure&ndash;dielectric property relationship in lead-free (1-<em>x<\/em>)(Bi1\/2Na1\/2)TiO3-<em>x<\/em>BaTiO3 ceramics,&rdquo; <em>Journal of Applied Physics<\/em> <strong>108<\/strong>, 104105\/1-8 (2010). DOI: 10.1063\/1.3514093.<\/li>\r\n<li>69. E.A. Stefanescu, <strong>X. Tan<\/strong>, Z. Lin, N. Bowler, and M.R. Kessler, &ldquo;Multifunctional PMMA-ceramic composites as structural dielectrics,&rdquo; <em>Polymer<\/em> <strong>51<\/strong>, 5823-32 (2010). DOI: 10.1016\/j.polymer.2010.09.025.<\/li>\r\n<li>68. J. Kling, <strong>X. Tan<\/strong>, H.-J. Kleebe, H. Fuess, W. Jo, and J. R&ouml;del, &ldquo;<em>In situ<\/em> transmission electron microscopy of electric field-triggered reversible domain formation in Bi-based lead-free piezoceramics,&rdquo; Rapid Communication in <em>Journal of the American Ceramic Society<\/em> <strong>93<\/strong>, 2452-55 (2010). DOI: 10.1111\/j.1551-2916.2010.03778.x.<\/li>\r\n<li>67. C. Ma, and <strong>X. Tan*<\/strong>, &ldquo;Phase diagram of unpoled lead-free (1-<em>x<\/em>)(Bi1\/2Na1\/2)TiO3-<em>x<\/em>BaTiO3 ceramics,&rdquo; Fast Track Communication in <em>Solid State Communications<\/em> <strong>150<\/strong>, 1497-1500 (2010). DOI: 10.1016\/j.ssc.2010.06.006.<\/li>\r\n<li>66. C. Ma, and <strong>X. Tan*<\/strong>, &ldquo;Morphotropic phase boundary and electrical properties of lead-free (1-<em>x<\/em>)BaTiO3-<em>x<\/em>Bi(Li1\/3Ti2\/3)O3 ceramics,&rdquo; <em>Journal of Applied Physics<\/em> <strong>107<\/strong>, 124108\/1-6 (2010). DOI: 10.1063\/1.3437215.<\/li>\r\n<li>65. W. Hu, <strong>X. Tan*<\/strong>, and K. Rajan, &ldquo;Combinatorial processing libraries for bulk BiFeO3&ndash;PbTiO3 piezoelectric ceramics,&rdquo; <em>Applied Physics A: Materials Science &amp; Processing<\/em> <strong>99<\/strong>, 427-31 (2010). DOI: 10.1007\/s00339-010-5574-7.<\/li>\r\n<li>64. <strong>X. Tan*<\/strong>, J. Frederick, C. Ma, E. Aulbach, M. Marsilius, W. Hong, T. Granzow, W. Jo, and J. R&ouml;del, &ldquo;Electric-field-induced phase transition in mechanically confined antiferroelectric Pb0.99Nb0.02[(Zr0.57Sn0.43)0.94Ti0.06]0.98O3,&rdquo; <em>Physical Review B<\/em> <strong>81<\/strong>, 014103\/1-5 (2010). DOI: 10.1103\/PhysRevB.81.014103.<\/li>\r\n<li>63. E. Dul'kin, E. Mojaev, M. Roth, O. Khamman, and <strong>X. Tan<\/strong>, &ldquo;Acoustic emission and dielectric studies of phase transitions within the morphotropic phase boundary of <em>x<\/em>Pb(Zr1\/2Ti1\/2)O3&ndash;(1-<em>x<\/em>)Pb(Ni1\/3Nb2\/3)O3 relaxor ferroelectrics,&rdquo; <em>Applied Physics Letters<\/em> <strong>95<\/strong>, 252903\/1-3 (2009).<\/li>\r\n<li>62. C. Ma, J.-Q. Yan, K.W. Dennis, R.W. McCallum, and <strong>X. Tan*<\/strong>, &ldquo;Synthesis, thermal stability and magnetic properties of the Lu1&minus;<em>x<\/em>La<em>x<\/em>Mn2O5 solid solution,&rdquo; <em>Journal of Solid State Chemistry<\/em> <strong>182<\/strong>, 3013-3020 (2009).<\/li>\r\n<li>61. <strong>X. Tan<\/strong>*, E. Aulbach, W. Jo, T. Granzow, J. Kling, M. Marsilius, H.J. Kleebe, and J. R&ouml;del, &ldquo;Effect of uniaxial stress on ferroelectric behavior of (Bi1\/2Na1\/2)TiO3-based lead-free piezoelectric ceramics,&rdquo; <em>Journal of Applied Physics<\/em> <strong>106<\/strong>, 044107\/1-7 (2009).<\/li>\r\n<li>60. J. Chen,<strong> X. Tan<\/strong>, W. Jo, and J. R&ouml;del, &ldquo;Temperature dependence of piezoelectric properties of high-Tc Bi(Mg1\/2Ti1\/2)O3-PbTiO3,&rdquo; <em>Journal of Applied Physics<\/em> <strong>106<\/strong>, 034109\/1-7 (2009).<\/li>\r\n<li>59. C. Ma, J.-Q. Yan, K.W. Dennis, A. Llobet, R.W. McCallum, and <strong>X. Tan*<\/strong>, &ldquo;Effect of oxygen content on the magnetic properties of multiferroic YMn2O5+d,&rdquo; <em>Journal of Physics: Condensed Matter<\/em><strong>21<\/strong>, 346002\/1-5 (2009).<\/li>\r\n<li>58. O. Khamman, <strong>X. Tan*<\/strong>, R. Yimnirun, and S. Ananta, &ldquo;Ferroelectric properties of (1-<em>x<\/em>) Bi(Zn1\/2Ti1\/2)O3&minus;<em>x<\/em>PbZrO3 ceramics,&rdquo; <em>Journal of Materials Science<\/em> <strong>44<\/strong>, 4321-4325 (2009).<\/li>\r\n<li>57. F. Chao, N. Bowler, <strong>X. Tan<\/strong>, G. Liang, M.R. Kessler, &ldquo;Influence of absorbed moisture on the properties of BaTiO3\/cyanate ester composites,&rdquo; <em>Composites Part A<\/em> <strong>40<\/strong>, 1266-1271 (2009).<\/li>\r\n<li>56. X. Zhao, W. Qu, <strong>X. Tan*<\/strong>, A.A. Bokov, Z.-G. Ye, &ldquo;Influence of long-range cation order on relaxor properties of <a name=\"OLE_LINK2\"><\/a>doped Pb(Mg1\/3Nb2\/3)O3 ceramics,&rdquo; <em>Physical Review B<\/em> <strong>79<\/strong>, 144101\/1-12 (2009).<\/li>\r\n<li>55. O. Khamman, <strong>X. Tan*<\/strong>, S. Ananta, and R. Yimnirun, &ldquo;The morphotropic phase boundary and electrical properties of (1-<em>x<\/em>)Pb(Zn1\/2W1\/2)O3&minus;<em>x<\/em>Pb(Zr0.5Ti0.5)O3 ceramics,&rdquo; <em>Journal of Materials Science<\/em> <strong>44<\/strong>, 1868-1872 (2009).<\/li>\r\n<li>54. W. Qu, <strong>X. Tan*<\/strong>, and P. Yang, &ldquo;In-situ transmission electron microscopy study on Nb-doped Pb(Zr0.95Ti0.05)O3 ceramics,&rdquo; an invited article for the special issue of <em>In-Situ Electron Microscopy Methods<\/em> in <em>Microscopy Research and Technique<\/em> <strong>72<\/strong>, 216-222 (2009).<\/li>\r\n<li>53. C. Ma, J.-Q. Yan, K.W. Dennis, R.W. McCallum, and <strong>X. Tan*<\/strong>, &ldquo;Size-dependent magnetic properties of high oxygen content YMn2O5 multiferroic nanoparticles,&rdquo; <em>Journal of Applied Physics<\/em> <strong>105<\/strong>, 033908\/1-6 (2009).<\/li>\r\n<li>52. <strong>X. Tan*<\/strong>, W. Jo, T. Granzow, J. Frederick, E. Aulbach, and J. R&ouml;del, &ldquo;Auxetic behavior under electrical loads in an induced ferroelectric phase,&rdquo; <em>Applied Physics Letters<\/em> <strong>94<\/strong>, 042909\/1-3 (2009).<\/li>\r\n<li>51. W. Qu, <strong>X. Tan*<\/strong>, N. Vittayakorn, S. Wirunchit, and M.F. Besser, &ldquo;High temperature phases in the 0.98PbZrO3&ndash;0.02Pb(Ni1\/3Nb2\/3)O3 ceramic,&rdquo; <em>Journal of Applied Physics,<\/em> <strong>105<\/strong>, 014106\/1-5 (2009).<\/li>\r\n<li>50. X. Zhao, W. Qu, and <strong>X. Tan*<\/strong>, &ldquo;Zr-modified Pb(Mg1\/3Nb2\/3)O3 with long range cation order,&rdquo; <em>Journal of the American Ceramic Society,<\/em> <strong>91<\/strong>, 3031-3038 (2008).<\/li>\r\n<li>49. D.&nbsp;White, X.&nbsp;Zhao, M.&nbsp;F.&nbsp;Besser, and <strong>X.&nbsp;Tan*<\/strong>, &ldquo;Structure and properties of (1- <em>x<\/em>)Pb(Mg1\/2W1\/2)O3&minus;<em>x<\/em>Pb(Zr0.5Ti0.5)O3 solid solution ceramics,&rdquo; <em>Journal of Materials Science<\/em>, <strong>43<\/strong>, 5258-5264 (2008).<\/li>\r\n<li>48. S. Wongsaenmai, S. Ananta, <strong>X. Tan<\/strong>, R. Yimnirun, &ldquo;Dielectric and ferroelectric properties of lead indium niobate ceramic prepared by wolframite method,&rdquo; <em>Ceramics International<\/em>, <strong>34<\/strong>, 723-726 (2008).<\/li>\r\n<li>47. S. Wongsaenmai, <strong>X. Tan<\/strong>, S. Ananta, and R. Yimnirun, &ldquo;Dielectric and ferroelectric properties of fine grains Pb(In1\/2Nb1\/2)O3&ndash;PbTiO3 ceramics,&rdquo; <em>Journal of Alloys and Compounds,<\/em> <strong>454<\/strong>, 331-339 (2008).<\/li>\r\n<li>46. X. Long, A.A. Bokov, Z.-G. Ye, W. Qu, and <strong>X. Tan<\/strong>, &ldquo;Enhanced ordered structure and relaxor behavior of 0.98Pb(Mg1\/3Nb2\/3)O3-0.02La(Mg2\/3Nb1\/3)O3 single crystals,&rdquo; <em>Journal of Physics: Condensed Matter<\/em>, <strong>20<\/strong>, 015210-1-7 (2008).<\/li>\r\n<li>45. <strong>X. Tan*<\/strong>, R. Wongmaneerung, and R.W. McCallum, &ldquo;Ferroelectric and magnetic properties of Pb(Fe2\/3W1\/3)O3-based multiferroic compounds with cation order,&rdquo; <em>Journal of Applied Physics<\/em>, <strong>102<\/strong>, 104114-1-6 (2007).<\/li>\r\n<li>44. W. Qu, X. Zhao, and <strong>X. Tan*<\/strong>, &ldquo;Evolution of nanodomains during the electric field-induced relaxor to normal ferroelectric phase transition in a Sc-doped Pb(Mg1\/3Nb2\/3)O3 ceramic,&rdquo; <em>Journal of Applied Physics<\/em>, <strong>102<\/strong>, 084101-1-8 (2007).<\/li>\r\n<li>43. C.C. Huang, D.P. Cann, <strong>X. Tan<\/strong>, and N. Vittayakorn, &ldquo;Phase transitions and ferroelectric properties in BiScO3-Bi(Zn1\/2Ti1\/2)O3-BaTiO3 solid solutions,&rdquo; <em>Journal of Applied Physics<\/em>, <strong>102<\/strong>, 044103-1-5 (2007).<\/li>\r\n<li>42. S. Wongsaenmai, W. Qu, S. Ananta, R. Yimnirun, and <strong>X. Tan*<\/strong>, &ldquo;Effect of Ba-substitution on the structure and properties of Pb0.8Ba0.2[(In1\/2Nb1\/2)1-<em>x<\/em>Ti<em>x<\/em>]O3,&rdquo; <em>Applied Physics A<\/em>, <strong>88<\/strong>, 757-61 (2007).<\/li>\r\n<li>41. R. Yimnirun, <strong>X. Tan<\/strong>, S. Ananta, and S. Wongsaenmai, &ldquo;Preparation of fine-grain lead indium niobate ceramics with wolframite precursor method and resulting electrical properties,&rdquo; <em>Applied Physics A<\/em>, <strong>88<\/strong>, 323-28 (2007).<\/li>\r\n<li>40. R. Wongmaneerung, <strong>X. Tan*<\/strong>, R.W. McCallum, S. Ananta, and R. Yimnirun, &ldquo;Cation-, dipole-, and spin-order in Pb(Fe2\/3W1\/3)O3-based magnetoelectric multiferroic compounds,&rdquo; <em>Applied Physics Letters<\/em>, <strong>90<\/strong>, 242905 (2007).<\/li>\r\n<li>39. H. He, and <strong>X. Tan*<\/strong>, &ldquo;A comparative study of the structure and properties of Sn-modified lead zirconate titanate ferroelectric and antiferroelectric ceramics,&rdquo; <em>Journal of the American Ceramic Society<\/em>, <strong>90<\/strong>, 2090-94 (2007).<\/li>\r\n<li>38. H. He, and <strong>X. Tan*<\/strong>, Raman spectroscopy study of the phase transitions in Pb0.99Nb0.02[(Zr0.57Sn0.43)1-<em>y<\/em>Ti<em>y<\/em>]0.98O3 ceramics, <em>Journal of Physics: Condensed Matter<\/em>, <strong>19<\/strong>,&nbsp;136003-1-13 (2007).<\/li>\r\n<li>37. X. Zhao, W. Qu, <strong>X. Tan*<\/strong>, A. Bokov and Z.-G. Ye, Electric field-induced phase transitions in (111)-, (110)-, and (100)-oriented Pb(Mg1\/3Nb2\/3)O3 single crystals, <em>Physical Review B<\/em>, <strong>75<\/strong>, 104106-1-12 (2007).<\/li>\r\n<li>36. W. Qu, <strong>X. Tan*<\/strong>, R. W. McCallum, D. P. Cann, and E. Ustundag, Room temperature magnetoelectric multiferroism through cation ordering in complex perovskite solid solutions, <em>Journal of Physics: Condensed Matter<\/em>, <strong>18<\/strong>, 8935-42 (2006).<\/li>\r\n<li>35. W. Qu, X. Zhao, and <strong>X. Tan*<\/strong>, <em>In situ<\/em> transmission electron microscopy study of the nanodomain growth in a Sc-doped lead magnesium niobate ceramic, <em>Applied Physics Letters<\/em>, <strong>89<\/strong>, 022904-1-022904-3 (2006).<\/li>\r\n<li>34. N. Vittaykorn, C. Puchmark, G. Rujijanagul, <strong>X. Tan<\/strong>, D.P. Cann, Piezoelectricproperties of (1-<em>x<\/em>)Pb(Zr1\/2Ti1\/2)O3&ndash;<em>x<\/em>Pb(Zn1\/3Nb2\/3)O3 ceramics prepared by the columbite-(wolframite) precursor method, <em>Current Applied Physics<\/em>, <strong>6<\/strong>, 303-06 (2006).<\/li>\r\n<li>33. N. Vittayakorn, G. Rujijanagul,<strong> X. Tan<\/strong>, H. He, M.A. Marquardt, and D.P. Cann, Dielectric properties and morphotropic phase boundaries in the <em>x<\/em>Pb(Zn1\/3Nb2\/3)O3-(<em>1-x<\/em>) Pb(Zr0.5Ti0.5)O3 pseudo-binary system, <em>Journal of Electroceramics<\/em>, <strong>16<\/strong>, 141-49 (2006).<\/li>\r\n<li>32. X. Zhao, W. Qu, H. He, N. Vittayakorn, and <strong>X. Tan*<\/strong>, &ldquo;Influence of cation order on the electric field-induced phase transition in Pb(Mg1\/3Nb2\/3)O3-based relaxor ferroelectrics,&rdquo; <em>Journal of the American Ceramic Society<\/em> <strong>89<\/strong>, 202-09 (2006).<\/li>\r\n<li>31. W. Qu, and <strong>X. Tan*<\/strong>, &ldquo;Texture control and ferroelectric properties of Pb(Nb,Zr,Sn,Ti)O3 thin films prepared by chemical solution method,&rdquo; <em>Thin Solid Films<\/em> <strong>496<\/strong>, 383-88 (2006).<\/li>\r\n<li>30. S. Aygun, <strong>X. Tan<\/strong>, D.P. Cann, and J.P. Maria, &ldquo;Effects of processing conditions on the dielectric properties of CaCu3Ti4O12,&rdquo; <em>Journal of Electroceramics<\/em> <strong>15<\/strong>, 203-08 (2005).<\/li>\r\n<li>29. M.J. Kramer, D.J. Sordelet, A.F. Bastarows, <strong>X. Tan<\/strong>, and S.B. Biner, &ldquo;Absence of crystallization during cylindrical indentation of a Zr-based metallic glass,&rdquo; <em>Journal of Non-crystalline Solids<\/em> <strong>351<\/strong>, 2159-65 (2005).<\/li>\r\n<li>28. H. He, and <strong>X. Tan*<\/strong>, Electric field-induced transformation of incommensurate modulations in antiferroelectric Pb0.99Nb0.02[(Zr1-xSnx)1-yTiy]0.98O3, <em>Physical Review B<\/em>, <strong>72<\/strong>, 024102-1-10 (2005).<\/li>\r\n<li>27. <strong>X. Tan*<\/strong>, H. He, J.K. Shang, In situ TEM studies of electric field-induced phenomena in ferroelectrics, an invited review in the <em>In situ TEM Focus Issue<\/em> of <em>Journal of Materials Research<\/em>, <strong>20<\/strong>, 1641-53 (2005).<\/li>\r\n<li>26. R.B. Gall, N. Ashmore, M.A. Marquardt, <strong>X. Tan<\/strong>, D.P. Cann, Synthesis, microstructure, and electrical properties of the delafossite compound CuGaO2, <em>Journal of Alloys and Compounds<\/em>, <strong>391<\/strong>, 262-66 (2005).<\/li>\r\n<li>25. N. Vittayakorn, G. Rujijanagul, <strong>X. Tan<\/strong>, M.A. Marquardt, and D.P. Cann, The morphotropic phase boundary and dielectric properties of the xPb(Zr1\/2Ti1\/2)O3 -(1-x)Pb(Ni1\/3Nb2\/3)O3 binary solid solution, <em>Journal of Applied Physics<\/em>, <strong>96<\/strong>, 5103-5109 (2004).<\/li>\r\n<li>24. H. He, and <strong>X. Tan*<\/strong>, <em>In situ<\/em> transmission electron microscopy study of the electric field-induced transformation of incommensurate modulations in a Sn-modified lead zirconate titanate ceramic, <em>Applied Physics Letters<\/em>, <strong>85<\/strong>, 3187-3189 (2004).<\/li>\r\n<li>23. <strong>X. Tan*<\/strong>, and J.K. Shang, Intersection of <em>a<\/em>-domains in the <em>c<\/em>-domain matrix driven by electric field in tetragonal ferroelectric crystal, <em>Journal of Applied Physics<\/em>, <strong>96<\/strong>, 2805-2810 (2004).<\/li>\r\n<li>22. N. Vittayakorn, G. Rujijanagul, T. Tunkasiri, <strong>X. Tan<\/strong>, and D.P. Cann, Influence of processing conditions on the phase transition and ferroelectric properties of the Pb(Zn1\/3Nb2\/3)O3-Pb(Zr1\/2Ti1\/2)O3 ceramics, <em>Materials Science and Engineering: B<\/em>, <strong>108<\/strong>, 258-265 (2004).<\/li>\r\n<li>21. <strong>X. Tan*<\/strong>, and J.K. Shang, Partial dislocations at domain intersections in a tetragonal ferroelectric crystal, <em>Journal of Physics: Condensed Matter<\/em>, <strong>16<\/strong>, 1455-66 (2004).<\/li>\r\n<li>20. <strong>X. Tan*<\/strong>, and J.K. Shang, Field-induced domain interpenetration in tetragonal ferroelectric crystal, <em>Journal of Applied Physics<\/em>, <strong>95<\/strong>, 635-39 (2004).<\/li>\r\n<li>19. N. Vittayakorn, G. Rujijanagul, T. Tunkasiri, <strong>X. Tan<\/strong>, and D.P. Cann, Perovskite phase formation and ferroelectric properties of the PNN-PZN-PZT ternary system, <em>Journal of Materials Research<\/em>, <strong>18<\/strong>, 2882-2889 (2003).<\/li>\r\n<li>18. <strong>X. Tan<\/strong>, T. Du, and J.K. Shang, Piezoelectric in-situ transmission electron microscopy technique for direct observations of fatigue damage accumulation in constrained metallic thin films, <em>Applied Physics Letters<\/em>, <strong>80<\/strong>, 3946-48 (2002).<\/li>\r\n<li>17. <strong>X. Tan<\/strong>, and J.K. Shang, In-situ transmission electron microscopy study of electric-field-induced grain-boundary cracking in lead zirconate titanate, <em>Philosophical Magazine A<\/em>, <strong>82<\/strong>, 1463-78 (2002).<\/li>\r\n<li>16. <strong>X. Tan<\/strong>, Z. Xu, and J.K. Shang, In-situ transmission electron microscopy observations of electric-field-induced domain switching and microcracking in ferroelectric ceramics, <em>Materials Science &amp; Engineering A<\/em>,<strong> A314<\/strong>, 157-61 (2001).<\/li>\r\n<li>15. J.K. Shang, and <strong>X. Tan<\/strong>, Indentation-induced domain switching in Pb(Mg1\/3Nb2\/3)O3-PbTiO3 crystal, <em>Acta Materialia<\/em> <strong>49<\/strong>, 2993-99 (2001).<\/li>\r\n<li>14. J.K. Shang, and <strong>X. Tan<\/strong>, A maximum strain criterion for electric-field-induced fatigue crack propagation in ferroelectric ceramics, <em>Materials Science &amp; Engineering<\/em> <strong>A301<\/strong>, 131-39 (2001).<\/li>\r\n<li>13. <strong>X. Tan<\/strong>, Z. Xu, J.K. Shang, and P. Han, Direct observations of electric field-induced domain boundary cracking in oriented piezoelectric Pb(Mg1\/3Nb2\/3)O3-PbTiO3 single crystal, <em>Applied Physics Letters<\/em>, <strong>77<\/strong>, 1529-31 (2000).<\/li>\r\n<li>12. Z. Xu, <strong>X. Tan<\/strong>, P. Han, and J. K. Shang, In situ transmission electron microscopy study of electric-field-induced microcracking in single crystal 0.66Pb(Mg1\/3Nb2\/3)O3-0.34PbTiO3, <em>Applied Physics Letters<\/em>, <strong>76<\/strong>, 3732-34 (2000).<\/li>\r\n<li>11. <strong>X. Tan<\/strong>, and J.K. Shang, Crack deflection in relaxor ferroelectric PLZT under inclined cyclic electric field, <em>Scripta Materialia<\/em> <strong>43<\/strong>, 925-28 (2000).<\/li>\r\n<li>10.&nbsp;<strong>X. Tan*<\/strong>, N. Munroe, Z. Fathi, and R. Garard, Firing of bauxite extrudates in a variable frequency microwave furnace,&nbsp;<em>Journal of Microwave Power and Electromagnetic Energy&nbsp;<\/em><strong>33<\/strong>, 31-35 (1998).<\/li>\r\n<li>9.&nbsp;<strong>X. Tan*<\/strong>, H. Guo, H. Gu, C. Laird, and N. Munroe, Cyclic deformation behavior of high purity titanium single crystals: II. microstructure and mechanism,&nbsp;<em>Metallurgical and Materials Transactions&nbsp;<\/em><strong>29A<\/strong>, 513-18 (1998).<\/li>\r\n<li>8.&nbsp;<strong>X. Tan*<\/strong>, H. Gu, C. Laird, and N. Munroe, Cyclic deformation behavior of high purity titanium single crystals: I. orientation dependence of stress-strain response,&nbsp;<em>Metallurgical and Materials Transactions&nbsp;<\/em><strong>29A<\/strong>, 507-12 (1998).<\/li>\r\n<li>7. Z. F. Zhang, H. Gu, and&nbsp;<strong>X. Tan<\/strong>, Low-cycle fatigue behavior of commercial-purity titanium,&nbsp;<em>Materials Science and Engineering&nbsp;<\/em><strong>A252<\/strong>, 85-92 (1998).<\/li>\r\n<li>6. Z. F. Zhang, H. Gu, and&nbsp;<strong>X. Tan<\/strong>, Influence of low cycle fatigue on deformation twins in commercial purity titanium,&nbsp;<em>Journal of Materials Science Letters&nbsp;<\/em><strong>17<\/strong>, 211-14 (1998).<\/li>\r\n<li>5.&nbsp;<strong>X. Tan<\/strong>, H. Gu, and N. Munroe, Orientation dependence of slip and twinning in HCP metals,&nbsp;<em>Scripta Materialia&nbsp;<\/em><strong>36<\/strong>, 1383-86 (1997).<\/li>\r\n<li>4.&nbsp;<strong>X. Tan<\/strong>, and H. Gu, Fatigue crack initiation in high purity titanium crystals,<em>International Journal of Fatigue&nbsp;<\/em><strong>18<\/strong>, 329-33 (1996).<\/li>\r\n<li>3.&nbsp;<strong>X. Tan<\/strong>, and H. Gu, Stacking faults in fatigued titanium single crystals,&nbsp;<em>Scripta Metallurgica et Materialia&nbsp;<\/em><strong>33<\/strong>, 1977-80 (1995).<\/li>\r\n<li>2.&nbsp;<strong>X. Tan<\/strong>, H. Gu, and Z. Wang, Cyclic deformation features in high purity titanium bicrystals,&nbsp;<em>Materials Science and Engineering&nbsp;<\/em><strong>A196<\/strong>, 45-52 (1995).<\/li>\r\n<li>1.&nbsp;<strong>X. Tan<\/strong>, H. Gu, S. Zhang, and C. Laird, Loading mode dependence of deformation microstructure in high purity titanium single crystal oriented for difficult glide,&nbsp;<em>Materials Science Engineering&nbsp;<\/em><strong>A189<\/strong>, 77-84 (1994).<\/li>\r\n<\/ul>\r\n<p><strong>Grants and Contracts<\/strong><\/p>\r\n<ul>\r\n<li>PI: Restricting ferroelectric domain wall mortion with volume defects - nanoprecipitates. NSF-DMR, $569,497, 08\/01\/2021&ndash;07\/31\/2025<\/li>\r\n<li>PI: Novel ceramic capacitors with ultrahigh energy density and efficiency. DOE EERE-AMO, $2,494,875, 07\/01\/2020&ndash;06\/30\/2024<\/li>\r\n<li>PI: Dielectrics under extreme electric fields: <em>In situ<\/em> studies on nanoscale mechanisms. DOE-BES, $675,000, 09\/15\/2017&ndash;07\/14\/2020<\/li>\r\n<li>PI: Nanoscale phase transition in free-standing dielectric thin foils. NSF-DMR, $396,171, 07\/01\/2017&ndash;06\/30\/2020<\/li>\r\n<li>PI: AGEP-GRS supplemental funding for &ldquo;Nanoscale insight into electric fatigue of lead-free piezoelectric ceramics&rdquo;. NSF-DMR, $63,969, 07\/01\/2016&ndash;06\/30\/2017<\/li>\r\n<li>PI: Nanoscale insight into electric fatigue of lead-free piezoelectric ceramics, NSF-DMR, $462,802, 07\/01\/2015--06\/30\/2019<\/li>\r\n<li>PI: AGEP-GRS supplemental funding for \"Nanoscale insight into electric fatigue of lead-free piezoelectric ceramics,\" NSF-DMR, $60,000, 07\/01\/2015--06\/30\/2016<\/li>\r\n<li>PI: Nanoscale mechanism of dielectric breakdown, Iowa Energy Center, $142,200, 07\/01\/2015--09\/30\/2016<\/li>\r\n<li>Co-PI: Materials for extreme environments, ISU College of Engineering, $150,000, 07\/01\/2015--06\/30\/2017<\/li>\r\n<li>Co-PI: Transfomative research on advanced thermal technology, ISU College of Engineering, $150,000, 07\/01\/2015--06\/30\/2017<\/li>\r\n<li>PI: Mechanics of multi-responsive ceramics for electrical capacitors with high power\/energy density, NSF-CMMI, $327,530, 10\/01\/2010&ndash;09\/30\/2013.<\/li>\r\n<li>PI: Origin of the electric field-induced strain in lead-free piezoelectric ceramics, NSF-DMR, $520,000, 10\/01\/2010&ndash;09\/30\/2014.<\/li>\r\n<li>Co-PI: Multifunctional polymer matrix composites, NASA-EPSCoR, $700,508, 09\/01\/2009&ndash;08\/31\/2012.<\/li>\r\n<li>Co-PI: Design and development of novel hierarchically ordered block copolymer-magnetoelectric particle nanocomposites, US-Air Force Office of Scientific Research, $600,000, 06\/01\/2009-05\/31\/2012.<\/li>\r\n<li>PI: Design and fabrication of flexible piezoelectric composites for NDE applications up to 150&deg;C,&nbsp;US-AFOSR through CNDE at ISU, $254,477, 10\/01\/2008-06\/30\/2010.<\/li>\r\n<li>Co-PI:&nbsp;Combinatorial and high throughput discovery of high temperature piezoelectric ceramics,&nbsp;U.S. Air Force Office of Scientific Research, $633,174, 04\/01\/2008-10\/31\/2011.<\/li>\r\n<li>Co-PI: REU site: Materials education and research on far-from-equilibrium materials, processes, structures, and properties,&nbsp;NSF, DMR, $273,000. 04\/15\/2008-04\/14\/2011.<\/li>\r\n<li>PI: Coupled phenomena in magnetoelectric multiferroics, Materials and Engineering Physics, Ames Laboratory, U.S. DOE, $750,000, 10\/01\/2007-09\/30\/2010.<\/li>\r\n<li>Co-PI:&nbsp;Investigation of structure\/properties relationships in thermally cycled novel <em>x<\/em>PZT-(1-<em>x<\/em>)PNN relaxor ferroelectrics, United States-Israel Binational Science Foundation, $123,027, 10\/01\/2007&ndash;09\/30\/2010.<\/li>\r\n<li>PI: TEM Study of PZT95\/5 (1.5Nb) Ceramics, Sandia National Laboratories, $59,873, 04\/01\/2007-09\/30\/2007.<\/li>\r\n<li>Co-PI: Acquisition of a wide frequency, impedance, and temperature range impedance spectrometer for materials research and education, Roy J. Carver Trust Foundation, $472,896, 01\/01\/2007&ndash;12\/30\/2007.<\/li>\r\n<li>PI: Searching for single phase compounds with strong spontaneous polarization and magnetization at room temperature, Short Term Innovative Research Program, the Army Research Office, $49,000, 09\/01\/2006&ndash;05\/31\/2007.<\/li>\r\n<li>PI:&nbsp;Coupled phenomena in multiferroics, Seed Fund from the Materials and Engineering Physics Program, Ames Laboratory; $235,400, 10\/01\/2006&ndash;09\/30\/2007.<\/li>\r\n<li>Co-PI:&nbsp;Multiscale study of domain mechanics, Seed Fund from the Materials and Engineering Physics Program, Ames Laboratory; $50,000, 08\/01\/2005?06\/30\/2006.<\/li>\r\n<li>PI: Direct observations of the dynamic evolution of nanoscale features in ferroelectric thin films: An in situ transmission electron microscopy study, Petroleum Research Fund, the American Chemical Society; $35,000; 09\/01\/2005-8\/31\/2007.<\/li>\r\n<li>PI: CAREER: The evolution of polar nanoregions and its coupling with cation-ordered domains in Pb(B'B\")O3 relaxor ferroelectrics, NSF, DMR-Ceramics; $400,000; 08\/01\/2004-07\/30\/2009.<\/li>\r\n<li>Co-PI: Acquisition of a comprehensive high temperature and high purity glove box materials processing facility for education and research, NSF, DMR-IMR; $200,000; 08\/15\/2003-08\/14\/2004.<\/li>\r\n<li>PI: Chemical solution deposition of ferroelectric thin films for in situ transmission electron microscopy study, University Research Grant, ISU; $15,970; 07\/01\/2003-06\/30\/2004.<\/li>\r\n<li>PI: Hot press processing and in situ transmission electron microscopic study of high-density, high-purity lead zirconate titanate ceramics, Process Science Initiative Program, Ames Laboratory, U.S. DOE, $70,000; 10\/01\/2002-9\/30\/2003.<\/li>\r\n<\/ul>\r\n<p><strong>Graduate Students<\/strong><\/p>\r\n<ul>\r\n<li>Haonan Qin (PhD)<\/li>\r\n<li>Odin Taylor (PhD)<\/li>\r\n<\/ul>\r\n<p><strong>Graduated PhD students<\/strong><\/p>\r\n<ul>\r\n<li>Binzhi Liu (May 2022, Advisor)<\/li>\r\n<li>Pratyasha Mohapatra (Jul. 2021, Co-advisor)<\/li>\r\n<li>Zhongming Fan (Jul. 2019, Advisor)<\/li>\r\n<li>Xiaoming Liu (Sep. 2015, Advisor)<\/li>\r\n<li>Yonghao Xu (Mar. 2015, visiting PhD student)<\/li>\r\n<li>Hanzheng Guo (Jul. 2014, Advisor)<\/li>\r\n<li>Cheng Ma (Aug. 2012, Advisor)<\/li>\r\n<li>Wei Hu (Aug. 2011, Advisor)<\/li>\r\n<li>Meagen A. Gillispie (Aug. 2006, Co-advisor)<\/li>\r\n<li>Hui He (Aug. 2007, Advisor)<\/li>\r\n<li>Xiaohui Zhao (Dec. 2008, Advisor)<\/li>\r\n<li>Weiguo Qu (Dec. 2008, Advisor)<\/li>\r\n<\/ul>\r\n<p><strong>Graduated MS students<\/strong><\/p>\r\n<ul>\r\n<li>Daniel Sommer (July 2017, Advisor)<\/li>\r\n<li>Samuel E Young (May 2013, Advisor)<\/li>\r\n<li>Weixing Sun (Aug. 2012, Advisor)<\/li>\r\n<li>Joshua Frederick (Jul. 2010, Advisor)<\/li>\r\n<\/ul>\r\n<p><strong>Undergraduate research assistants<\/strong><\/p>\r\n<ul>\r\n<li>Jesse Hatton, 2024<\/li>\r\n<li>Andrew Hoyt, 2023-2025<\/li>\r\n<li>Matthew Burris, 2022<\/li>\r\n<li>Elizabeth Griffin, 2022<\/li>\r\n<li>Ethan Chaffee, 2019-2020<\/li>\r\n<li>Odin Taylor, 2019-2020<\/li>\r\n<li>Joshua McLeod, 2018<\/li>\r\n<li>Kathleen Wilcox, 2016-2018<\/li>\r\n<li>Amy Kurr, 2015<\/li>\r\n<li>Benjamin Trieu, 2014<\/li>\r\n<li>Alexa Oser, 2013<\/li>\r\n<li>Deon Ploessl, 2013<\/li>\r\n<li>Cynthia Biggs, 2012-2013<\/li>\r\n<li>Daniel Hastings, 2012<\/li>\r\n<li>Skylar Conn, 2012<\/li>\r\n<li>Alexandra Skora, 2011<\/li>\r\n<li>Samuel Young, 2011<\/li>\r\n<li>Ryan Gebhardt, 2009<\/li>\r\n<li>Daniel Marincel, 2009<\/li>\r\n<li>Emily Decker, 2008-2009<\/li>\r\n<li>Daniel White, 2007-2008<\/li>\r\n<li>Fabian Stolzenburg, 2007-2009<\/li>\r\n<li>Matthew Cromwell, 2007<\/li>\r\n<li>Roshnika Fernando, 2007<\/li>\r\n<li>Charlotte Stewart-Sloan, 2006<\/li>\r\n<li>Eric Patterson, 2006<\/li>\r\n<li>Pylin Sarobol, 2005<\/li>\r\n<li>Natalie Schlesselman, 2005<\/li>\r\n<li>Martin Gran, 2003<\/li>\r\n<li>Ping Kuang, 2002-2003<\/li>\r\n<\/ul>","user_image":{"ID":"1285","post_author":"0","post_date":"2016-01-14 23:00:28","post_date_gmt":"2016-01-15 05:00:28","post_content":"","post_title":"Tan","post_excerpt":"","post_status":"inherit","comment_status":"closed","ping_status":"closed","post_password":"","post_name":"tan","to_ping":"","pinged":"","post_modified":"2022-06-06 09:48:13","post_modified_gmt":"2022-06-06 14:48:13","post_content_filtered":"","post_parent":"91","guid":"http:\/\/www.engineering.iastate.edu\/people\/files\/2016\/01\/Tan.jpg","menu_order":"0","post_type":"attachment","post_mime_type":"image\/jpeg","comment_count":"0","pod_item_id":"1285"},"user_title":"Professor\r\nMaterials Science and Engineering","phone_number":"515-294-3355","fax":"","office":"","_links":{"self":[{"href":"https:\/\/www.engineering.iastate.edu\/people\/wp-json\/wp\/v2\/profile\/91","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/www.engineering.iastate.edu\/people\/wp-json\/wp\/v2\/profile"}],"about":[{"href":"https:\/\/www.engineering.iastate.edu\/people\/wp-json\/wp\/v2\/types\/profile"}],"author":[{"embeddable":true,"href":"https:\/\/www.engineering.iastate.edu\/people\/wp-json\/wp\/v2\/users\/3"}],"version-history":[{"count":5,"href":"https:\/\/www.engineering.iastate.edu\/people\/wp-json\/wp\/v2\/profile\/91\/revisions"}],"predecessor-version":[{"id":17324,"href":"https:\/\/www.engineering.iastate.edu\/people\/wp-json\/wp\/v2\/profile\/91\/revisions\/17324"}],"wp:attachment":[{"href":"https:\/\/www.engineering.iastate.edu\/people\/wp-json\/wp\/v2\/media?parent=91"}],"wp:term":[{"taxonomy":"affiliation","embeddable":true,"href":"https:\/\/www.engineering.iastate.edu\/people\/wp-json\/wp\/v2\/affiliation?post=91"},{"taxonomy":"department","embeddable":true,"href":"https:\/\/www.engineering.iastate.edu\/people\/wp-json\/wp\/v2\/department?post=91"},{"taxonomy":"group","embeddable":true,"href":"https:\/\/www.engineering.iastate.edu\/people\/wp-json\/wp\/v2\/group?post=91"},{"taxonomy":"interest","embeddable":true,"href":"https:\/\/www.engineering.iastate.edu\/people\/wp-json\/wp\/v2\/interest?post=91"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}