Bipolar conduction and giant positive magnetoresistance in doped metallic titanium oxide heterostructures
Empowering conventional materials with unexpected magnetoelectric properties is appealing to the multi-functionalization of existing devices and the exploration of future electronics. Recently, owing to its unique effect in modulating a matter's properties, ultra-small dopants, for example, H,...
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sg-ntu-dr.10356-1513922023-02-28T19:54:00Z Bipolar conduction and giant positive magnetoresistance in doped metallic titanium oxide heterostructures Huang, Ke Wang, Tao Jin, Mengjia Wu, Liang Wang, Floria Junyao Li, Shengyao Qi, Dong-Chen Cheng, Shuying Li, Yangyang Chen, Jingsheng He, Xiaozhong Li, Changjian Pennycook, Stephen J. Wang, Renshaw Xiao School of Physical and Mathematical Sciences Engineering::Materials Bipolar Conduction Giant Magnetoresistance Empowering conventional materials with unexpected magnetoelectric properties is appealing to the multi-functionalization of existing devices and the exploration of future electronics. Recently, owing to its unique effect in modulating a matter's properties, ultra-small dopants, for example, H, D, and Li, attract enormous attention in creating emergent functionalities, such as superconductivity, and metal–insulator transition. Here, an observation of bipolar conduction accompanied by a giant positive magnetoresistance in D-doped metallic Ti oxide (TiOxDy) films is reported. To overcome the challenges in intercalating the D into a crystalline oxide, a series of TiOxDy is formed by sequentially doping Ti with D and surface/interface oxidation. Intriguingly, while the electron mobility of the TiOxDy increases by an order of magnitude larger after doping, the emergent holes also exhibit high mobility. Moreover, the bipolar conduction induces a giant magnetoresistance up to 900% at 6 T, which is ≈6 times higher than its conventional phase. This study paves a way to empower conventional materials in existing electronics and induce novel electronic phases. Ministry of Education (MOE) National Research Foundation (NRF) Accepted version 2021-06-14T02:09:14Z 2021-06-14T02:09:14Z 2021 Journal Article Huang, K., Wang, T., Jin, M., Wu, L., Wang, F. J., Li, S., Qi, D., Cheng, S., Li, Y., Chen, J., He, X., Li, C., Pennycook, S. J. & Wang, R. X. (2021). Bipolar conduction and giant positive magnetoresistance in doped metallic titanium oxide heterostructures. Advanced Materials Interfaces, 8(9), 2002147-. https://dx.doi.org/10.1002/admi.202002147 2196-7350 0000-0002-5503-9899 https://hdl.handle.net/10356/151392 10.1002/admi.202002147 2-s2.0-85100492789 9 8 2002147 en Advanced Materials Interfaces This is the peer reviewed version of the following article: Huang, K., Wang, T., Jin, M., Wu, L., Wang, F. J., Li, S., Qi, D., Cheng, S., Li, Y., Chen, J., He, X., Li, C., Pennycook, S. J. & Wang, R. X. (2021). Bipolar conduction and giant positive magnetoresistance in doped metallic titanium oxide heterostructures. Advanced Materials Interfaces, 8(9), 2002147-. https://dx.doi.org/10.1002/admi.202002147, which has been published in final form at https://doi.org/10.1002/admi.202002147. This article may be used for non-commercial purposes in accordance with Wiley Terms and Conditions for Use of Self-Archived Versions. application/pdf |
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Engineering::Materials Bipolar Conduction Giant Magnetoresistance Huang, Ke Wang, Tao Jin, Mengjia Wu, Liang Wang, Floria Junyao Li, Shengyao Qi, Dong-Chen Cheng, Shuying Li, Yangyang Chen, Jingsheng He, Xiaozhong Li, Changjian Pennycook, Stephen J. Wang, Renshaw Xiao Bipolar conduction and giant positive magnetoresistance in doped metallic titanium oxide heterostructures |
| description |
Empowering conventional materials with unexpected magnetoelectric properties is appealing to the multi-functionalization of existing devices and the exploration of future electronics. Recently, owing to its unique effect in modulating a matter's properties, ultra-small dopants, for example, H, D, and Li, attract enormous attention in creating emergent functionalities, such as superconductivity, and metal–insulator transition. Here, an observation of bipolar conduction accompanied by a giant positive magnetoresistance in D-doped metallic Ti oxide (TiOxDy) films is reported. To overcome the challenges in intercalating the D into a crystalline oxide, a series of TiOxDy is formed by sequentially doping Ti with D and surface/interface oxidation. Intriguingly, while the electron mobility of the TiOxDy increases by an order of magnitude larger after doping, the emergent holes also exhibit high mobility. Moreover, the bipolar conduction induces a giant magnetoresistance up to 900% at 6 T, which is ≈6 times higher than its conventional phase. This study paves a way to empower conventional materials in existing electronics and induce novel electronic phases. |
| author2 |
School of Physical and Mathematical Sciences |
| author_facet |
School of Physical and Mathematical Sciences Huang, Ke Wang, Tao Jin, Mengjia Wu, Liang Wang, Floria Junyao Li, Shengyao Qi, Dong-Chen Cheng, Shuying Li, Yangyang Chen, Jingsheng He, Xiaozhong Li, Changjian Pennycook, Stephen J. Wang, Renshaw Xiao |
| format |
Article |
| author |
Huang, Ke Wang, Tao Jin, Mengjia Wu, Liang Wang, Floria Junyao Li, Shengyao Qi, Dong-Chen Cheng, Shuying Li, Yangyang Chen, Jingsheng He, Xiaozhong Li, Changjian Pennycook, Stephen J. Wang, Renshaw Xiao |
| author_sort |
Huang, Ke |
| title |
Bipolar conduction and giant positive magnetoresistance in doped metallic titanium oxide heterostructures |
| title_short |
Bipolar conduction and giant positive magnetoresistance in doped metallic titanium oxide heterostructures |
| title_full |
Bipolar conduction and giant positive magnetoresistance in doped metallic titanium oxide heterostructures |
| title_fullStr |
Bipolar conduction and giant positive magnetoresistance in doped metallic titanium oxide heterostructures |
| title_full_unstemmed |
Bipolar conduction and giant positive magnetoresistance in doped metallic titanium oxide heterostructures |
| title_sort |
bipolar conduction and giant positive magnetoresistance in doped metallic titanium oxide heterostructures |
| publishDate |
2021 |
| url |
https://hdl.handle.net/10356/151392 |
| _version_ |
1759858014428332032 |