최소 단어 이상 선택하여야 합니다.
최대 10 단어까지만 선택 가능합니다.
다음과 같은 기능을 한번의 로그인으로 사용 할 수 있습니다.
NTIS 바로가기ACS energy letters, v.7, 2022년, pp.3718 - 3726
Park, Jooha (Department of Materials Science and Engineering, Research Institute of Advanced Materials (RIAM) , Seoul National University , 1 Gwanak-ro , Gwanak-gu, Seoul 151-742 , Republic of Korea) , Kim, Sung Joo (Department of Materials Science and Engineering, Research Institute of Advanced Materials (RIAM) , Seoul National University , 1 Gwanak-ro , Gwanak-gu, Seoul 151-742 , Republic of Korea) , Lim, Kyungmi (Department of Materials Science and Engineering, Research Institute of Advanced Materials (RIAM) , Seoul National University , 1 Gwanak-ro , Gwanak-gu, Seoul 151-742 , Republic of Korea) , Cho, Jiung , Kang, Kisuk
Titanium disulfide (TiS2), a first-generation cathode in lithium batteries, has also attracted a broad interest as a sodium-ion battery electrode due to fast sodium intercalation kinetics and large theoretical capacity. However, the reversibility of sodium de/intercalation is far inferior to that of...
Armand, M., Tarascon, J.-M.. Building better batteries. Nature, vol.451, no.7179, 652-657.
Kang, Kisuk, Meng, Ying Shirley, Bréger, Julien, Grey, Clare P., Ceder, Gerbrand. Electrodes with High Power and High Capacity for Rechargeable Lithium Batteries. Science, vol.311, no.5763, 977-980.
Whittingham, M. Stanley. Ultimate Limits to Intercalation Reactions for Lithium Batteries. Chemical reviews, vol.114, no.23, 11414-11443.
Kim, Hyungsub, Kim, Haegyeom, Ding, Zhang, Lee, Myeong Hwan, Lim, Kyungmi, Yoon, Gabin, Kang, Kisuk. Recent Progress in Electrode Materials for Sodium‐Ion Batteries. Advanced energy materials, vol.6, no.19, 1600943-.
Xu, Zheng‐Long, Park, Jooha, Yoon, Gabin, Kim, Haegyeom, Kang, Kisuk. Graphitic Carbon Materials for Advanced Sodium‐Ion Batteries. Small methods, vol.3, no.4, 1800227-.
Kim, Sung‐Wook, Seo, Dong‐Hwa, Ma, Xiaohua, Ceder, Gerbrand, Kang, Kisuk. Electrode Materials for Rechargeable Sodium‐Ion Batteries: Potential Alternatives to Current Lithium‐Ion Batteries. Advanced energy materials, vol.2, no.7, 710-721.
HwangThese authors contributed equally to this work., Jang-Yeon, Myung, Seung-Taek, Sun, Yang-Kook. Sodium-ion batteries: present and future. Chemical Society reviews, vol.46, no.12, 3529-3614.
Luo, Wei, Shen, Fei, Bommier, Clement, Zhu, Hongli, Ji, Xiulei, Hu, Liangbing. Na-Ion Battery Anodes: Materials and Electrochemistry. Accounts of chemical research, vol.49, no.2, 231-240.
Vaalma, Christoph, Buchholz, Daniel, Weil, Marcel, Passerini, Stefano. A cost and resource analysis of sodium-ion batteries. Nature reviews. Materials, vol.3, no.2, 18013-.
Han, Man Huon, Gonzalo, Elena, Singh, Gurpreet, Rojo, Teófilo. A comprehensive review of sodium layered oxides: powerful cathodes for Na-ion batteries. Energy & environmental science, vol.8, no.1, 81-102.
Chen, Shuangqiang, Wu, Chao, Shen, Laifa, Zhu, Changbao, Huang, Yuanye, Xi, Kai, Maier, Joachim, Yu, Yan. Challenges and Perspectives for NASICON‐Type Electrode Materials for Advanced Sodium‐Ion Batteries. Advanced materials, vol.29, no.48, 1700431-.
Fang, Yongjin, Zhang, Jiexin, Xiao, Lifen, Ai, Xinping, Cao, Yuliang, Yang, Hanxi. Phosphate Framework Electrode Materials for Sodium Ion Batteries. Advanced science, vol.4, no.5, 1600392-.
Xie, Bingxing, Sun, Baoyu, Gao, Tianyu, Ma, Yulin, Yin, Geping, Zuo, Pengjian. Recent progress of Prussian blue analogues as cathode materials for nonaqueous sodium-ion batteries. Coordination chemistry reviews, vol.460, 214478-.
Fang, Shan, Bresser, Dominic, Passerini, Stefano. Transition Metal Oxide Anodes for Electrochemical Energy Storage in Lithium‐ and Sodium‐Ion Batteries. Advanced energy materials, vol.10, no.1, 1902485-.
Park, Young‐Uk, Seo, Dong‐Hwa, Kim, Hyungsub, Kim, Jongsoon, Lee, Seongsu, Kim, Byoungkook, Kang, Kisuk. A Family of High‐Performance Cathode Materials for Na‐ion Batteries, Na3(VO1−xPO4)2 F1+2x (0 ≤ x ≤ 1): Combined First‐Principles and Experimental Study. Advanced functional materials, vol.24, no.29, 4603-4614.
Kim, Jongsoon, Yoon, Gabin, Kim, Hyungsub, Park, Young-Uk, Kang, Kisuk. Na3V(PO4)2: A New Layered-Type Cathode Material with High Water Stability and Power Capability for Na-Ion Batteries. Chemistry of materials : a publication of the American Chemical Society, vol.30, no.11, 3683-3689.
Hwang, Insang, Jung, Sung-Kyun, Cho, Sung-Pyo, Kang, Kisuk. In operando formation of new iron-oxyfluoride host structure for Na-ion storage from NaF-FeO nanocomposite. Energy storage materials, vol.23, 427-433.
Ali, Zeeshan, Zhang, Teng, Asif, Muhammad, Zhao, Lina, Yu, Yan, Hou, Yanglong. Transition metal chalcogenide anodes for sodium storage. Materials today, vol.35, 131-167.
Dahn, J., Haering, R.R.. Lithium intercalation in TiS2. Materials research bulletin, vol.14, no.10, 1259-1262.
WHITTINGHAM, M. S.. Electrical Energy Storage and Intercalation Chemistry. Science, vol.192, no.4244, 1126-1127.
Kasai, Hidetaka, Tolborg, Kasper, Sist, Mattia, Zhang, Jiawei, Hathwar, Venkatesha R., Filsø, Mette Ø., Cenedese, Simone, Sugimoto, Kunihisa, Overgaard, Jacob, Nishibori, Eiji, Iversen, Bo B.. X-ray electron density investigation of chemical bonding in van der Waals materials. Nature materials, vol.17, no.3, 249-252.
Lin, Cheng-Hung, Topsakal, Mehmet, Sun, Ke, Bai, Jianming, Zhao, Chonghang, Dooryhee, Eric, Northrup, Paul, Gan, Hong, Lu, Deyu, Stavitski, Eli, Chen-Wiegart, Yu-chen Karen. Operandostructural and chemical evolutions of TiS2in Na-ion batteries. Journal of materials chemistry. A, Materials for energy and sustainability, vol.8, no.25, 12339-12350.
Hu, Zhe, Tai, Zhixin, Liu, Qiannan, Wang, Shi‐Wen, Jin, Huile, Wang, Shun, Lai, Weihong, Chen, Mingzhe, Li, Lin, Chen, Lingna, Tao, Zhanliang, Chou, Shu‐Lei. Ultrathin 2D TiS2 Nanosheets for High Capacity and Long‐Life Sodium Ion Batteries. Advanced energy materials, vol.9, no.8, 1803210-.
Ryu, Ho-Suk, Kim, Jong-Seon, Park, Jin-Soo, Park, Jin-Woo, Kim, Ki-Won, Ahn, Jou-Hyeon, Nam, Tae-Hyeon, Wang, Guoxiu, Ahn, Hyo-Jun. Electrochemical Properties and Discharge Mechanism of Na/TiS2Cells with Liquid Electrolyte at Room Temperature. Journal of the Electrochemical Society : JES, vol.160, no.2, A338-A343.
Wang, Liping, Zou, Jian, Chen, Shulin, Zhou, Ge, Bai, Jianming, Gao, Peng, Wang, Yuesheng, Yu, Xiqian, Li, Jingze, Hu, Yong-Sheng, Li, Hong. TiS2 as a high performance potassium ion battery cathode in ether-based electrolyte. Energy storage materials, vol.12, 216-222.
Tchitchekova, Deyana S., Ponrouch, Alexandre, Verrelli, Roberta, Broux, Thibault, Frontera, Carlos, Sorrentino, Andrea, Bardé, Fanny, Biskup, Neven, Arroyo-de Dompablo, M. Elena, Palacín, M. Rosa. Electrochemical Intercalation of Calcium and Magnesium in TiS2: Fundamental Studies Related to Multivalent Battery Applications. Chemistry of materials : a publication of the American Chemical Society, vol.30, no.3, 847-856.
Sun, Xiaoqi, Bonnick, Patrick, Nazar, Linda F.. Layered TiS2 Positive Electrode for Mg Batteries. ACS energy letters, vol.1, no.1, 297-301.
Yoo, Hyun Deog, Liang, Yanliang, Dong, Hui, Lin, Junhao, Wang, Hua, Liu, Yisheng, Ma, Lu, Wu, Tianpin, Li, Yifei, Ru, Qiang, Jing, Yan, An, Qinyou, Zhou, Wu, Guo, Jinghua, Lu, Jun, Pantelides, Sokrates T., Qian, Xiaofeng, Yao, Yan. Fast kinetics of magnesium monochloride cations in interlayer-expanded titanium disulfide for magnesium rechargeable batteries. Nature communications, vol.8, no.1, 339-339.
Jeong, Sohee, Yoo, Dongwon, Ahn, Minji, Miró, Pere, Heine, Thomas, Cheon, Jinwoo. Tandem intercalation strategy for single-layer nanosheets as an effective alternative to conventional exfoliation processes. Nature communications, vol.6, 5763-.
Liu, Yuping, Wang, Hongtao, Cheng, Liang, Han, Na, Zhao, Feipeng, Li, Peirong, Jin, Chuanhong, Li, Yanguang. TiS2 nanoplates: A high-rate and stable electrode material for sodium ion batteries. Nano energy, vol.20, 168-175.
Chaturvedi, Apoorva, Edison, Eldho, Arun, Nagasubramanian, Hu, Peng, Kloc, Christian, Aravindan, Vanchiappan, Madhavi, Srinivasan. Two Dimensional TiS2 as a Promising Insertion Anode for Na‐Ion Battery. ChemistrySelect, vol.3, no.2, 524-528.
Tao, Hongwei, Zhou, Min, Wang, Ruxing, Wang, Kangli, Cheng, Shijie, Jiang, Kai. TiS 2 as an Advanced Conversion Electrode for Sodium‐Ion Batteries with Ultra‐High Capacity and Long‐Cycle Life. Advanced science, vol.5, no.11, 1801021-.
Park, Jooha, Xu, Zheng-Long, Kang, Kisuk. Solvated Ion Intercalation in Graphite: Sodium and Beyond. Frontiers in chemistry, vol.8, 432-.
Suo, Liumin, Borodin, Oleg, Gao, Tao, Olguin, Marco, Ho, Janet, Fan, Xiulin, Luo, Chao, Wang, Chunsheng, Xu, Kang. “Water-in-salt” electrolyte enables high-voltage aqueous lithium-ion chemistries. Science, vol.350, no.6263, 938-943.
Hou, Singyuk, Ji, Xiao, Gaskell, Karen, Wang, Peng-fei, Wang, Luning, Xu, Jijian, Sun, Ruimin, Borodin, Oleg, Wang, Chunsheng. Solvation sheath reorganization enables divalent metal batteries with fast interfacial charge transfer kinetics. Science, vol.374, no.6564, 172-178.
Yamada, Yuki, Wang, Jianhui, Ko, Seongjae, Watanabe, Eriko, Yamada, Atsuo. Advances and issues in developing salt-concentrated battery electrolytes. Nature energy, vol.4, no.4, 269-280.
Kim, Haegyeom, Hong, Jihyun, Park, Young‐Uk, Kim, Jinsoo, Hwang, Insang, Kang, Kisuk. Sodium Storage Behavior in Natural Graphite using Ether‐based Electrolyte Systems. Advanced functional materials, vol.25, no.4, 534-541.
Kim, Haegyeom, Hong, Jihyun, Yoon, Gabin, Kim, Hyunchul, Park, Kyu-Young, Park, Min-Sik, Yoon, Won-Sub, Kang, Kisuk. Sodium intercalation chemistry in graphite. Energy & environmental science, vol.8, no.10, 2963-2969.
Suo, Liumin, Borodin, Oleg, Wang, Yuesheng, Rong, Xiaohui, Sun, Wei, Fan, Xiiulin, Xu, Shuyin, Schroeder, Marshall A., Cresce, Arthur V., Wang, Fei, Yang, Chongyin, Hu, Yong‐Sheng, Xu, Kang, Wang, Chunsheng. “Water‐in‐Salt” Electrolyte Makes Aqueous Sodium‐Ion Battery Safe, Green, and Long‐Lasting. Advanced energy materials, vol.7, no.21, 1701189-.
Lee, Myeong Hwan, Kim, Sung Joo, Chang, Donghee, Kim, Jinsoo, Moon, Sehwan, Oh, Kyungbae, Park, Kyu-Young, Seong, Won Mo, Park, Hyeokjun, Kwon, Giyun, Lee, Byungju, Kang, Kisuk. Toward a low-cost high-voltage sodium aqueous rechargeable battery. Materials today, vol.29, 26-36.
Yoon, Gabin, Kim, Haegyeom, Park, Inchul, Kang, Kisuk. Conditions for Reversible Na Intercalation in Graphite: Theoretical Studies on the Interplay Among Guest Ions, Solvent, and Graphite Host. Advanced energy materials, vol.7, no.2, 1601519-.
Kim, Haegyeom, Lim, Kyungmi, Yoon, Gabin, Park, Jae‐Hyuk, Ku, Kyojin, Lim, Hee‐Dae, Sung, Yung‐Eun, Kang, Kisuk. Exploiting Lithium-Ether Co‐Intercalation in Graphite for High‐Power Lithium‐Ion Batteries. Advanced energy materials, vol.7, no.19, 1700418-.
Newman, Gerald H., Klemann, Lawrence P.. Ambient Temperature Cycling of an Na ‐ TiS2 Cell. Journal of the Electrochemical Society : JES, vol.127, no.10, 2097-2099.
Han, Bo, Chen, Shulin, Zou, Jian, Shao, Ruiwen, Dou, Zhipeng, Yang, Chen, Ma, Xiumei, Lu, Jing, Liu, Kaihui, Yu, Dapeng, Wang, Liping, Wang, Haicheng, Gao, Peng. Tracking sodium migration in TiS2usingin situTEM. Nanoscale, vol.11, no.15, 7474-7480.
*원문 PDF 파일 및 링크정보가 존재하지 않을 경우 KISTI DDS 시스템에서 제공하는 원문복사서비스를 사용할 수 있습니다.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.