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°ÄÖÞÀ¥Ê¿À¼¿Æ¼¼´óѧÍõºìϼ (hongxia wang) µ¼Ê¦ÕÐÊÕ²©Ê¿Ñо¿Éú ¼ò½é À¥Ê¿À¼¿Æ¼¼´óѧ£¨queensland university of technology£©×øÂäÓÚ°Ä´óÀûÑÇÀ¥Ê¿À¼Öݲ¼Àï˹°àÊÐÇø¡£ÀúÊ·Óƾã¬ÉùÓþ׿Öø¡£Ä¿Ç°ÅÅÃûÈ«°ÄÇ°10¡£ ×éÄÚ¿ÆÑо·Ñ³ä×㣬µ¼Ê¦ÍõºìϼΪ°ÄÖÞarc future fellowµÄ»ñµÃÕߣ¨Ï൱ÓÚ¹úÄÚ½ÜÇࣩ¡£ ¾ßÌåÏêÇéÇë²Î¿¼¿ÎÌâ×éÁ´½Ó http://hongxiawanggroup.org/ ÈëѧҪÇó »ñµÃ»òÕß¼´½«»ñµÃ¹úÄÚ˶ʿѧλ£¬Ó¢Óï´ïµ½ÈëѧÌõ¼þ£¨ÑÅ˼ƽ¾ù6.5·Ö£¬µ¥¿Æ²»µÍÓÚ6·Ö£»»òÕßÍи£90·Ö£¬µ¥¿Æ²»µÍÓÚ20·Ö)¡£ Ìṩȫ¶î½±Ñ§½ð£¨Ã¿ÄêÔ¼27000°Ä±Ò£©£¬½±Ñ§½ð²»ÐèÒª²ÎÓëѧУ¾ºÕù£¬Ö»ÐèÒªÄãͨ¹ýºìϼµ¼Ê¦µÄÈϿɼ´¿É¡£ Éú»î·½Ãæ qut×øÂäÓÚ°ÄÖ޵IJ¼Àï˹°à£¬ÊÇÒ»¸öÑô¹â³ÇÊУ¬Ëļ¾Èç´º£¬Ã¿Äê×îµÍÆøβ»µÍÓÚÁãÉÏ5ÉãÊ϶ȣ¬ºÜÊʺÏÉú»î¡£ Ö÷ÒªÑо¿·½Ïò »¶Ó¾ßÓл¯Ñ§¡¢ÎïÀí¡¢²ÄÁϱ³¾°µÄѧÉúÉêÇ룬 Ï£ÍûÄã¾ßÓÐÌ«ÑôÄܵç³Ø£¨¸ÆîÑ¿óÌ«ÑôÄܵç³Ø£©»òÕߵ绯ѧÄÜÔ´´æ´¢·½ÃæµÄÑо¿¾Ñ飬ÖÁÉÙÓÐһƪsciÂÛÎÄ·¢±í¡£ ÓÐÒâÕß¿ÉÒÔ·¢¼òÀúµ½ ÒÔÏÂÊÇÎÒÃÇ×éÔÚ2018ÄêÒ»Äê·¢±íµÄ²¿·ÖÎÄÕ£¬¹©²Î¿¼¡£ [1] l. wang, z. wei, m. mao, h. wang, y. li, and j. ma, ¡°metal oxide/graphene composite anode materials for sodium-ion batteries,¡± energy storage materials, vol. 16, pp. 434-454, 2019. [2] y. zhao, n. jiang, x. zhang, j. guo, y. li, l. gao, et al., ¡°low-cost, large-scale, one-pot synthesis of c/ni 3 (no 3 ) 2 (oh) 4 composites for high performance supercapacitor,¡± materials chemistry and physics, vol. 217, pp. 291-299, 2018. [3] z. zhang, j. zhao, m. xu, h. wang, y. gong, and j. xu, ¡°facile synthesis of sb2s3/mos2 heterostructure as anode material for sodium-ion batteries,¡± nanotechnology, vol. 29, pp. 1-7, 2018. [4] z. zhang, j. zhao, h. wang, y. gong, and j. l. xu, ¡°facile synthesis of sb/cnt nanocomposite as anode material for sodium-ion batteries,¡± functional materials letters, vol. 11, pp. 1850004- 1850004, 2018. [5] z. zhang, x. huang, h. wang, s. h. teo, and t. ma, ¡°free-standing nico2s4@vs2 nanoneedle array composite electrode for high performance asymmetric supercapacitor application,¡± journal of alloys and compounds, vol. 771, pp. 274-280, 2018. [6] s. zhang, n. d. pham, t. tesfamichael, j. bell, and h. wang, ¡°thermal effect on czts solar cells in different process of zno/ito window layer fabrication,¡± sustainable materials and technologies, vol. 18, pp. article number-e00078, 2018. [7] s. zhang, h. d. hadi, y. wang, b. liang, v. t. tiong, f. ali, et al., ¡°a precursor stacking strategy to boost open-circuit voltage of cu2znsns4 thin-film solar cells,¡± ieee journal of photovoltaics, 2018. [8] f. yu, z. liu, r. zhou, d. tan, h. wang, and f. wang, ¡°pseudocapacitance contribution in boron-doped graphite sheets for anion storage enables high-performance sodium-ion capacitors,¡± materials horizons, vol. 5, pp. 529-535, 2018. [9] f. yu, z. chang, x. yuan, f. wang, y. zhu, l. fu, et al., ¡°ultrathin nico2s4@graphene with a core¨cshell structure as a high performance positive electrode for hybrid supercapacitors,¡± journal of materials chemistry a, vol. 2018, pp. 5856-5861, 2018. [10] d. yao, c. zhang, n. d. pham, y. zhang, v. t. tiong, a. du, et al., ¡°hindered formation of photo-inactive ¦Ä-fapbi3 phase and hysteresis-free mixed-cation planar heterojunction perovskite solar cells with enhanced efficiency via potassium incorporation,¡± the journal of physical chemistry letters, vol. 9, pp. 2113-2120, 2018. [11] y. yang, n. d. pham, d. yao, h. zhu, p. yarlagadda, and h. wang, ¡°inorganic p-type semiconductors and carbon materials based hole transport materials for perovskite solar cells,¡± chinese chemical letters, vol. 29, pp. 1242-1250, 2018. [12] w. xu, t. wang, h. wang, s. zhu, y. liang, z. cui, et al., ¡°free-standing amorphous nanoporous nickel cobalt phosphide prepared by electrochemically delloying process as a high performance energy storage electrode material,¡± energy storage materials, 2018. [13] t. wang, h. c. chen, f. yu, x. s. zhao, and h. wang, ¡°boosting the cycling stability of transition metal compounds-based supercapacitors,¡± energy storage materials, 2018. [14] v. t. tiong, n. d. pham, t. wang, t. zhu, x. zhao, y. zhang, et al., ¡°octadecylamine-functionalized single-walled carbon nanotubes for facilitating the formation of a monolithic perovskite layer and stable solar cells,¡± advanced functional materials, pp. 1705545-1705545, 2018. [15] l. sun, j. liu, z. liu, t. wang, h. wang, and y. li, ¡°sulfur-doped mesoporous carbon via thermal reduction of cs2 by mg for high-performance supercapacitor electrodes and li-ion battery anodes,¡± rsc advances, vol. 8, pp. 19964-19970, 2018. [16] m. roknuzzaman, k. ostrikov, k. chandula wasalathilake, c. yan, h. wang, and t. tesfamichael, ¡°insight into lead-free organic-inorganic hybrid perovskites for photovoltaics and optoelectronics: a first-principles study,¡± organic electronics, vol. 59, pp. 99-106, 2018. [17] h. d. pham, h. hu, f.-l. wong, c.-s. lee, w.-c. chen, k. feron, et al., ¡°acene-based organic semiconductors for organic light-emitting diodes and perovskite solar cells,¡± journal of materials chemistry c, 2018. [18] s. Öz, j. burschka, e. jung, r. bhattacharjee, t. fischer, a. mettenbörger, et al., ¡°protic ionic liquid assisted solution processing of lead halide perovskites with water, alcohols and acetonitrile,¡± nano energy, vol. 51, pp. 632-638, 2018. [19] j. ma, z. wei, l. wang, m. zhuo, w. ni, h. wang, et al., ¡°layered tin sulfide and selenide anode materials for li- and na-ion batteries,¡± journal of materials chemistry a, vol. 6, pp. 12185-12214, 2018. [20] a. jaggessar, a. mathew, h. wang, t. tesfamichael, c. yan, and p. k. yarlagadda, ¡°mechanical, bactericidal and osteogenic behaviours of hydrothermally synthesised tio 2 nanowire arrays,¡± journal of the mechanical behavior of biomedical materials, vol. 80, pp. 311-319, 2018. [21] z. huang, x. qin, x. gu, g. li, y. mu, n. wang, et al., ¡°mn3o4 quantum dots supported on nitrogen-doped partially exfoliated multi-wall carbon nanotubes as oxygen reduction electrocatalysts for high-performance zn-air batteries,¡± acs applied materials & interfaces, 2018. [22] x. huang, z. zhang, h. li, h. wang, and t. ma, ¡°in-situ growth of nanowire wo 2.72 on carbon cloth as a binder-free electrode for flexible asymmetric supercapacitors with high performance,¡± journal of energy chemistry, 2018. [23] j. guo, y. zhao, n. jiang, a. liu, l. gao, y. li, et al., ¡°one-pot synthesis of 2d ti3c2/ni2co3(oh)2 composite as electrode material with superior capacity and high stability for hybrid supercapacitor,¡± electrochimica acta, vol. 292, pp. 168-179, 2018. [24] j. guo, y. zhao, n. jiang, a. liu, l. gao, y. li, et al., ¡°in-situ grown ni(oh)2 nanosheets on ni foam for hybrid supercapacitors with high electrochemical performance,¡± journal of the electrochemical society, vol. 165, pp. a882-a890, 2018. [25] y. gong, j. zhao, h. wang, and j. xu, ¡°cuco2s4/reduced graphene oxide nanocomposites synthesized by one-step solvothermal method as anode materials for sodium ion batteries,¡± electrochimica acta, 2018. [26] f. ali, n. d. pham, j. bradford, n. khoshsirat, k. ostrikov, j. bell, et al., ¡°tuning of oxygen vacancy in sputter-deposited snox films for enhancing the performance of perovskite solar cells,¡± chemsuschem, vol. 11, pp. 3096-3103, 2018. [ Last edited by MrWilliam on 2020-10-14 at 04:36 ] |
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