¸·Ñôʦ·¶´óѧÇÇÈð½ÌÊÚ¿ÎÌâ×éµ÷¼ÁÕÐÉúÐÅÏ¢
ÕÐÊÕ¶ÔÏ󣺱¨¿¼»¯Ñ§×¨Òµ¹ý. AÇøÏß¿¼Éú
Ñо¿·½Ïò£ºÓлúÓ«¹â²ÄÁÏ
¿ÎÌâ×éÕÐÉúÓÅÊÆ£º
1.ÓÅÁ¼µÄʵÑéÊÒ»·¾³¡£±¾¿ÎÌâ×éʵÑéÊÒ¿Õ¼äºÍ¿ÆÑо·Ñ³ä×㣬ʵÑéÒÇÆ÷É豸ÍêÉÆ£¬¾ß±¸¸ßЧ¿ªÕ¹¿ÆÑÐʵÑéµÄÌõ¼þ¡£
2.Á¼ºÃµÄ¿ÆÑзÕΧ¡£ ÇÇÈð½ÌÊÚ¿ÆÑÐ֪ʶ´¢±¸·áºñ£¬´ýÈËÇ×½üºÍÉÆ£¬ÔÚ¿ÆÑй¤×÷ÖÐÄܹ»¸øÓèºÜ´óµÄÖ¸µ¼°ïÖú¡£
3.ѧУ½±ÖúÌåϵÍêÉÆ¡£ ¾ßÌåÐÅÏ¢¿ÉÒԵǼ¸·Ñôʦ·¶´óѧ¹ÙÍø²éѯ2020ÄêÑо¿ÉúÕÐÉúרÌâ¡£
»¶Ó¹ã´ó¶ÔÓлúÓ«¹â²ÄÁϺÍÓиÐÐËȤµÄͬѧ¼ÓÈëÎÒÃÇ£¡
Óе÷¼ÁÒâÏòµÄͬѧÇ뽫¸öÈ˼òÀúÒÔÐÕÃû+¸öÈË¿¼Ñгɼ¨ÃüÃûµÄ·½Ê½·¢ËÍÖÁÓÊÏ䣺qiaorui@mail.ipc.ac.cn
ÇÇÈðÀÏʦ¼ò½é£ºÇÇÈð£¬Àíѧ²©Ê¿£¬½ÌÊÚ
µç×ÓÓÊÏ䣺qiaorui@mail.ipc.ac.cn
ѧϰ¹¤×÷¾Àú£º
2002.07 °²»Õʦ·¶´óѧ »¯Ñ§Ñ§Ê¿Ñ§Î»
2007.07 Öйú¿ÆѧԺÀí»¯¼¼ÊõÑо¿Ëù Óлú»¯Ñ§²©Ê¿Ñ§Î»
2010.11 ¸±½ÌÊÚ
2017.11 ½ÌÊÚ
Ö÷ÒªÑо¿·½Ïò£º
Öñºì¾úËØÀà¹âÃô¼ÁµÄ½á¹¹ÐÞÊÎÒÔ¼°ÆäÔڹ⶯Á¦ÖÎÁÆÖеÄÓ¦ÓÃ
Àë×Ó̽ÕëµÄÉè¼ÆÓëºÏ³É
³É¹û¼ò½é£º
Ò»¡¢Ö÷³Ö¸÷Àà¿ÆÑÐÏîÄ¿
DNA°ÐÏò¹¦ÄܵÄðèÄÒÇ»¾úËØAÀà¹âÃô¼ÁµÄÉè¼ÆºÏ³ÉÓë¹â¶¯Á¦ÐÔÖÊÑо¿£¬¹ú¼Ò×ÔÈ»¿Æѧ»ù½ðÇàÄê¿ÆѧÏîÄ¿£¬1302019
°²»ÕÊ¡¸ßµÈѧУ×ÔÈ»¿ÆѧÑо¿ÖØ´óÏîÄ¿£¬KJ2019ZD38
¹âÖ±äÉ«¼¼ÊõÔÚʳƷ°²È«ÖеÄÓ¦Ó㬸·ÑôÊÐÕþ¸®-¸·Ñôʦ·¶Ñ§ÔººáÏòºÏ×÷ÖصãÏîÄ¿
°²»Õ¸ßУÓÅÐãÇàÄêÈ˲ÅÖ§³Ö¼Æ»®ÖصãÏîÄ¿£¬gxyqZD2017068
ðèÄÒÇ»¾úËØAÑÜÉúÎïµÄºÏ³É¼°Æä¹â¶¯Á¦ÐÔÖÊÑо¿£¬Öйú¿ÆѧԺ¡°¹â»¯Ñ§×ª»»Ó빦ÄܲÄÁÏ¡±ÖصãʵÑéÊÒ¿ª·Å¿ÎÌâ
°²»ÕÊ¡¸ßУʡ¼¶ÓÅÐãÇàÄêÈ˲ÅÏîÄ¿£¬2011SQRL101
°²»ÕÊ¡¸ßУʡ¼¶×ÔÈ»¿ÆѧÑо¿ÏîÄ¿£¬2011KJ2011B123
¶þ£®¸÷Àà»ñ½±
°²»ÕÊ¡¿Æѧ¼¼ÊõÈýµÈ½±£¨2015Ä꣬µÚÈýÍê³ÉÈË£©
Èý£®´ú±íÐÔÖø×÷ÓëÂÛÎÄ
2020Äê
[14] Bai, C.-B.; Zhang, J.; Qiao, R.*; Mu, S.-Y.; Meng, M.; Wei, B.; Wang, C.; Qu, C.-Q.; Ji, Y.-T. Thiadiazole-based turn-on fluorescent chemosensor for AcO− and its application in environmental systems and in bioimaging. SN Applied Sciences 2020, 2, 567.
[13] Bai, C. B.; Wang, W. G.; Zhang, J.; Wang, C.; Qiao, R.*; Wei, B.; Zhang, L.; Chen, S. S.; Yang, S. A Fluorescent and Colorimetric Chemosensor for Hg2+ Based on Rhodamine 6G With a Two-Step Reaction Mechanism. Frontiers in Chemistry 2020, 8, 7.
[12] Bai, C. B.; Liu, X. Y.; Zhang, J.; Qiao, R.*; Dang, K.; Wang, C.; Wei, B.; Zhang, L.; Chen, S. S. Using Smartphone APP To Determine the CN- Concentration Quantitatively in Tap Water: Synthesis of the Naked-Eye Colorimetric Chemosensor for CN- and Ni2+ Based on Benzothiazole. Acs Omega 2020, 5, 2488.
2019Äê
[11] Bai, C.-B.; Xu, P.; Zhang, J.; Qiao, R.*; Chen, M.-Y.; Mei, M.-Y.; Wei, B.; Wang, C.; Zhang, L.; Chen, S.-S. Long-Wavelength Fluorescent Chemosensors for Hg2+ based on Pyrene. ACS Omega 2019, 4, 14621-14625.
[10] Bai, C.-B.; Fan, H.-Y.; Qiao, R.*; Wang, S.-N.; Wei, B.; Meng, Q.; Wang, Z.-Q.; Liao, J.-X.; Zhang, J.; Zhang, L.; Chen, S.-S.; Miao, H. Synthesis of methionine methyl ester-modified coumarin as the fluorescent-colorimetric chemosensor for selective detection Cu2+ with application in molecular logic gate. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy 2019, 216, 45-51.
[9] Qiao, R.; Fan, H. Y.; Bai, C. B.; Dai, L.; Zhang, L.; Zhang, J.; Chen, S. S.; Miao, H. Using Heterocycle to Improve the Selectivity of Rhodamine-6G Dye: Synthesis of Pyrrole-Modified Rhodamine-6G and its Recognition to Zn2+. J. Chem. Soc. Pak. 2019, 41, 300-307.
2018Äê
[8] Qiao, R.; Xiong, W.-Z.; Bai, C.-B.; Liao, J.-X.; Zhang, L. A highly selective fluorescent chemosensor for Fe [III] based on rhodamine 6G dyes derivative. Supramolecular Chemistry 2018, 30, 911-917.
[7] Bai, C.-B.; Qiao, R.*; Liao, J.-X.; Xiong, W.-Z.; Zhang, J.; Chen, S.-S.; Yang, S. A highly selective and reversible fluorescence ¡°OFF-ON-OFF¡± chemosensor for Hg2+ based on rhodamine-6G dyes derivative and its application as a molecular logic gate. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy 2018, 202, 252-259.
[6] Qiao, R.; Xiong, W.-Z.; Bai, C.-B.; Zhang, L.; Zhu, M.-M.; Chen, S.-S.; Miao, H. A highly selective fluorescent probe for Zn2+ based on a rhodamine-6G dye derivative modified by a furan unit. Journal of Chemical Research 2018, 42, 194-197.
[5] Bai, C. B.; Wang, S. N.; Qiao, R.*; Fan, H. Y.; Wei, B.; Xu, P.; Zhang, L.; Zhang, J.; Li, R. Q.; Chen, S. S.; Yang, S. A Fluorescent Sensor For Zn2+ Based on Rhodamine Thiophene Framework. Int. J. Electrochem. Sci. 2018, 13, 10368-10381.
2017Äê֮ǰ
[4] Qiao, R.; Zhang, Z.-Y.; Zhu, M.-A. Synthesis, Crystal Structure and Water Vapor Adsorption Properties of a Porous Supramolecular Architecture. Crystals 2017, 7.
[3] Qiao, R.; Chen, S.-S.; Sheng, L.-Q.; Yang, S.; Li, W.-D. Syntheses, crystal structures, and properties of four complexes based on polycarboxylate and imidazole ligands. Journal of Solid State Chemistry 2015, 228, 199-207.
[2] Qiao, R.; Zhou, L.; Zhou, J.; Wei, S.; Shen, J.; Zhang, B.; Wang, X. The synthesis and characterization of ethylenediamine-modified Elsinochrome A. Dyes and Pigments 2012, 94, 99-102.
[1] Qiao, R.; Zeng, Z.-H.; Xia, S.-Q.; Zhou, J.-H.; Liu, Y.-Y.; Chen, J.-R.; Wang, X.-S.; Zhang, B.-W. Using electrostatic interactions to increase the photodamaging ability of hypocrellin B: synthesis and study of 2-(dimethylamino) ethanethiol-modified HB. New Journal of Chemistry 2007, 31, 196-198.
·¢×ÔСľ³æAndroid¿Í»§¶Ë |