[1] 石瑛, 王婷, 李晋平, 王爽. co4ⅲ 四边形和 coⅱ 八面体构筑块搭建的一维超分子化合物. 化学通报. 2016;79:152-6.
[2] 罗居杰, 张萌, 郭瑞乾, 李晋平. 氨基功能化聚醚砜气体分离膜对 co_2/n_2, co_2/ch_4 分离性能研究. 化工新型材料. 2016;44:95-7.
[3] 李立博, 王勇, 王小青, 陈杨, 杨江峰, 李晋平. 柔性金属有机骨架材料 (mofs) 用于气体吸附分离. 化工进展. 2016;35:1794-803.
[4] 李丹丹, 高国锋, 郝根彦, 李晋平, 赵强. 银基析氧催化剂的研究进展. 化工进展. 2016;35:1428-32.
[5] 郝根彦 李, 高国锋, 赵强, 李晋平. co-ci析氧催化剂的原位调控制备及性能. 太阳能学报. 2016;37:2768-71.
[6] 郭天宇, 杜建平, 王爽, 吴金婷, 李晋平. 具有温和可控的 sio2 微球尺寸及吸附和催化性能. chemical research in chinese universities. 2016:0-.
[7] 高国锋 李, 郝根彦,李晋平赵强. 铁基阳极析氧催化剂的研究进展与展望. 应用化学. 2016;33:504-12.
[8] 陈杨, 杨江峰, 欧阳坤, 李立博, 王勇, 李晋平. 基于减少雾霾形成的脱氨材料的研究进展. 化工新型材料. 2016;44:1-3.
[9] zhao q, li d, gao g, yuan w, hao g, li j. nanostructured fe (iii) catalysts for water oxidation assembled with the aid of organic acid salt electrolytes. appl surf sci. 2016;387:1274-80.
[10] yang j, wang j, deng s, li j. improved synthesis of trigone trimer cluster metal organic framework mil-100al by a later entry of methyl groups. chem commun. 2016;52:725-8.
[11] yang chen cy, xiaoqing wang, jiangfeng yang, kun ouyang, jinping li. kinetically controlled ammonia vapor diffusion synthesis of a zn(ii) mof and its h2o/nh3 adsorption properties. j mater chem a. 2016;4:10345-51.
[12] wang y, yang q, zhong c, li j. graphene-like poly (triazine imide) as n2-selective ultrathin membrane for post-combustion co2 capture. j phys chem c. 2016;120:28782-8.
[13] wang y, yang q, li j, yang j, zhong c. exploration of nanoporous graphene membranes for the separation of n 2 from co 2: a multi-scale computational study. phys chem chem phys. 2016;18:8352-8.
[14] wang y, li j, yang q, zhong c. two-dimensional covalent triazine framework membrane for helium separation and hydrogen purification. acs appl mater interfaces. 2016;8:8694-701.
[15] wang x, li l, yang j, li j. co 2/ch 4 and ch 4/n 2 separation on isomeric metal organic frameworks. chin j chem eng. 2016;26:1687–94.
[16] wang s, wang t, shi y, liu g, li j. mesoporous co 3 o 4@ carbon composites derived from microporous cobalt-based porous coordination polymers for enhanced electrochemical properties in supercapacitors. rsc advances. 2016;6:18465-70.
[17] wang k, huang h, liu d, wang c, li j, zhong c. covalent triazine-based frameworks with ultramicropores and high nitrogen contents for highly selective co2 capture. environ sci technol. 2016;50:4869-76.
[18] shi q, xu w-j, huang r-k, zhang w-x, li y, wang p, et al. zeolite can and afi-type zeolitic imidazolate frameworks with large 12-membered ring pore openings synthesized using bulky amides as structure-directing agents. j am chem soc. 2016;138:16232-5.
[19] shi q, guan y, wang f, yang j, li l, li j, et al. synthesis and structural characterization of a two‐dimensional magnesium acetate, mg7 (oh) 2 (oac) 12 (h2o) 4· 4h2o, a precursor to three‐dimensional porous magnesium acetate. eur j inorg chem. 2016;2016:3299-304.
[20] rong jiang sw, jinping li. cucurbit[7]uril-tetraphenylethene host-guest system induced emission activity. rsc advances. 2016;6:4478-82.
[21] qiang zhao dl, guofeng gao, wen yuan, genyan hao, jinping li. nanostructured iron(iii) oxide catalyst electrodeposited from fe(ii) triflate for electrocatalytic water oxidation. int j hydrogen energy. 2016;41:17193-8.
[22] luo j, guo r, zhang m, li j. gas permeation properties of polymer membranes containing pendant tertiary amine groups. high perform polym. 2016;28:1005-14.
[23] liu g, wang k, li j, wang y, yuan h. enhancement of hydrogen desorption in magnesium hydride catalyzed by graphene nanosheets supported ni-ceo x hybrid nanocatalyst. int j hydrogen energy. 2016;41:10786–94.
[24] liu g, wang k, gao x, he d, li j. fabrication of mesoporous nife 2 o 4 nanorods as efficient oxygen evolution catalyst for water splitting. electrochim acta. 2016;211:871–8.
[25] liu g, gao x, wang k, he d, li j. uniformly mesoporous nio/nife 2 o 4 biphasic nanorods as efficient oxygen evolving catalyst for water splitting. int j hydrogen energy. 2016;41:17976-86.
[26] libo li rk, yong wang, xiaoqing wang, jiangfeng yang, jinping li. flexible metal–organic frameworks with discriminatory gate-opening effect for the separation of acetylene from ethylene/acetylene mixtures. eur j inorg chem. 2016;2016:4457–62.
[27] li l, wang y, yang j, chen y, li j. functionalized metal‐organic frameworks for the efficient removal of low‐concentrations of ammonia. chempluschem. 2016;81:222–8.
[28] li l, krishna r, wang y, yang j, wang x, li j. exploiting the gate opening effect in a flexible mof for selective adsorption of propyne from c1/c2/c3 hydrocarbons. j mater chem a. 2016;4:751 - 5.
[29] hao g, zhang r, li j, wang b, zhao q. insight into the effect of surface structure on h 2 adsorption and activation over different cuo (111) surfaces: a first-principle study. computational materials science. 2016;122:191-200.
[30] guo t, du j, wu j, wang s, li j. structure and kinetic investigations of surface-stepped ceo 2-supported pd catalysts for low-concentration methane oxidation. chem eng j. 2016;306:745-53.
[31] guo t, du j, wu j, li j. palladium catalyst supported on stair-like microstructural ceo 2 provides enhanced activity and stability for low-concentration methane oxidation. applied catalysis a: general. 2016;524:237-42.
[32] guo t, du j, li j. the effects of ceria morphology on the properties of pd/ceria catalyst for catalytic oxidation of low-concentration methane. journal of materials science. 2016:1-9.
[33] du j, huang x, zhao r, li j, asefa t. hierarchically self‐assembled star‐shaped zno microparticles for electrochemical sensing of amines. chemistry-a european journal. 2016;22:8068-73.
[34] chen y, li l, li j, ouyang k, yang j. ammonia capture and flexible transformation of m-2 (ina)(m= cu, co, ni, cd) series materials. j hazard mater. 2016;306:340-7.