Abstract
Herein, a 2D closely packed bicobalt complex supported by DFNS was first provided. The XPS and EDX pictures of the DFNS/(bicobalt complex) catalysts affirmed that bicobalt complex was well spread on the outer layer of DFNS. The CO2/propylene oxide coupling reactions, employing DFNS/(bicobalt complex) as catalysts were announced. In addition, the catalyst anatomical heterogeneity of DFNS/(bicobalt complex) was characterized by various techniques, including EDX, SEM, TGA, TEM, XPS, and FT-IR. No leaching of cobalt into the solution was observed. The catalytic power of our catalyst was compared with literature reported catalysts for the synthesis of cyclic carbonate. lower temperature, the minimum amount of catalyst, lower pressure of carbon dioxide and shorter reaction time were required for CO2 transformation, using DFNS/(bicobalt complex) NPs. Besides, hot filtration presented a throughout understanding of the catalyst’s heterogeneous nature. The easy and applied reusability of the catalyst was observed after the completion of the reaction.
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Aresta M (2010) Wiley-VCH. Weinheim, Germany, 1–13
Guan H, Huang S, Ding J, Tian F, Xu Q, Zhao J (2020) Actamaterialia 187:122–134
Xu Y, Zhang H, Yang F, Tong L, Yan D, Yang Y, Wang T, Wu Y (2021) Renew Energy 179:517–527
Zhang Y, Pan Z, Yang J, Chen J, Chen K, Yan K, Meng X, Zhang X, He M (2022) Powder Technol 399:117193
Zhang Z, Feng L, Liu H, Wang L, Wang S, Tang Z (2021) Inorganic chem front 9:35–43
Coates GW, Moore DR (2004) Angew Chem Int Ed 43:6618–6639
Darensbourg DJ (2007) Chem Rev 107:2388–2410
Xi M, Fu X, Yang H, He C, Fu L, Cheng X, Guo J (2022) Chin Chem Lett 33:2595–2599
Zhang X, Sun X, Lv T, Weng L, Chi M, Shi J, Zhang S (2020) J Mater sci Mater electron 31:13344–13351
Zhang L, Cong M, Ding X, Jin Y, Xu F, Wang Y, Chen L, Zhang L (2020) AngewandteChemie (Int ed) 59:10888–10893
Narang S, Macova E, Berek D, Upadhyay SN, Mehta R (2016) J Appl Polym Sci 133:43099
Hoštálek Z, Mundil R, Císařová I, Trhlíková O, Grau E, Peruch F, Cramail H, Merna J (2015) Polymer 63:52–61
Liu H, Li X, Ma Z, Sun M, Li M, Zhang Z, Zhang L, Tang Z, Yao Y, Huang B, Guo S (2021) Nano Lett 21:10284–10291
Artz J, Müller TE, Thenert K, Kleinekorte J, Meys R, Sternberg A, Bardow A, Leitner W (2018) Chem Rev 118:434–504
Liu W, Zheng J, Ou X, Liu X, Song Y, Tian C, Rong W, Shi Z, Dang Z, Lin Z (2018) Environ Sci Technol 52:13336–13342
Xue X, Zhang H, Liu H, Wang S, Li J, Zhou Q, Chen X, Ren X, Jing Y, Deng Y, Geng Z, Wang X, Su J (2022). Adv Func Mater. https://doi.org/10.1002/adfm.202202470
Yang L, Wang H (2014) Chem Sus Chem 7:962–998
Li B, Li C, Zhang Y, Wang Y, Jia D, Yang M (2016) Chin J Aeronaut 29:1084–1095
Zhang XP, Li CH, Zhang YB, Wang YG, Li BK, Yang M, Guo SM, Liu GT, Zhang NQ (2017) Precis Eng 47:532–545
He G, Liu X, Cui Z (2021) Glob Food Sec 29:100536
Shi C, Wu Z, Yang F, Tang Y (2021) Solid State Sci 119:106702
Poremba KE, Kadunce NT, Suzuki N, Cherney AH, Reisman SE (2017) J Am Chem Soc 139:5684–5687
Yugandar S, Konda S, Ila H (2017) Org Lett 19:1512–1515
Wang Y, Li C, Zhang Y, Yang M, Li B, Dong L, Wang J (2018) Int J Precis Eng Manuf-Green Technol 5:327–339
Corpet M, Gosmini C (2012) Chem Commun 48:11561–11563
Zhang J, Li C, Zhang Y, Yang M, Jia D, Liu G, Hou Y, Li R, Zhang N, Wu Q, Cao H (2018) J Clean Prod 193:236–248
Maity A, Polshettiwar V (2017) Chemsuschem 10:3866–3913
Liu M, Li C, Zhang Y, An Q, Yang M, Gao T, Mao C, Liu B, Cao H, Xu X, Said Z, Debnath S, Jamil M, Muhammad Ali H (2021) Frontiers of. Mech Eng 16:649–697
Gao T, Li C, Wang Y, Liu X, An Q, Li HN, Zhang Y, Cao H, Liu B, Wang D, Said Z, Debnath S, Jamil M, Muhammad Ali H, Sharma S (2022) Compos Struct 286:115232
Fihri A, Cha D, Bouhrara M, Almana N, Polshettiwar V (2012) Chemsuschem 5:85–89
Mishra AK, Belgamwar R, Jana R, Datta A, Polshettiwar V (2020) PNAS 117:6383–6390
Maity A, Chaudhari S, Titman JJ, Polshettiwar V (2020) Nature Comm 11:3828
Belgamwar R, Maity A, Das T, Chakraborty S, Vinod CP, Polshettiwar V (2021) Chemical Sci 12:4825–4835
Maity A, Belgamwar R, Polshettiwar V (2019) Nature Prot 14:2177–2203
Dong Z, Le X, Li X, Zhang W, Dong C, Ma J (2014) Appl Catal B 158–159:129–135
Baghbamidi SE, Hassankhani A, Sanchooli E, Sadeghzadeh SM (2018) Appl Organomet Chem 32:e4251
Sadeghzadeh SM (2016) J Mol Liq 223:267–273
Zhiani R, Saadati SM, Zahedifar M, Sadeghzadeh SM (2018) Catal Lett 148:2487–2500
Sun J, Ren J, Zhang S, Cheng W (2009) Tetrahedron Lett 50:423–426
Udayakumar S, Raman V, Shim HL, Park DW (2009) Appl Catal A 368:97–104
Lan DH, Chen L, Au CT, Yin SF (2015) Carbon 93:22–31
Xiao L, Su D, Yue C, Wu W (2014) J CO2 Utiliz. 6 1–6
Sakai T, Tsutsumi Y, Ema T (2008) Green Chem 10:337–434
Mirabaud A, Mulatier JC, Martinez A, Dutasta JP, Dufaud V (2015) ACS Catal 5:6748–6752
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Hassan, A., Samawi, K.A., Nassar, M.F. et al. Synthesis of Cyclic Carbonate from Carbon Dioxide and Epoxides Using Bicobalt Complexes Absorbed on DFNS. Catal Lett 153, 2900–2909 (2023). https://doi.org/10.1007/s10562-022-04130-z
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DOI: https://doi.org/10.1007/s10562-022-04130-z