B. Bożek et al.
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(
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molybdate MoO (1,3-dapH ) 3, in a reproducible fashion.
4
2
The best-performing catalyst for cis-cyclooctene (Cy) and
6. Neves P, Gomes AC, Paz FAA, Valente AA, Gonçalves IS, Pill-
inger M (2017) Mol Catal 432:104–114
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3
7
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tungsten analogue WO (1,2-dap) 4 performed inferiorly; e.g.
3
up to 47% Cy conversion for 4, compared to up to quan-
titative epoxide yield for 1, at 70 °C. Overall, the results
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8
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clean, cheap fashions from commercially available organic
and inorganic precursors and using environmentally benign
water as solvent.
1
2. Amarante TR, Neves P, Coelho AC, Gago S, Valente AA,
Paz FAA, Pillinger M, Gonçalves IS (2010) Organometallics
In the emergence of simple cheap hybrids for diverse
applications, it is desirable to investigate the inꢂuence of
the type of aliphatic diamine and synthesis conditions on
properties such as structural density and distances between
2
9:883–892
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7:1246–1250
1
1
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5. Neves P, Nogueira LS, Gomes AC, Oliveira TSM, Lopes AD,
Valente AA, Gonçalves IS, Pillinger M (2017) Eur J Inorg Chem
MO centers, aiming at, for example, facilitated access of
3
organic molecules to active sites of the internal surface.
2
017:2617–2627
Acknowledgements This work was developed within the scope of
the project CICECO-Aveiro Institute of Materials, FCT Ref. UID/
CTM/50011/2019, financed by national funds through the FCT/
MCTES, and the project POCI-01-0145-FEDER-030075 co-funded by
POCI (Programa Operacional Competitividade e Internacionalização),
FEDER Fundo Europeu de Desenvolvimento Regional) and FCT. P. N.
thanks to national funds (OE), through FCT, I.P., in the scope of the
framework contract foreseen in the numbers 4, 5 and 6 of the article 23,
of the Decree-Law 57/2016, of August 29, changed by Law 57/2017, of
July 19. The European Union Erasmus+programme [Project Number:
16. Jendoubi I, Smail RB, Maczka M, Zid MF (2018) Ionics
24:3515–3533
17. Öztürk N, Bahçeli S (2006) Z. Naturforsch. A 61:399–401
18. Amarante TR, Antunes MM, Valente AA, Paz FAA, Pillinger
M, Gonçalves IS (2015) Inorg Chem 54:9690–9703
19. Twu J, Fang T-H, Hsu C-F, Yu Y-Y, Wang G-J, Tang C-W, Chen
K-H, Lii K-H (1998) J Mater Chem 8:2181–2184
20. Altomare A, Camalli M, Cuocci C, Giacovazzo C, Moliterni A,
Rizzi R (2009) J Appl Cryst 42(6):1197–1202
21. Petricek V, Dusek M, Palatinus L (2006) The crystallographic
computing system, JANA2006. Czech Republic, Institute of
Physics
2
016-1-PL01-KA103-023786] is acknowledged for providing scholar-
ship (ꢀnancial support) for the traineeship of B.B. And B.B., M.O.,
K.P., J.P., W.L. acknowledge partial ꢀnancial support of the project by
the statutory research fund of ICSC PAS and/or FC UJ.
22. Amarante TR, Neves P, Valente AA, Paz FAA, Pillinger M,
Gonçalves IS (2016) J Catal 340:354–367
2
2
2
3. Bożek B, Neves P, Łasocha W, Valente AA (2018) Appl Catal
A 564:13–25
Compliance with Ethical Standards
4. Veiros LF, Prazeres Â, Costa PJ, Romão CC, Khün FE, Calhorda
MJ (2006) Dalton Trans 1383–1390
Conflict of interest All authors have no conꢂicts of interest to declare.
5. Lysenko AB, Senchyk GA, Domasevitch KV, Hauser J, Fuhr-
mann D, Kobalz M, Krautscheid H, Neves P, Valente AA, Gon-
çalves IS (2015) Inorg Chem 54:8327–8338
tion, and reproduction in any medium, provided you give appropriate
credit to the original author(s) and the source, provide a link to the
Creative Commons license, and indicate if changes were made.
26. Lysenko AB, Senchyk GA, Domasevitch KV, Kobalz M, Krau-
tscheid H, Cichos J, Karbowiab M, Neves P, Valente AA, Gon-
çalves IS (2017) Inorg Chem 56:4380–4394
27. Amarante TR, Neves P, Paz FAA, Valente AA, Pillinger P, Gon-
çalves IS (2014) Dalton Trans 43:6059–6069
2
2
3
8. Schachner JA, Mösch-Zanetti NC, Peuronen A, Lehtonen A
(
2017) Polyhedron 134:73–78
9. Zhao J, Santos AM, Herdtweck E, Khün FE (2004) J Mol Catal
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