2017年1月29日 · Why is Cu(acac)X2 C u (a c a c) X 2 square planar, whereas Al(acac)X3 A l (a c a c) X 3 and Fe(acac)X3 F e (a c a c) X 3 form octahedral complexes? I see how a similar …

2015年7月23日 · All Cupric complexes irrespective of the kind of ligands is always dsp2 square planar hybridization . Now the question is that why this is so? In tetrahedral complexes when …

2017年7月1日 · The tetraamminecopper(II) ion is square planar in shape. But why? How can I rationalise this? Can I rationalise this without the concept of hybridization? And even if I take …

2017年4月23日 · Why do square planar coordination compounds of type $\ce { [Mabcd]}$ not show optical activity, although they contain 4 different ligands (i.e. chiral central metal atom)?

2020年5月16日 · I recently came across a fact that for the same combination of metal and ligand, the crystal field splitting energy for square planar complexes is larger than that of the …

2020年10月14日 · The title says it all really. I thought it would be acetylacetonatobipyridinecopper (II) tetraphenylborate. Is this correct? I feel as though it looks a bit clumsy and wasn’t sure if I …

2020年1月20日 · The complex Ni(acac)X2 N i (a c a c) X 2 is paramagnetic as expected , i.e it has two unpaired electrons giving rise to a magnetic moment of 8–√ 8 BM but doesn't have the …

How can one predict whether a given complex ion will be square planar or tetrahedral when its coordination number is 4 using crystal field theory? Is it possible to theoretically predict this?

Is there a way to explain why the coordination number of for example $\\ce{Cu^2+}$ can be either 4 or 6?

It is highly unlikely for square planar complex to be high-spin, otherwise the benefit of square planar coordination is too low. That said, addressing your title question: it is possible for metal …