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Square Planar Complexes

In square planar complexes the central metal cation is either dsp 2 or sp2d hybridised. Examples are shown below:


[Ni(CN)4]2– ion:-In this complex the valence shell electronic configuration of Ni (o.s. +2) is 3d8. Since CN is a strong ligand, therefore, pairing of two unpaired electrons of 3d orbitals takes place resultin g in a vacant d orbital. This vacant 3d orbital gets hybridised with the vacant 4s and two of 4p orbitals to give four dsp2 hybrid orbitals. This lead to the formation of square planar geometry and the magnetic moment is zero. Hence the complex is diamagnetic.

Square Planar Complexes - Coordination Chemistry | Inorganic Chemistry
Square Planar Complexes - Coordination Chemistry | Inorganic Chemistry

n  = 0 ,       μ = 0 (diamagnetic)


[PdCl4]In this complex the o.s. of Pd is +2. Hence the outermost electronic configuration is 3d8. Alt hough Cl is a weak ligand, pairing of d electrons takes place because Pd is a transit ion metal of 4d series and according to VBT assumptions, the pairing always takes place in the 4d and 5d metals irrespective of the ligand type. Hence, 3d electrons get paired here. Consequently, dsp2 hybridisation takes place and the magnetic moment is zero. Thus, the geometry of this complex is square planar in contrast to corresponding Ni complex NiCl42– which is tetrahedral.

Square Planar Complexes - Coordination Chemistry | Inorganic Chemistry

Square Planar Complexes - Coordination Chemistry | Inorganic Chemistry  Square Planar Complexes - Coordination Chemistry | Inorganic Chemistry

n = 0,       μ = 0 (diamagnetic)


[Cu(NH3)4]2+In this complex ion, the o.s. of copper is +2 and its valence shell electronic configuration is 3d9. Magnetic moment observations indicate that the complex is paramagnetic. This observation is in correspondence with the tetrahedral geometry of this complex ion having sp3 hybridisation as shown below:

Square Planar Complexes - Coordination Chemistry | Inorganic Chemistry
Square Planar Complexes - Coordination Chemistry | Inorganic Chemistry

n = 1,      Square Planar Complexes - Coordination Chemistry | Inorganic Chemistry    = 1.73 B.M. (paramagnetic)

In this compound the expected hybridisation was sp3 but according to ESR (Electron Spin Resonance Spectroscop y) and X-ray crystallography studies, the structure of [Cu(NH3)4]2+ ion is square planar. But this is only possible with either dspor sp2d hybrid orbitals.
To form dsp2 hybrid orbitals, it is considered that the unpaired electrons in 3d orbital are promoted to the 4p orbital as shown below:

Square Planar Complexes - Coordination Chemistry | Inorganic Chemistry
Square Planar Complexes - Coordination Chemistry | Inorganic Chemistry

In the above electronic configuration the single unpaired electron is present in the higher level 4p orbital. Hence it can be oxidised ver y easily. But the Cu 3+ ion does not exist i.e. oxidation of Cu2+ to Cu3+ is not possible.

Square Planar Complexes - Coordination Chemistry | Inorganic Chemistry

This observation led to the failure of above theory of dsp2 hybridisation also.
Finally, it was suggested that in square planar [Cu(NH3)4]2+ complex, Cu2+ ion is sp2d hybridised as shown below.

Square Planar Complexes - Coordination Chemistry | Inorganic Chemistry

In this configuration, one of the three 4p orbitals, 4pz orbital does not participate in hybridisation because pz orbital lies above and below the plane of the ion. [Cu(py)2]2+, [Cu(en)2]2+, [Cu(CN)4]2– all complexes are square planar and Cu2+ is sp2d hybridised. 

 Limitations of VBT

Although, VBT is useful to visualize the bonding in complexes but it fails to explain certain observations in coordination complexes:

  • VBT does not explain the nature of ligands i.e. it does not tell which ligand is weak and which is strong.
  • VBT could not explain the phenomenon of electron pairing which occurs in the presence of strong ligands.
  • It does not explain the effect of temperature on magnetic moment and also not able to explain why the experimental value of magnetic moment is greater than the calculated value in some complexes.
  • VBT could not explain the colour and electronic spectra of complexes.

Crystal Field Theory (CFT)

To explain the above properties which did not explain by VBT, Bethe and Van Vleck proposed another theory which is known as Crystal Field Theory or CFT.
This theory is based on following assumptions:

  • Bonding in complexes is purely electrostatic in nat ure and not covalent as proposed b y the VBT.
  • In complexes two types of electrostatic forces operate.
    • One is the attraction between the metal cation and the e lectron rich ligands.
    • The second type of electrostatic interaction is the repulsion between the lone pair of electrons on the ligands and electrons in the d orbitals of the metal cation and the repulsion between the two nuclei of metal cation and the ligand.
  • Ionic ligands such as Cl, CN, OH are regarded as negative point charges or point charges and the neutral ligands such as H2O, NH3, py are regarded as point dipole. In the case of later species, the negative end of the dipole is directed towards the metal ion.
  • The five orbitals in a free metal ion are degenerate. When a complex is formed, the electrostatic field of ligands affect the degeneracy of d orbitals and thereby destroy their degeneracy.
  • The orbitals which lobes pointed towards axis of ligands have higher energies than those lying away from the ligands because of the repulsion between the d electrons and the ligands.

The shapes of five d orbitals are shown below:

Square Planar Complexes - Coordination Chemistry | Inorganic ChemistrySquare Planar Complexes - Coordination Chemistry | Inorganic ChemistrySquare Planar Complexes - Coordination Chemistry | Inorganic ChemistrySquare Planar Complexes - Coordination Chemistry | Inorganic ChemistrySquare Planar Complexes - Coordination Chemistry | Inorganic Chemistry

All the three orbitals dxy, dyz and dzx lie in between the axes. These orbitals lie in xy, yz and zx-planes respectively. The dx2 – y2 orbital lie on x and y axes and the dz2 orbital on z-axis. All the five d orbitals are gerade because they have centre of symmetry exist between their axis. The (+) and (-) signs indicate the different phase of the lobes of orbitals.

The document Square Planar Complexes - Coordination Chemistry | Inorganic Chemistry is a part of the Chemistry Course Inorganic Chemistry.
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FAQs on Square Planar Complexes - Coordination Chemistry - Inorganic Chemistry

1. What is a square planar complex in coordination chemistry?
Ans. A square planar complex is a type of coordination complex in which the central metal ion is surrounded by four ligands arranged in a square planar geometry. This means that the ligands are situated at the corners of a square around the central metal ion.
2. What are the characteristics of square planar complexes?
Ans. Some of the characteristics of square planar complexes include: - They have a coordination number of 4, meaning that there are four ligands attached to the central metal ion. - The ligands in a square planar complex are arranged in a flat, square shape around the central metal ion. - Square planar complexes are commonly formed by metal ions with a d8 electron configuration. - They often exhibit high spin-low spin transitions due to the presence of unpaired electrons.
3. How do ligands arrange themselves in a square planar complex?
Ans. In a square planar complex, the ligands arrange themselves in a square shape around the central metal ion. The ligands occupy the corners of the square, with two ligands positioned in the same plane as the central metal ion and the other two ligands perpendicular to this plane. This arrangement allows for maximum interaction between the ligands and the central metal ion.
4. What are some examples of square planar complexes?
Ans. Some examples of square planar complexes include: - [PtCl4]2-: This complex is formed by platinum (Pt) with four chloride (Cl-) ligands. - [Ni(CO)4]: This complex is formed by nickel (Ni) with four carbon monoxide (CO) ligands. - [PdCl2(PPh3)2]: This complex is formed by palladium (Pd) with two chloride (Cl-) ligands and two triphenylphosphine (PPh3) ligands.
5. What are the applications of square planar complexes?
Ans. Square planar complexes have various applications in coordination chemistry and related fields. Some of the applications include: - Catalysis: Square planar complexes are often used as catalysts in chemical reactions due to their ability to activate and control reactants. - Medicinal chemistry: Some square planar complexes have shown potential in the development of new drugs and therapies, particularly in the treatment of cancer. - Material science: Square planar complexes can be used to design and synthesize new materials with tailored properties, such as magnetic or luminescent behavior.
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