Textbook Question
The lobes of which d orbitals point directly between the ligands in a. octahedral geometry,
104
views
Ch.23 - Transition Metals and Coordination Chemistry
Chapter 23, Problem 59
A classmate says, “A weak-field ligand usually means the complex is high spin.” Is your classmate correct? Explain.
Verified step by step guidance1
Understand the terms: A 'ligand' is a molecule or ion that binds to a central metal atom to form a coordination complex. The 'field strength' of a ligand refers to its ability to split the d-orbitals of the metal ion in a complex.
Recognize the relationship between field strength and electron pairing: Weak-field ligands cause smaller splitting of the d-orbitals in a metal complex compared to strong-field ligands. This smaller splitting may not be sufficient to overcome the electron pairing energy.
Define high spin and low spin complexes: In a high spin complex, electrons occupy higher energy d-orbitals to maximize unpaired electrons, due to insufficient splitting by the ligand. In a low spin complex, electrons pair up in the lower energy d-orbitals as the splitting is significant enough to overcome electron pairing energy.
Connect ligand field strength to spin state: With weak-field ligands, the splitting of d-orbitals is not large enough to promote electron pairing, leading to a high spin state where more unpaired electrons are present.
Conclude the accuracy of the statement: Your classmate is correct. A weak-field ligand usually results in a high spin complex because the small splitting of d-orbitals does not favor electron pairing, thus maximizing the number of unpaired electrons.
Verified Solution
Video duration:
5m
This video solution was recommended by our tutors as helpful for the problem above.Was this helpful?
Key Concepts
Here are the essential concepts you must grasp in order to answer the question correctly.
Ligand Field Theory
Ligand Field Theory explains how the presence of ligands around a central metal ion affects the energy levels of the d-orbitals. In this theory, ligands can be classified as strong or weak field based on their ability to split the d-orbital energies. Strong field ligands cause a large splitting, leading to low spin complexes, while weak field ligands result in smaller splitting, often leading to high spin complexes.
Recommended video:
Guided course
02:40
Strong-Field Ligands result in a large Δ and Weak-Field Ligands result in a small Δ.
Spin State of Complexes
The spin state of a complex refers to the arrangement of electrons in the d-orbitals, which can be either high spin or low spin. High spin complexes have unpaired electrons in higher energy orbitals due to smaller splitting, while low spin complexes have paired electrons in lower energy orbitals due to larger splitting. The spin state significantly influences the magnetic properties and reactivity of the complex.
Recommended video:
Guided course
01:28For octahedral complexes, Weak-Field Ligands create High-spin complexes and Strong-Field Ligands create Low-spin complexes.
Crystal Field Splitting Energy (Δ)
Crystal Field Splitting Energy (Δ) is the energy difference between the split d-orbitals in a transition metal complex. The magnitude of Δ is influenced by the nature of the ligands; weak field ligands produce a small Δ, favoring high spin configurations, while strong field ligands produce a large Δ, favoring low spin configurations. Understanding Δ is crucial for predicting the electronic structure and properties of coordination compounds.
Recommended video:
Guided course
03:04The crystal field splitting pattern for octahedral complexes has the d orbitals on or along the axes as having the higher energy.
Related Practice
Textbook Question
The lobes of which d orbitals point directly between the ligands in b. tetrahedral geometry?
116
views
Textbook Question
As shown in Figure 23.26, the d-d transition of [Ti(H2O)6]³⁺ produces an absorption maximum at a wavelength of about 500 nm .
a. What is the magnitude of ∆ for [Ti(H2O)6]³⁺ in kJ/mol?
b. How would the magnitude of ∆ change if the H2O ligands in [Ti(H2O)6]]³⁺ were placed with NH3 ligands?
118
views
Textbook Question
For a given metal ion and set of ligands, is the crystal-field splitting energy larger for a tetrahedral or an octahedral geometry?
130
views
Textbook Question
Complete the exercises below. Draw the crystal-field energy-level diagrams and show the placement of electrons for each of the following complexes:
a. [VCl6]3–,
b. [FeF6]3– (a high-spin complex),
Textbook Question
Draw the crystal-field energy-level diagrams and show the placement of electrons for each of the following complexes:
d. [NiCl4]2+ (tetrahedral),
115
views