Textbook Question
Tell how many diastereoisomers are possible for each of the following complexes, and draw their structures.
(a) Pt(NH3)3Cl (square planar)
(b) [FeBr2Cl2(en)]-
102
views
Ch.21 - Transition Elements and Coordination Chemistry
McMurry8th EditionChemistryISBN: 9781292336145
Not the one you use?Change textbookSelect a different textbook
Table of contents
- Ch.1 - Chemical Tools: Experimentation & Measurement170
- Ch.2 - Atoms, Molecules & Ions160
- Ch.3 - Mass Relationships in Chemical Reactions169
- Ch.4 - Reactions in Aqueous Solution199
- Ch.5 - Periodicity & Electronic Structure of Atoms102
- Ch.6 - Ionic Compounds: Periodic Trends and Bonding Theory92
- Ch.7 - Covalent Bonding and Electron-Dot Structures61
- Ch.8 - Covalent Compounds: Bonding Theories and Molecular Structure59
- Ch.9 - Thermochemistry: Chemical Energy122
- Ch.10 - Gases: Their Properties & Behavior155
- Ch.11 - Liquids & Phase Changes54
- Ch.12 - Solids and Solid-State Materials73
- Ch.13 - Solutions & Their Properties120
- Ch.14 - Chemical Kinetics98
- Ch.15 - Chemical Equilibrium125
- Ch.16 - Aqueous Equilibria: Acids & Bases110
- Ch.17 - Applications of Aqueous Equilibria147
- Ch.18 - Thermodynamics: Entropy, Free Energy & Equilibrium86
- Ch.19 - Electrochemistry154
- Ch.20 - Nuclear Chemistry96
- Ch.21 - Transition Elements and Coordination Chemistry156
- Ch.22 - The Main Group Elements187
- Ch.23 - Organic and Biological Chemistry51
All textbooks
McMurry 8th EditionCh.21 - Transition Elements and Coordination ChemistryProblem 21.129a
McMurry 8th EditionCh.21 - Transition Elements and Coordination ChemistryProblem 21.129aChapter 21, Problem 21.129a
Two first-series transition metals have three unpaired electrons in complex ions of the type [MCl4]2-.
(a) What are the oxidation state and the identity of M in these complexes?
(b) Draw valence bond orbital diagrams for the two possible ions.
(c) Based on common oxidation states of first-series transition metals (Figure 21.6), which ion is more likely to exist?
<QUESTION REFERENCES FIGURE 21.6>
Verified step by step guidance1
Determine the oxidation state of M: The complex ion is [MCl_4]^{2-}. Each chloride ion (Cl^-) has a charge of -1. Therefore, the total charge contributed by the four chloride ions is -4. Since the overall charge of the complex is -2, the oxidation state of M must be +2 to balance the charges.
Identify the transition metals with three unpaired electrons in a +2 oxidation state: In the first transition series, the metals with three unpaired electrons in a +2 oxidation state are typically those with a d^7 electron configuration. These metals are Cobalt (Co) and Nickel (Ni).
Draw valence bond orbital diagrams: For each metal ion, draw the d-orbital splitting diagram in a tetrahedral field. Show the distribution of electrons in the d-orbitals, ensuring that there are three unpaired electrons.
Consider the common oxidation states: Refer to Figure 21.6 or a similar resource to determine which of the two metals, Co or Ni, is more commonly found in the +2 oxidation state.
Conclude which ion is more likely to exist: Based on the common oxidation states and the stability of the electron configuration, determine which of the two ions, [CoCl_4]^{2-} or [NiCl_4]^{2-}, is more likely to exist.
Verified video answer for a similar problem:
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.
Oxidation States of Transition Metals
The oxidation state of a transition metal in a complex ion indicates the charge of the metal ion after accounting for the charges of the ligands. In the case of [MCl4]2-, the overall charge is -2, and since each chloride ion (Cl-) has a charge of -1, the oxidation state of M can be calculated by balancing these charges. Understanding oxidation states is crucial for identifying the metal and its possible electronic configurations.
Recommended video:
Guided course
03:12
Transition Metals
Valence Bond Theory and Orbital Diagrams
Valence Bond Theory explains how atomic orbitals combine to form bonds in molecules. For transition metals, the d orbitals play a significant role in bonding and can be involved in hybridization. Drawing orbital diagrams for the complex ions helps visualize the arrangement of electrons, particularly the unpaired electrons, which are essential for determining the magnetic properties and reactivity of the complexes.
Recommended video:
Guided course
04:12Molecular Orbital Diagram
Common Oxidation States of First-Series Transition Metals
First-series transition metals exhibit a variety of oxidation states due to the involvement of d electrons in bonding. Common oxidation states can be predicted based on the electron configuration and the stability of the resulting ions. By referring to Figure 21.6, one can assess which oxidation states are more prevalent and likely to form stable complexes, aiding in the identification of the metal in the given complex.
Recommended video:
Guided course
03:12Transition Metals
Related Practice
Textbook Question
Cobalt(III) trifluoroacetylacetonate, Co(tfac)3, is a sixc oordinate, octahedral metal chelate in which three planar, bidentate tfac ligands are attached to a central Co atom:
(a) Draw all possible diastereoisomers and enantiomers of Co(tfac)3.
105
views
Textbook Question
What is the systematic name for each of the following ions?
(a) [MnCl4]2-
(b) [Ni(NH3)6]2+
132
views
Textbook Question
Tell how many diastereoisomers are possible for each of the following complexes, and draw their structures.
(c) [Cu(H2O)4Cl2]+
(d) Ru(NH3)3I3
88
views
Textbook Question
Give a valence bond description of the bonding in each of the following complexes. Include orbital diagrams for the free metal ion and the metal ion in the complex. Indicate which hybrid orbitals the metal ion uses for bonding, and specify the number of unpaired electrons.
(b) [NiBr4]2- (tetrahedral)
112
views
Textbook Question
Assign a systematic name to each of the following ions.
(c) [Fe(H2O)5NCS]2+
(d) [Cr(NH3)2(C2O4)2]-
220
views