19: Transition Metals and Coordination Chemistry

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Page ID: 479259

Marco Zimmer-De Iuliis, Anna Galang, and Amir Kanbar
University of Toronto Scarborough

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Transition metals are defined as those elements that have (or readily form) partially filled d orbitals. These include the d-block (groups 3–11) and f-block element elements. The variety of properties exhibited by transition metals is due to their complex valence shells. Unlike most main group metals where one oxidation state is normally observed, the valence shell structure of transition metals means that they usually occur in several different stable oxidation states. In addition, electron transitions in these elements can correspond with absorption of photons in the visible electromagnetic spectrum, leading to colored compounds. Because of these behaviors, transition metals exhibit a rich and fascinating chemistry.

Faculty Feature

We highlight Dr. Bernie Kraatz’s innovative research, which spans peptide hydrogels, prebiotic self-assembly, enzymatic sensors, and CO₂ electrochemical reduction. His work demonstrates the critical role of transition metals in coordination chemistry, catalysis, and sensor development. Dr. Kraatz’s research exemplifies the transformative applications of transition metal chemistry, showcasing its relevance to cutting-edge scientific advancements.

Read more about Dr. Bernie Kraatz and his research here: https://www.utsc.utoronto.ca/people/bkraatz/the-group/

19.1: Introduction
Transition metals exhibit unique chemistry due to their complex valence electron configurations, enabling multiple oxidation states and colored compounds (from visible light-absorbing d-electron transitions). These properties make them fundamental to inorganic chemistry. The chapter highlights how these principles drive real-world innovation, shown by research like Dr. Kraatz's, showcasing transition metals' role in scientific advancements and practical applications across diverse fields.
19.2: Occurrence, Preparation, and Properties of Transition Metals and Their Compounds
The transition metals are elements with partially filled d orbitals, located in the d-block of the periodic table. The reactivity of the transition elements varies widely from very active metals such as scandium and iron to almost inert elements, such as the platinum metals. The type of chemistry used in the isolation of the elements from their ores depends upon the concentration of the element in its ore and the difficulty of reducing ions of the elements to the metals.
19.3: Coordination Chemistry of Transition Metals
The transition elements and main group elements can form coordination compounds, or complexes, in which a central metal atom or ion is bonded to one or more ligands by coordinate covalent bonds. Ligands with more than one donor atom are called polydentate ligands and form chelates. The common geometries found in complexes are tetrahedral and square planar (both with a coordination number of four) and octahedral (with a coordination number of six).
19.4: Spectroscopic and Magnetic Properties of Coordination Compounds
Crystal field theory, which assumes that metal–ligand interactions are only electrostatic in nature, explains many important properties of transition-metal complexes, including their colors, magnetism, structures, stability, and reactivity.
19.5: Key Terms
19.6: Summary
This section provides a brief summary of all the sections covered. It is important to understand that this should not be seen as a summary that will help you understand everything; it will only get you familiar with big concepts.
19.7: Exercises
These are homework exercises to accompany the Textmap created for "Chemistry" by OpenStax. Complementary General Chemistry question banks can be found for other Textmaps and can be accessed here.

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