Part A: The Essentials
The IUPAC definition of a transition element is an element that has an incomplete d subshell in either the neutral atom or its ions. Thus, Zn and Cd are d-block members but not transition elements (no incomplete d subshell). Mercury qualifies as a transition metal due to the reported HgF4 compound (d8 configuration).
19.1 Occurrence and Recovery
The elements on the left of the 3d series occur in nature primarily as metal oxides or as metal cations in combination with oxoanions. To the right of Fe, Co, Ni, Cu, and Zn occur mainly as sulfides and arsenides, consistent with increasingly soft Lewis acid character.
| Metal | Principal Minerals | Method of Recovery |
|---|---|---|
| Titanium | Ilmenite (FeTiO3), Rutile (TiO2) | TiO2 + C + Cl2 → TiCl4, then reduction with Na/Mg |
| Chromium | Chromite (FeCr2O4) | FeCr2O4 + 4C → Fe + 2Cr + 4CO |
| Manganese | Pyrolusite (MnO2) | MnO2 + 2C → Mn + 2CO |
| Iron | Haematite (Fe2O3), Magnetite (Fe3O4) | Fe2O3 + 3CO → 2Fe + 3CO2 |
| Copper | Chalcopyrite (CuFeS2) | 2CuFeS2 + 2SiO2 + 5O2 → 2Cu + 2FeSiO3 + 4SO2 |
19.2 Chemical and Physical Properties
Size and Electronegativity
| Group | 3 | 4 | 5 | 6 | 7 | 8 | 9 | 10 | 11 | 12 |
|---|---|---|---|---|---|---|---|---|---|---|
| 3d | Sc | Ti | V | Cr | Mn | Fe | Co | Ni | Cu | Zn |
| χP | 1.3 | 1.5 | 1.6 | 1.6 | 1.5 | 1.9 | 1.9 | 1.9 | 1.9 | 1.6 |
| r/pm | 164 | 147 | 135 | 129 | 137 | 126 | 125 | 125 | 128 | 137 |
| 4d | Y | Zr | Nb | Mo | Tc | Ru | Rh | Pd | Ag | Cd |
| χP | 1.2 | 1.4 | 1.6 | 1.8 | 1.9 | 2.2 | 2.2 | 2.2 | 1.9 | 1.7 |
| r/pm | 182 | 160 | 140 | 140 | 135 | 134 | 134 | 137 | 144 | 152 |
| 5d | La | Hf | Ta | W | Re | Os | Ir | Pt | Au | Hg |
| χP | 1.0 | 1.3 | 1.5 | 1.7 | 1.9 | 2.2 | 2.2 | 2.2 | 2.4 | 1.9 |
| r/pm | 187 | 159 | 141 | 141 | 137 | 135 | 136 | 139 | 144 | 155 |
The presence of d electrons in the valence shell is responsible for the colour, electronic conduction, magnetism, and rich organometallic chemistry of the d metals and their compounds.
Part B: The Detail - Overview
19.3 Group 3: Scandium, Yttrium, and Lanthanum
(a) Occurrence and Uses
Scandium is present at low levels in many lanthanoid ores. Commercial uses include alloying with aluminium in aerospace components (~2 tonnes/year production). ScI3 is used in high-intensity mercury vapor discharge lamps producing sunlight-like output.
Yttrium (~600 tonnes/year) is used extensively in optical applications. Doped complex oxides such as Eu:YVO4 are used as phosphors in displays and LED lighting. Yttrium aluminium garnet (YAG, Y3Al5O12) is used in lasers. YBa2Cu3O7 is used in high-temperature superconductors.
Lanthanum is used in mischmetal and as a component in nickel metal hydride rechargeable batteries. Lanthanum carbonate treats chronic kidney dysfunction by forming extremely insoluble LaPO4 (Ksp = 3.7 × 10−23).
(b) Binary Compounds
All form compounds almost exclusively in the +3 oxidation state. Oxides are white solids (M2O3), insoluble in water but soluble in dilute acid. A number of subhalides exist, such as Sc7Cl10 containing multiple metal–metal bonds.
(c) Complex Oxides and Halides
The ionic radius of Y3+ (102 pm in eight-fold coordination) is similar to many Ln3+ cations. Unlike lanthanoids, Y3+ has no unpaired f electrons, making yttrium compounds excellent host materials for doping with Ln3+ cations.
Replacement of 1% of yttrium by neodymium in YAG produces a material which, when exposed to high-intensity light from a flashlamp, produces an intense laser emission at 1064 nm. Er:YAG produces emission at 2940 nm for dentistry and medical applications.
19.4 Group 4: Titanium, Zirconium, and Hafnium
(a) Occurrence and Uses
Titanium is the second most abundant d metal after iron. It is as strong as steel but only half as dense, corrosion-resistant and high-melting. The Kroll process involves heating TiO2 with chlorine and carbon to give TiCl4, then reducing with molten magnesium under argon. TiO2 is widely used as a white pigment.
Zirconium is highly transparent to neutrons and is used as cladding material for fuel rods in nuclear power plants. Hafnium is a highly effective neutron absorber in control rods.
(b) Binary Compounds
Chemistry dominated by the +4 oxidation state. MO2 compounds are high-melting solids. MX4 (X = Cl, Br, I) are volatile covalent liquids/low-melting solids with tetrahedral geometries and are strong Lewis acids.
(c) Complex Oxides
In BaTiO3, the distorted perovskite structure gives a very high dielectric constant (~2000× that of air), used in charge-storage capacitors. Lead zirconate titanate (PZT) shows a strong piezoelectric effect for transducers.
Yttria-stabilized zirconia (YSZ): Doping ZrO2 with Y2O3 introduces oxide vacancies. Above 750°C, oxide ions diffuse rapidly, enabling applications in oxygen sensors and solid oxide fuel cells.
(e) Organometallic Compounds
Group 4 organometallics are normally electron-deficient (16-electron). Compounds of type [M(Cp)2XY] are active alkene polymerization catalysts for highly stereoregular polymers.
19.5 Group 5: Vanadium, Niobium, and Tantalum
(a) Occurrence and Uses
Vanadium occurs in 60+ minerals and fossil fuels. Used to harden steel and in high-speed tools. V2O5 catalyzes sulfuric acid production. Vanadium is essential to many species, found in haloperoxidases and an alternative nitrogenase.
Niobium and tantalum have very similar properties. Niobium–tin (Nb3Sn) alloys are superconducting at 4.2 K and used in NMR spectrometer and MRI scanner magnets.
(b) Binary Compounds
V2O5 structure consists of sheets of V(=O)O4 square-based pyramids. Depending on pH, the oxide form varies from [MO4]3− to [MO2]+, with many polyoxometallates in between.
A polyoxometallate is an oxoanion containing more than one metal atom. They form when mononuclear oxometallates condense at low pH. Example: acidification of [MoO4]2− gives [Mo6O19]2− (six edge-shared octahedra).
Applications include reversible reduction catalysts, luminescent materials, magnetic data storage, and potential medicinal uses (antitumoral, antiviral).
Problem: What species forms when acidic V2+ is exposed to O2?
Answer: Since E°(O2/H2O) = 1.229 V, V2+ will be oxidized all the way to VO2+ (+5 state):
19.6 Group 6: Chromium, Molybdenum, and Tungsten
(a) Occurrence and Uses
Chromium (40% from South Africa) is extremely hard and corrosion-resistant. Used in stainless steels (10-40%) and chrome plating. Essential to humans for glucose regulation.
Molybdenum (80% used in steels, up to 10%). Essential to all species in 20+ enzymes for oxygen atom transfer. Found in the FeMo cofactor of nitrogenase.
Tungsten has the highest melting point of any metal (filaments in incandescent lightbulbs). Tungsten carbide tips drill bits and saw blades. Only third-row d metal with a biological role (formate dehydrogenase in microbes).
(b) Binary Compounds
CrO3 (chains of vertex-sharing tetrahedra) and [CrO4]2−/[Cr2O7]2− are strongly oxidizing. MoO3 and WO3 (linked MO6 octahedra) are not rapidly oxidizing—reflecting increased stability of high oxidation states for 4d/5d metals.
CrO2 (rutile structure) exhibits excellent ferromagnetic properties, used in high-quality audio/video tapes. Cr2O3 (viridian) is a widely used green pigment.
MS2 (M = Mo, W) adopt layered structures used as solid-state lubricants.
(c) Complex Oxides: Bronzes
Tungsten bronzes (MxWO3, 0 < x ≤ 1) are nonstoichiometric compounds with metallic properties. While WO3 is an insulator (d0), alkali metal presence reduces W and introduces electrons into a conduction band, giving high electrical conductivity and lustre.
D orbitals can overlap to form:
- σ bond: from dz²–dz² overlap
- π bonds (2): from dzx or dzy overlap
- δ bonds (2): from face-to-face dxy or dx²−y² overlap
A quintuple bond (σ²π⁴δ⁴) is possible with 5 d electrons per metal—observed in Cr(I) compounds with Cr–Cr = 183.5 pm (vs 258 pm in bulk Cr).
[Re2Cl8]2− has a quadruple bond (σ²π⁴δ²). The eclipsed Cl arrangement (sterically unfavorable) is locked by the δ bond.
(e) Organometallic Compounds
The 18-electron neutral hexacarbonyls [M(CO)6] are extremely stable white solids that can be handled in air. Bis(arene) complexes and cyclopentadienyl derivatives are well known. Tungsten forms alkylidene and alkylidyne complexes with formal M=C and M≡C bonds.
19.7 Group 7: Manganese, Technetium, and Rhenium
(a) Occurrence and Uses
Manganese (80% reserves in South Africa as pyrolusite MnO2). ~500 billion tonnes exist in ocean floor nodules. Used in steel (1-13%) and alkaline batteries (MnO2 → Mn2O3). Most notable biological role: the active site for photosynthetic O2 evolution.
Technetium was the first unstable element synthesized (1936). 99mTc (t½ = 6 hours, β emission) is used medically as a radioactive tracer in compounds like Cardiolyte® for heart imaging.
Rhenium was the last stable nonradioactive element discovered (1925). One of the rarest metals; used in high-temperature jet engine alloys and as a platinum co-catalyst for alkane reforming.
(b) Binary Compounds
Mn forms oxides MnO, Mn2O3, MnO2, and Mn2O7. Tc and Re only form MO2, MO3, and M2O7. The +7 oxides dissolve in water to give [MO4]− ions—permanganate is very powerful oxidizer; pertechnate and perrhenate are less oxidizing.
Binary MX7 halides only represented by ReF7. MnF3/MnF4 equilibrium is used to purify fluorine.
(d) Coordination Complexes
Mn(II) is the most stable form in aqueous solution with high-spin d5 configuration (stabilized by exchange energy). Mn(II) complexes have no LFSE, show little geometry preference, and are essentially colorless (no allowed d-d transitions).
Tc and Re coordination chemistry is dominated by high-oxidation-state complexes with oxido and nitrido ligands.
19.8 Group 8: Iron, Ruthenium, and Osmium
(a) Occurrence and Uses
Iron is the most abundant transition metal in biology (>4 g per human). Roles include O2 transport (haemoglobin), electron transfer, acid–base catalysis, gene regulation, and magnetic field sensing. Used as catalyst in the Haber process for ammonia synthesis.
Ruthenium is used in platinum/palladium alloys and RuO2 in chip resistors (>50% consumption). [Ru(bpy)3]2+ is a photosensitizer.
Osmium is the densest element (22.6 g cm−3), twice as dense as lead. OsO4 is used in organic synthesis but is highly toxic.
(b) Binary Compounds
Fe3O4 (magnetite, spinel structure) may be permanently magnetized (lodestone)—used in navigational compasses for 800+ years. Fe(VI) exists in [FeO4]2− compounds. FeS2 (iron pyrites, "fool's gold") contains the disulfide ion S22−.
Os slowly oxidizes in air to volatile OsO4. Both RuO4 and OsO4 are yellow, volatile, and extremely toxic.
(c) Complex Oxides
Ferrites (AB2O4 spinels with B = Fe3+): Soft ferrites (Mn1−xZnxFe2O4) for transformer cores. Hard ferrites (SrFe12O19) as permanent magnets.
Iron-based superconductors: Ln(O,F)FeAs with Tc up to 53 K; LiFeAs (Tc = 18 K).
(d) Coordination Complexes
The balance between high- and low-spin for Fe(III) is delicate—complexes with low-field ligands (H2O, halides) are high-spin; with high-field ligands (CN−, bpy) are low-spin. Spin-crossover complexes change spin state with temperature, pressure, or solvent.
(e) Organometallic Compounds
Ferrocene [(η5-C5H5)2Fe]: Discovery in the 1950s kick-started modern organometallic chemistry. Very stable 18-electron sandwich complex. [Fe(CO)5] is trigonal bipyramidal; forms clusters [Fe2(CO)9] and [Fe3(CO)12].
Grubbs catalyst (Ru carbene complex): Active in alkene metathesis (2005 Nobel Prize).
19.9 Group 9: Cobalt, Rhodium, and Iridium
(a) Occurrence and Uses
Cobalt compounds have been used for millennia for rich blue glass coloring (detected in Egyptian sculptures, 3rd century BC Persian jewelry, Pompeii ruins). Vitamin B12 (cobalamin) has organometallic cobalt at its heart—essential to all animal life.
Rhodium (~20 tonnes/year): Highly reflective; used to coat optical fibers and mirrors. 80% used in catalytic converters. Also used in the Monsanto acetic acid process.
Iridium is the most corrosion-resistant metal (~3 tonnes/year). Used in X-ray telescope reflectors and the Cativa process for methanol carbonylation.
(b) Binary Compounds
Most stable oxidation state: +2 for cobalt, +3 for rhodium and iridium. High-oxidation-state compounds (RhF6, IrF6) are strongly oxidizing and often unstable.
(c) Complex Oxides
LiCoO2 (layer structure): Used in rechargeable battery systems. CoAl2O4 (spinel): Deep royal blue pigment (tetrahedral Co(II)).
(d) Coordination Complexes
Co(II) forms more tetrahedral complexes than any other d metal (d7 minimizes LFSE difference between octahedral and tetrahedral). Octahedral complexes are pink/red; tetrahedral are intensely blue.
Rh and Ir are dominated by octahedral low-spin d6 M3+ complexes.
(e) Organometallic Compounds
16-electron square-planar Rh(I) and Ir(I) complexes (e.g., Vaska's complex) readily undergo oxidative addition to give 18-electron octahedral M(III) complexes. This enables homogeneous hydrogenation (Wilkinson's catalyst) and methanol carbonylation.
19.10 Group 10: Nickel, Palladium, and Platinum
(a) Occurrence and Uses
Nickel (60% in corrosion-resistant steel): The Mond process uses volatile [Ni(CO)4] for purification. Important in microbial biology for H2 oxidation, H2 production, and CO2 reduction. [Ni(CO)4] is extremely toxic.
Palladium: Majority used in catalytic converters. Widely used in synthesis (hydrogenation, carbon–carbon bond forming—2010 Nobel Prize).
Platinum: Most ductile pure metal. Major uses in catalytic converters and jewelry. cis-[PtCl2(NH3)2] (cisplatin) derivatives are widely used anticancer treatments—platinum binds to DNA preventing cell replication.
(b) Binary Compounds
PtF6 is very strongly oxidizing—can oxidize both O2 and xenon. Pd readily absorbs H2 to form interstitial hydride with greater H density than solid H2. Raney nickel (porous form) absorbs H2 for delivery to organic substrates.
(c) Hydroxides and Oxides
Ni metal hydride batteries use Ni(OH)2 ⇌ NiO(OH) transformation. LaNi5H6 contains more H2 per unit volume than liquid H2—potential hydrogen storage material.
NiO/YSZ composites: Anodes in solid oxide fuel cells.
(d) Coordination Complexes
Ni2+ shows octahedral, trigonal bipyramidal, square-based pyramidal, tetrahedral, and square-planar geometries. Pd2+ and Pt2+ are almost invariably square-planar (d8 configuration). Pt(IV) complexes are low-spin octahedral d6 and very inert.
(e) Organometallic Compounds
[Ni(CO)4] (tetrahedral 18-electron) and Zeise's salt K[(CH2=CH2)PtCl3] are historic compounds. Pd(II) 16-electron square-planar complexes are used in hydrogenation, Wacker process, and Pd-mediated C–C bond formation.
19.11 Group 11: Copper, Silver, and Gold
(a) Occurrence and Uses
Copper (15 million tonnes/year): Very high electrical and thermal conductivity. Reserves predicted to last only 15-20 years. Essential to biology (10+ Cu-dependent enzymes including cytochrome c oxidase). Also found in hemocyanin (blue O2-transport protein in arthropods/molluscs).
Silver: Highest electrical and thermal conductivity of all metals. Ag+ is deadly to bacteria and viruses—used in medical dressings and antibacterial clothing.
Gold (~2000 tonnes/year): Most malleable metal (1 g can be beaten into >1 m2 sheet). 75% used in jewelry. Colloidal gold nanoparticles vary from red to purple depending on size—used as pigments for centuries.
(b) Binary Compounds
Most stable state: +2 for Cu; +1 and +3 for Ag and Au. Cu(I) compounds disproportionate in solution. Cu2O (linear Cu+ coordination) is used as a red pigment and in antifouling paint. AuF5 and Ag(II) compounds are known but strongly oxidizing.
(c) Complex Chalcogenides: High-Temperature Superconductors
Over 50 different complex copper oxide superconductors discovered since 1986, including YBa2Cu3O7-d (YBCO) and Bi2Sr2CaCu2O8 (BISCO). All contain sheets of linked CuO4 square planes with Cu in average oxidation state between +2.15 and +2.35.
Copper indium gallium selenide (CIGS): Solar cell efficiencies near 20%.
(d) Coordination Complexes
Cu(II) d9 complexes are Jahn–Teller distorted. Ag+ d10 shows little geometry preference (linear, trigonal, tetrahedral all known). Au(III) d8 complexes are square-planar; Au(I) are linear.
19.12 Group 12: Zinc, Cadmium, and Mercury
(a) Occurrence and Uses
Zinc (4th most used metal, ~10 million tonnes/year): 50%+ used for galvanizing steel. ZnO used in vulcanization, medical applications (calamine, antibacterial), white pigment, UV-blocking. Second most abundant d metal in biology (200+ enzymes including carbonic anhydrase; Zn-finger transcription factors).
Cadmium: 90% used in rechargeable batteries. An accumulative poison—nonreversibly replaces zinc in enzymes.
Mercury: Unique liquid metal at room temperature (filled subshells + relativistic effects + lanthanoid contraction). Cinnabar (HgS, vermillion) used as red pigment since Palaeolithic times (~30,000 years ago). Highly toxic—uses being phased out.
(b) Binary Compounds
Zn and Cd chemistry is almost exclusively M2+ d10. Mercury also forms [Hg2]2+ cation with Hg–Hg single bond. HgF4 (d8) reported in low-temperature matrices would make Hg a transition metal.
ZnO polymorphs: wurtzite and zinc-blende (4:4 coordination); transforms to rock-salt at >10 GPa. HgO contains linear O–Hg–O units; heating decomposes to Hg and O2 (Priestley first produced pure O2 this way, 1774).
Heavy metals like Hg bind tightly to thiol groups in proteins. Mercury salts (Hg2+) are relatively harmless because membranes are impermeable to ions. However:
- Mercury vapor: Highly toxic—neutral atoms pass through lung membranes and blood–brain barrier
- Methylmercury (CH3Hg+): Most hazardous—forms neutral CH3HgCl which passes through membranes
The worst case was Minamata, Japan (1950s): Fish accumulated methylmercury to ~100 ppm from industrial discharge. Thousands were poisoned; infants suffered mental disabilities from in utero exposure.
In MX compounds, valence band ≈ X2− orbitals; conduction band ≈ M2+ orbitals.
| O | S | Se | Te | |
|---|---|---|---|---|
| Zn | 3.37 eV | 3.54 eV | 2.7 eV | 2.25 eV |
| Cd | 2.37 eV | 2.42 eV | 1.84 eV | 1.49 eV |
ZnO (band gap >3.1 eV): Absorbs only UV—used in sunscreens; white pigment.
CdS (absorbs blue): Bright yellow pigment (cadmium yellow).
CdSe (absorbs all except red): Red pigment (cadmium red).
CdTe: Used in solar cells and infrared detectors.
(d) Coordination Complexes
Both tetrahedral and octahedral geometries (d10—no CFSE preference). Zn2+ is borderline hard/soft; Cd2+ and Hg2+ are distinctly soft. [Hg2]2+ complexes are linear X–Hg–Hg–X.
Problem: What is the bond order of the Hg–Hg bond?
Answer: Hg(I) configuration is d10s1. The 20 d electrons fill all bonding and antibonding d orbitals (no net bonding). The two remaining s electrons occupy the σ bonding orbital from s–s overlap, giving a single Hg–Hg bond.
Exercises
What is the highest group oxidation state observed for the first-row transition metals? Give an example of an oxo species. Contrast the stability down the group.
Construct Frost diagrams for Cr, Mo, and W in acidic conditions. Predict (a) the most oxidizing state and (b) any disproportionation susceptibility.
Explain why TiO2, V2O5, and CrO3 are well-known compounds but FeO4 and Co2O9 have not been prepared.
Explain why isostructural HfO2 and ZrO2 have densities of 9.68 g cm−3 and 5.73 g cm−3, respectively.
Answer: Despite similar ionic radii (lanthanoid contraction), Hf has nearly twice the atomic mass of Zr (178.5 vs 91.2), leading to much higher density in the isostructural oxide.
Many d-metal compounds are used as pigments. Apart from colour, what properties must a compound possess to be useful as a pigment?
Properties include: chemical stability, light-fastness, non-toxicity, insolubility, opacity/covering power, and compatibility with the medium.