Bonding

Metallic Bonding

"Sea of electrons" — delocalized bonding among metal atoms gives unique properties

Metallic bonding is the bonding model for metals — positively charged metal cations held in fixed positions by a "sea" of delocalized valence electrons. Unlike ionic (electron transfer) or covalent (localized sharing), metallic bonding has electrons free to move throughout the lattice. Explains: high electrical conductivity (mobile electrons), thermal conductivity, ductility/malleability (cations can shift without breaking bonds), shine (electrons interact with light), high melting points. Strength varies: Hg (BP -39°C, weak) to W (BP 3422°C, very strong).

  • ModelCation lattice + delocalized electron sea
  • Key featureMobile electrons enable conductivity
  • Strength rangeHg (weak) to W (very strong)
  • PropertiesConductive, malleable, ductile, shiny, dense
  • Bond characterNon-directional (unlike covalent)
  • Crystal structuresBCC, FCC, HCP (close-packed)

Interactive visualization

Press play, or step through manually. The visualization is yours to drive — try it before reading on.

Open visualization fullscreen ↗

Watch the 60-second explainer

A condensed visual walkthrough — narrated, captioned, under a minute.

Why metallic bonding matters

  • Engineering materials. Steel, aluminum, alloys.
  • Electrical wiring. Conductivity from electron sea.
  • Construction. Strength, ductility.
  • Heat transfer. Thermal conductivity.
  • Decoration. Reflective shine.
  • Currency. Coins (mostly metals).
  • Catalysis. Surface reactions on transition metals.

Common misconceptions

  • Metallic bonds same as covalent. Delocalized vs localized.
  • Electron sea is literal liquid. Quantum mechanical bands.
  • All metals shiny. Sodium oxidizes; many darken.
  • Ductile = malleable. Different (drawn into wires vs hammered into sheets).
  • Pure metals are strongest. Often alloys are stronger.
  • Metals all conduct same. Conductivity varies widely (Cu high, Bi low).

Frequently asked questions

How does metallic bonding work?

Metal atoms have low ionization energies — easily lose valence electrons. In solid metal: each atom contributes 1-3 valence electrons to a shared "sea." Result: lattice of metal cations (positive) bathed in mobile electrons (negative). Cations attracted to electron sea — bonding. No specific atom owns specific electron — fully delocalized.

Why are metals conductive?

Electron sea is mobile. Apply voltage → electrons drift toward positive electrode → current flows. Same mobility explains thermal conductivity (electrons carry heat), light reflection (interact with electromagnetic radiation), ductility (electrons reorganize to maintain bonding when atoms shift).

Why are metals malleable?

Non-directional bonding. Push metal — atoms slide past each other; electron sea reorganizes to maintain bonding. Doesn't break. Compare ionic crystals (NaCl): hit them and they shatter — sliding ions creates like-charge repulsion. Metals: sliding cations still surrounded by electrons. Property: deformable.

Why are some metals harder than others?

Bond strength. Depends on: number of valence electrons donated (more = stronger), size of cation (smaller = stronger), packing efficiency (close-packed = stronger). Sodium (1 e-, large): soft, low BP (98°C). Tungsten (6 e-, smaller): very hard, BP 3422°C. Mercury: anomalously weak — relativistic effects.

What's an alloy?

Mixture of metals (or metal + nonmetal) with metallic bonding. Two types: (1) Substitutional — different-sized atoms replace some host atoms (brass = Cu + Zn). (2) Interstitial — small atoms fit between host atoms (steel = Fe + C). Often stronger than pure metals (different sizes prevent slipping). Common: bronze, brass, steel, sterling silver.

How does metallic bonding compare to other bonds?

Different model. Ionic: localized electrostatic (cation + anion). Covalent: localized sharing (electron pair between specific atoms). Metallic: delocalized; electrons free to move; bonding without specific partners. All strong bonds (>100 kJ/mol typically) but very different properties — explains why metals so distinct.

What about transition metals?

d-electrons can also participate in bonding sea. Often stronger metallic bonds. Higher melting points: Fe 1538°C, Mo 2622°C, W 3422°C. Color: d-d transitions in some transition metals (Au gold, Cu reddish). Magnetic: Fe, Ni, Co ferromagnetic due to unpaired d electrons in bands.