Superatom

Aluminium clusters

Summarize

Perspective

Certain aluminium clusters have superatom properties. These aluminium clusters are generated as anions (Al⁻
_n with n = 1, 2, 3, … ) in helium gas and reacted with a gas containing iodine. When analyzed by mass spectrometry one main reaction product turns out to be Al
₁₃I⁻
.^[3] These clusters of 13 aluminium atoms with an extra electron added do not appear to react with oxygen when it is introduced in the same gas stream, indicating a halide-like character and a magic number of 40 free electrons. Such a cluster is known as a superhalogen.^[4]^[5]^[6]^[7] The cluster component in Al
₁₃I⁻
ion is similar to an iodide ion or better still a bromide ion. The related Al
₁₃I⁻
₂ cluster is expected to behave chemically like the triiodide ion.^[3]

Similarly it has been noted that Al
₁₄ clusters with 42 electrons (2 more than the magic numbers) appear to exhibit the properties of an alkaline earth metal which typically adopt +2 valence states. This is only known to occur when there are at least 3 iodine atoms attached to an Al⁻
₁₄ cluster, Al
₁₄I⁻
₃. The anionic cluster has a total of 43 itinerant electrons, but the three iodine atoms each remove one of the itinerant electrons to leave 40 electrons in the jellium shell.^[8]^[9]

It is particularly easy and reliable to study atomic clusters of inert gas atoms by computer simulation because interaction between two atoms can be approximated very well by the Lennard-Jones potential. Other methods are readily available and it has been established that the magic numbers are 13, 19, 23, 26, 29, 32, 34, 43, 46, 49, 55, etc.^[10]

Al
₇ = the property is similar to germanium atoms.
Al
₁₃ = the property is similar to halogen atoms, more specifically, chlorine.
- Al
  ₁₃I⁻
  _x, where x = 1–13.^[11]^{[unreliable source?]}
Al
₁₄ = the property is similar to alkaline earth metals.
- Al
  ₁₄I⁻
  _x, where x = 1–14.^[11]
Al
₂₃
Al
₃₇
Al
₅O⁻
₄^[12]

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Other clusters

Li(HF)₃Li = the (HF)₃ interior causes 2 valence electrons from the Li to orbit the entire molecule as if it were an atom's nucleus.^[13]
Li(NH₃)₄ = has one diffuse electron orbiting around Li(NH₃)+4 core, i.e., mimics an alkali-metal atom.^[14]^[15]^{[unreliable source?]}
Be(NH₃)₄ = has two diffuse electrons orbiting around Be(NH₃)2+4 core, i.e., mimics He-atom.^[16]^[15]

VSi₁₆F = has ionic bonding.^[17]
A cluster of 13 platinum atoms becomes highly paramagnetic, much more so than platinum itself.^[18]

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Superatom complexes

Summarize

Perspective

Superatom complexes are a special group of superatoms that incorporate a metal core which is stabilized by organic ligands. In thiolate-protected gold cluster complexes, a simple electron counting rule can be used to determine the total number of electrons ( $n e$ ) which correspond to a magic number:

n_{e}=N\nu _{A}-M-z

where $N$ is the number of metal atoms (A) in the core, $v$ is the atomic valence, $M$ is the number of electron withdrawing ligands, and $z$ is the overall charge on the complex.^[19] For example the Au₁₀₂(p-MBA)₄₄ has 58 electrons and corresponds to a closed shell magic number.^[20]

Gold superatom complexes

Au₂₅(SMe)−18^[21]
Au₁₀₂(p-MBA)₄₄^[22]
Au₁₄₄(SR)₆₀^[23]

Other superatom complexes

Ga₂₃(N(Si(CH₃)₃)₂)₁₁^[24]
Al₅₀(C₅(CH₃)₅)₁₂^[25]
Re₆Se₈Cl₂ – In 2018 researchers produced 15-nm-thick flakes of this superatomic material. They anticipate that a monolayer will be a superatomic 2-D semiconductor and offer new 2-D materials with unusual, tunable properties.^[26]
Organo− Zintl-based superatoms: [Ge₉(CHO)₃] and [Ge₉(CHO)]^[27]
[Cu₄₃Al₁₂](Cp*)₁₂^[28]

Aluminium clusters

Other clusters

Superatom complexes

Gold superatom complexes

Other superatom complexes

See also

References

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