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In physics the definition of a noble metal is even more strict. It is required that the [[atomic orbital|d-bands]] of the [[band structure|electronic structure]] are filled. Taking this into account, only copper, silver and gold are noble metals, as all d-like band are filled and don't cross the [[Fermi level]]. For platinum two d-bands cross the Fermi level, changing its chemical behaviour; it is used as a [[catalyst]]. The different reactivity can easily be seen while preparing clean metal surfaces in [[ultra high vacuum]]; surfaces of noble metals (e.g., gold) are easy to clean and stay clean for a long time, while those of platinum or palladium, for example, are covered by [[carbon monoxide]] very quickly.{{Fact|date=November 2008}} |
In physics the definition of a noble metal is even more strict. It is required that the [[atomic orbital|d-bands]] of the [[band structure|electronic structure]] are filled. Taking this into account, only copper, silver and gold are noble metals, as all d-like band are filled and don't cross the [[Fermi level]]. For platinum two d-bands cross the Fermi level, changing its chemical behaviour; it is used as a [[catalyst]]. The different reactivity can easily be seen while preparing clean metal surfaces in [[ultra high vacuum]]; surfaces of noble metals (e.g., gold) are easy to clean and stay clean for a long time, while those of platinum or palladium, for example, are covered by [[carbon monoxide]] very quickly.{{Fact|date=November 2008}} |
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The noble metalls sorted by their chemical "nobelity" are |
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{| class=wikitable |
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!element !! group !! reaction !! potential |
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|| Gold || Ib/6 || Au → Au<sup>3+</sup> || 1.498 V |
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|| Platinum || VIIIb/6 || Pt → Pt<sup>2+</sup> || 1.2 V |
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|| Iridium || VIIIb/6 || Ir → Ir<sup>2+</sup> || 1.1 V |
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|| Palladium || VIIIb/5 || Pd → Pd<sup>2+</sup> || 0.987 V |
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|| Pollonium || VIa/6 || Po → Po<sup>2+</sup> || 0.9 V |
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|| Osmium || VIIIb/6 || Os → Os<sup>2+</sup> || 0.85 V |
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|| Silver || Ib/5 || Ag → Ag<sup>+</sup> || 0.799 V |
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|| Mercury || IIb/6 || Hg → Hg<sup>2+</sup> || 0.7925 V |
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|| Rhodium || VIIIb/5 || Rh → Rh<sup>2+</sup> || 0.6 V |
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|| Ruthenium || VIIIb/5 || Ru → Ru<sup>2+</sup> || 0.45 V |
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|| Copper || Ib/4 || Cu → Cu<sup>2+</sup> || 0.337 V |
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|| Bismuth || Va/6 || Bi → Bi<sup>3</sup> || 0.32 V |
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|| Technetium || VIIb/5 || Tc → Tc<sup>4+</sup> || 0.272 V |
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|| Rhenium || VIIb/6 || Re → Re<sup>4+</sup> || 0.259 V |
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Bismuth and Polonium can be questioned to be only metalloids and thus ruled out to get "noble metal" status. Also many people consider metals which are not nobler than copper as "semi-noble", only. |
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==See also== |
==See also== |
Revision as of 17:24, 24 June 2009
Noble metals are metals that are resistant to corrosion or oxidation, unlike most base metals. They tend to be precious metals, often due to rarity in the crust of the Earth. The noble metals are considered to be (in order of increasing atomic number)[citation needed]
Some of the noble metals can be dissolved in aqua regia, a highly concentrated mixture of acids.
The term can also be used in a relative sense. A "Galvanic series" is a hierarchy of metals (or other electrically conductive materials, including composites and semimetals) that runs from noble to active, and allows designers to see at a glance how materials will interact in the environment used to generate the series. In this sense of the word, graphite is more noble than silver (even though it is alchemically more base) and the relative nobility of many materials is highly dependent upon context, as for aluminium and stainless steel in conditions of varying pH.[citation needed]
In physics the definition of a noble metal is even more strict. It is required that the d-bands of the electronic structure are filled. Taking this into account, only copper, silver and gold are noble metals, as all d-like band are filled and don't cross the Fermi level. For platinum two d-bands cross the Fermi level, changing its chemical behaviour; it is used as a catalyst. The different reactivity can easily be seen while preparing clean metal surfaces in ultra high vacuum; surfaces of noble metals (e.g., gold) are easy to clean and stay clean for a long time, while those of platinum or palladium, for example, are covered by carbon monoxide very quickly.[citation needed]
The noble metalls sorted by their chemical "nobelity" are
element | group | reaction | potential |
---|---|---|---|
Gold | Ib/6 | Au → Au3+ | 1.498 V |
Platinum | VIIIb/6 | Pt → Pt2+ | 1.2 V |
Iridium | VIIIb/6 | Ir → Ir2+ | 1.1 V |
Palladium | VIIIb/5 | Pd → Pd2+ | 0.987 V |
Pollonium | VIa/6 | Po → Po2+ | 0.9 V |
Osmium | VIIIb/6 | Os → Os2+ | 0.85 V |
Silver | Ib/5 | Ag → Ag+ | 0.799 V |
Mercury | IIb/6 | Hg → Hg2+ | 0.7925 V |
Rhodium | VIIIb/5 | Rh → Rh2+ | 0.6 V |
Ruthenium | VIIIb/5 | Ru → Ru2+ | 0.45 V |
Copper | Ib/4 | Cu → Cu2+ | 0.337 V |
Bismuth | Va/6 | Bi → Bi3 | 0.32 V |
Technetium | VIIb/5 | Tc → Tc4+ | 0.272 V |
Rhenium | VIIb/6 | Re → Re4+ | 0.259 V |
Bismuth and Polonium can be questioned to be only metalloids and thus ruled out to get "noble metal" status. Also many people consider metals which are not nobler than copper as "semi-noble", only.
See also
Silver and copper corrode and oxidize easily and readily, thus the copper sheets with a patina of oxidation used in architectural designs and the resultant market for a myriad of silver polishing compounds.[citation needed]
External links
- To see which bands cross the Fermi level, the Fermi surfaces of almost all the metals can be found at the Fermi Surface Database
- The following article might also clarify the correlation between band structure and the term noble metal: Hüger, E.; Osuch, K. (2005). "Making a noble metal of Pd". EPL (Europhysics Letters). 71: 276. doi:10.1209/epl/i2005-10075-5.
{{cite journal}}
: CS1 maint: multiple names: authors list (link)