Difference between revisions of "Lead"

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An unusually hard lead mineral is plattnerite (PbO<sub>2</sub>).
 
An unusually hard lead mineral is plattnerite (PbO<sub>2</sub>).
Its crystal structure is the rutile structure.
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Its crystal structure is the [[rutile structure]].
 
Just like it is the case with the corresponding minerals of leads group members (carbon excluded):
 
Just like it is the case with the corresponding minerals of leads group members (carbon excluded):
  
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* Other members of the group: '''Lead''', [[Tin]], [[Germanium]], [[Silicon]], [[Carbon]]
 
* Other members of the group: '''Lead''', [[Tin]], [[Germanium]], [[Silicon]], [[Carbon]]
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* [[Chemical element]]
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[[Category:Chemical element]]

Latest revision as of 21:29, 13 June 2021

This article is a stub. It needs to be expanded.

An unusually hard lead mineral is plattnerite (PbO2). Its crystal structure is the rutile structure. Just like it is the case with the corresponding minerals of leads group members (carbon excluded):

  • Plattnerite PbO2 (Mohs 5.5; ~9.63g/ccm)
  • Cassierite SnO2 (Mohs 6-7; ~7.1g/ccm)
  • Argutite GeO2 (Mohs 6-7; ~6.28g/ccm)
  • Stishovite SiO2 (Mohs 9-9.5; 4.287g/ccm)

Interestingly in earths crust lead (Pb) is a bit more common than tin (Sn) which in turn is more common than germanium (Ge). Despite this is going upwards the periods of the periodic table. Normally for groups this is the other way around. Higher periods mean

Lead may be on the border of its level of abundance/scarcity that allows for its use of mass structural element. But given its toxicity when getting leached out in some way one might want to go for other options like the element above tin (Sn).

From a mechanical perspective the biggest reason for the use of lead would likely be its high density.

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