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What is the fundamental argument behind explaining why Ta metal is so inert and does not usually participate in corrosion? I know that it forms a protective oxide, but nothing explains why in an acidic solution it is resistant to nearly everything (aside from HF). I want to know if it has to do with a bond strength of the metal or the molecular orbitals. An in-depth citation is required.

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I think the answer to your question can be described based primarily on thermodynamic considerations. Ta has very high fusion (25 kJ/mol), vaporization (760 kJ/mol) and atomization (780 kJ/mol) enthalpies which are a result of strong metal-metal bonding in the solid (see Greenwood and Earnshaw, Chemistry of the Elements).

To further understand the protective nature of the native oxide that forms on Ta, it is fruitful to look at an Ellingham diagram, which describes the stability of a metal oxide as a function of temperature. For more authoritative sources than the Wikipedia page, see a comprehensive Inorganic Chemistry textbook such as those by Shriver and Atkins or Housecroft and Sharpe. I found this site particularly interesting for purposes of visualizing Ellingham diagrams and used it to make the following plot:

enter image description here

(Apologies for the color scheme, which was not adjustable)

Here I've plotted the free energy for the oxide formation of tantalum oxide along with oxides of iron and aluminum. The x-axis is temperature. The large negative values for each of these oxides indicates that they are all thermodynamically favorable at the temperatures plotted. Room temperature would be very slightly to the left of the intersection of the x and y-axes. A complete analysis of the stability of the metal oxides would also require consideration of kinetics, but we can use thermodynamics to postulate that the very large negative values for the free energy of formation of the tantalum oxide are one factor in the stability of the oxide film. I'll leave it to the OP to play around with thermochemical cycles, which should demonstrate why the oxide films are resistant to many types of acids.

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I think, there are no secret properties of tantalum. The primer corrosion resistant is thin layer of Tantalum pentoxide $(\ce{Ta2O5})$. It's more case of a reaction of an oxide with fluorides. Here some related quotes from the book Chemistry of Tantalum and Niobium Fluoride Compounds by Anatoly Agulyansky:

As opposed to the oxides, fluoride compounds are characterized by the formation of mostly ionic bonds. This peculiarity is related to fluorine's high electronegativity.

...

Oxygen and fluorine ions have very similar ionic radii. This steric similarity ensures relatively easy substitution of the oxygen in the compounds, by fluorine ions. Such substitution opens up huge possibilities for the synthesis of oxyfluoride compounds with desired crystal structure and properties.

Fluorine-oxygen substitution, yielding oxyfluoride compounds, can be performed without changing the initial oxide crystal structure, provided the changes in the anionic sublattice are compensated by appropriate substitutions in the cationic sublattice. In these particular cases, the properties of the compounds will change due to variations in the character of the chemical bonds. On the other hand, fluorine-oxygen substitution can also cause cardinal changes in the initial crystal structure. Hence, compounds with desired structures and specific properties can be obtained only through controlled fluorine-oxygen substitution.

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  • $\begingroup$ "I think, there is no secret properties of Tantal." I disagree. Many metals, such as aluminum, readily form oxides too. Yet, these are surprisingly susceptible to corrosion in acidic solutions. $\endgroup$ – sciencenewbie Jun 23 '13 at 22:15
  • $\begingroup$ That doesn't address the way that magnesium, iron and nickel are all protected against hydrofluoric attack. They all have oxide layers. $\endgroup$ – user2617804 Dec 17 '14 at 11:09
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Other reactive metals like Tantalum with highly protective oxide layers are Zirconium, Hafnium (though most Zirconium contains Hafnium), Titanium (though it needs oxidising ions or platinum alloying to handle acid solutions), Chromium.

Aluminium and even iron will handle concentrated nitric and sulfuric acids due to protective oxide layers formed. Tantalum is generally the best and most all-around active metal to handle acid and other solutions.

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