Why are orthonitrate ions not found in nature?

Question

In general chemistry we often encounter $\ce{H3PO4}$, which got me wondering if I can replace the $\ce{P}$ in $\ce{H3PO4}$ with $\ce{N}$ giving us $\ce{H3NO4}$ , does such a compound exist?

Both phosphorous and nitrogen are in group 15 in the periodic table implying they have same number of valence electrons making the lewis structures for both $\ce{H3NO4}$ and $\ce{H3PO4}$ the same with octet configuration.

I do notice compounds exist which do not follow the octet rule (eg: $\ce{S}$ in $\ce{SO3}$) which makes the octet rule wrong but still why do we not find $\ce{NO4-}$ ions in nature?

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Possibly helpful info: As far as I know $\ce{H3NO4}$ has never been observed in real life but $\ce{Na3NO4}$ has been observed.

The compound forms white crystals that are very sensitive to atmospheric moisture and $\ce{CO2}$:

X-ray structural analyses have shown that the $\ce{NO4^3-}$ ion has regular $T_d$ (op note: $T_d$ means tetrahedral I think) symmetry with the unexpectedly small N - O distance of 139pm. This suggests that substantial polar interactions are superimposed on the N - O single bonds since the $d_\pi$ orbitals on N are too high in energy to contribute significantly to multiple covalent bonding. It further implies that $d_\pi$-$p_\pi$ interactions need not necessarily be invoked to explain the observed short interatomic distance in the isoelectronic oxoanions $\ce{PO4^3-}$, $\ce{SO4^3-}$ and $\ce{ClO4^-}$. [source, page 472]

But how did they observe $\ce{Na3NO4}$ was present? In the above book's link a source was mentioned: https://onlinelibrary.wiley.com/doi/epdf/10.1002/anie.197705341. This source's abstract says

The existence of the $\ce{NO4^3-}$ ion has now been proved by Raman spectroscopy. X-ray structure analysis has so far been precluded by the non-availability of single crystals of the extremely moisture- and $\ce{CO2}$-sensitive compound $\ce{Na3NO4}$.

Answer 1

Modern molecular orbital theory posits that in tetrahedral species with terminal oxygen atoms, pi bonding of the central atom to oxygen exists because formal "lone pairs" on the oxygen overlap sigma-antibonding orbitals between the central atom and its other neighbors. But this seems to work better in phosphate ion and in another relatively stable species, trifluoramine oxide ($\ce{ONF3}$), than in orthonitrate ion.

Since trifluoramine oxide has the same central atom as orthonitrate, we can compare pi back-donation in these two species via nitrogen-oxygen bond lengths and illustrate the value of having strongly polar sigma bonds as the pi acceptor. While the reference in the question points out that the $\ce{N – O}$ bond is shortened to 139 pm in orthonitrate, Wikipedia citing [1] reports that in trifluoramine oxide it is only 115.8 pm. The pi back-donation is clearly stronger in the more stable compound.

For pi back-donation in a tetrahedral molecule to work well, the sigma bonds should be highly polarized so that the antibonding orbitals lie mostly on the central atom where the overlap occurs. The $\ce{N – F}$ sigma bonds in trifluoramine oxide appear polar enough to promote pi back-donation from oxygen to the central atom, and (given the lower electronegativity of phosphorus), the same would be true of the $\ce{P – O}$ bonding in phosphate. But the $\ce{N – O}$ sigma bonds would be less polar, and so is a poorer pi acceptor from other $\ce{N – O}$ bonds than either the $\ce{N – F}$ bonds in trifluoramine oxide or the $\ce{P – O}$ bonds in phosphate ion.

Cited reference

1. Plato, Vernon; Hartford, William D.; Hedberg, Kenneth (November 1970). "Electron-Diffraction Investigation of the Molecular Structure of Trifluoramine Oxide, F3NO". The Journal of Chemical Physics. 53 (9): 3488–3494. doi:10.1063/1.1674522.