Table 4. The total energy difference and thermodynamic stability for different known and predicted RP phases from Quantum ESPRESSO⁶³.

RP oxides	Crystal symmetries from phonon calculations (ΔE)							Machine learning (ΔE)			ΔED
	P4/nmm	Pmn21	Pc	P21m	P2m	I2m	Pnma	P21212	Pbcm	Pca21
Known composition
Ca2IrO4 (Pbca)	—	—	—	—	—	—	—	—	—	—	+34
Ca2IrO4 (I4/mmm)	—	—	—	—	—	—	—	—	—	—	+156
New predictions
Stannates
NaLaSnO4	2.3	1.7	1.7	0	2.4	2.1	2.3	0	0.9	0.3	+68.6
NaPrSnO4	9.5	9.3	9.3	0	9.5	3.4	9.5	0	3.4	2.9	+79.9
NaNdSnO4	14.7	14.7	15.4	0	14.4	3.9	14.7	0	5.4	1.3	+81.2
NaGdSnO4	40.2	34.8	34.5	0	28.0	5.4	35.2	0	14.6	10.9	+75.6
NaYSnO4	46.8	37.1	36.4	0	32.5	5.9	37.6	0	16.6	11.7	+73.6
Ruthenates
NaLaRuO4	5.7	5.1	5.1	0	4.9	2.6	5.1	0	0.5	0.4	+72.2
NaPrRuO4	15.5	14.9	14.9	0	10.9	4.6	14.9	0	1.8	0.7	+78.3
NaNdRuO4	21.1	20.4	20.4	0	13.8	5.0	21.1	0	2.8	0.3	+53.3
NaGdRuO4	46.1	41.7	41.7	1.0	26.6	7.1	43.2	1.03	8.9	0	−14.1
NaYRuO4	179.9	47.6	47.6	2.6	32.7	8.8	49.2	2.6	11.4	0	−1.3

DFT, density-functional theory; RP, Ruddlesden-Popper; OQMD, Open Quantum Materials Database.

The total energy difference ΔE (in units of meV per atom) is taken with respect to the lowest energy phase. Crystal symmetry with ΔE=0 is identified as the ground state structure. For all ruthenates, we imposed ferromagnetic spin order on the Ru atom. ΔE^D in meV per atom is the total energy difference calculated from DFT for a decomposition reaction obtained from OQMD⁵⁰,⁵¹. Negative and positive values for ΔE^D indicate that the compound is thermodynamically stable and unstable, respectively. Corresponding decomposition reactions are given in Supplementary Note 4. For Ca₂IrO₄, space groups Pbca and I4/mmm are the theoretical ground state and high-symmetry structures¹⁵, respectively. Furthermore, in stannates structures initialized with Pnma symmetry converged to P2₁/m when R=La, Pr or Nd. Similarly, in ruthenates Pc structure converged to P1 when R=Pr, Gd or Y.