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Helium has two electrons. The only configuration they can have (ground state) is spin $\frac{1}{2}$ for one and $-\frac{1}{2}$ for the other one, by the Pauli exclusion principle, which is definitely a singlet state. So I'm assuming it's something to do with excited states. If that's the case, there's an exercise in my textbook which asks for an explanation of the energy ordering of the spin triplet state of helium, but wouldn't that depend on which excited state it was in?

I have read the answers to the related question 'What causes the triplet state in helium?' and still don't understand what the 'energy ordering' would be.

user13948
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    Why do you think it has something to do with excited states? That a combined system of two spin-1/2 particles is the sum of a spin-0 singlet and a spin-1 triplet is a standard result that holds very generally. – ACuriousMind Oct 31 '16 at 12:32
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    Take a look here. – Charlie Oct 31 '16 at 12:36
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    This link should clear your doubts.....and i have to disagree with @ACuriousMind here; in the ground state, both the electrons are in the $1s$ orbital which means their spin should be antisymmetric according to the exclusion principle...meaning ground state is the singlet state in case of Helium.......for it to have a triplet state, same spins imply electron must occupy different orbitals (spatial states with different quantum numbers) $1s$ and the next energy level $2s$...which is necessarily an excited state – Prasad Mani Oct 31 '16 at 13:22
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    My conclusion being that singlet state (ground state) has less energy than the triplet state (excited state).........it is an altogether different question though related ....that which of the excited states (triplet or singlet) is energetically more favourable...the answer is in the link posted by @Charlie – Prasad Mani Oct 31 '16 at 13:27
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    @Muthumanimaran What was meant is that there is only one configuration IN ground state not that the only possible state IS ground state. – user13948 Oct 31 '16 at 13:44
  • This question could use a lot of work in clarification. As it stands, it's not even really a question: you ask "how can helium have a spin triplet state?" to which the answer is "because there's more than the ground state"; if you want to ask a subtler question then at least get rid of the clickbait in the title. Beyond that, you mention "an exercise in my textbook which asks for an explanation of the energy ordering of the spin triplet state of helium", but without more details, it isn't really enough to say anything meaningful about "energy orderings" of one state w.r.t. ... itself? – Emilio Pisanty Oct 31 '16 at 14:01
  • Possible duplicate http://physics.stackexchange.com/questions/288357/why-is-nuclear-force-spin-dependent – Mass Oct 31 '16 at 16:33

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If we ignore spin-orbital coupling, helium atom's wavefunction can be represented by a product of spin part and spatial part. Triplet state is a state where spin part of the wavefunction is symmetric with respect to exchange of two electrons.

This means that the spatial part must be antisymmetric, since electrons are fermions. But this implies that there must be a node in the wavefunction — a hypersurface where the wavefunction vanishes. This can only happen in an excited state, since ground-state solution of non-symmetrized Schrödinger equation has no nodes and is always non-degenerate, so has strictly less energy. This gives you the answer about ordering of two lowest energy states with zero angular momentum.

Ruslan
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