Quantum network node and protocols with multiple qubit species

What is claimed is: 1. A quantum computing system having a modular optical architecture, comprising: one or more first quantum networking nodes that each include: multiple memory qubits, and one or more communication qubits, the multiple memory qubits and the one or more communication qubits in each of the first quantum networking nodes comprising different isotopes of a same species; one or more second quantum networking nodes that each include: multiple memory qubits, and one or more communication qubits, the multiple memory qubits and the one or more communication qubits in each of the second quantum networking nodes comprising different species; and a photonic entangler optically coupled to each of the one or more first quantum networking nodes and each of the one or more second quantum networking nodes, the photonic entangler including one or more optical switches that are reconfigurable to provide a connection between any two quantum networking nodes from the one or more first quantum networking nodes and the one or more second quantum networking nodes. 2. The quantum computing system of claim 1 , wherein the connection between the two quantum networking nodes is a connection between any of the one or more communication qubits of one of the two quantum networking nodes and any of the one or more communication qubits of the other one of the two quantum networking nodes. 3. The quantum computing system of claim 1 , wherein the connection between the two quantum networking nodes is via one or more optical fibers. 4. The quantum computing system of claim 3 , wherein the one or more optical fibers are configured to operate at an optical communications spectrum. 5. The quantum computing system of claim 4 , wherein: the connection between the two quantum networking nodes is a connection between a first communication qubit of one of the two quantum networking nodes and a second communication qubit of the other one of the two quantum networking nodes, and the quantum computing system further comprising a wavelength converter configured to convert a spectrum of a photon emitted by the first communication qubit to the optical communications spectrum of the one or more optical fibers. 6. The quantum computing system of claim 5 , wherein the spectrum of the photon emitted by the first communication qubit is a visible spectrum and the optical communications spectrum includes wavelengths of approximately 1300-1550 nm. 7. The quantum computing system of claim 1 , wherein: the multiple memory qubits and the one or more communication qubits in each of the first quantum networking nodes are part of a lattice in an ion trap, and the one or more quantum communication qubits in each of the first quantum networking nodes are positioned at any end of the lattice, and the multiple memory qubits and the one or more communication qubits in each of the second quantum networking nodes are part of a lattice in an ion trap, and the one or more quantum communication qubits in each of the second quantum networking nodes are positioned at any end of the lattice. 8. A quantum computing system having a modular optical architecture, comprising: one or more first quantum networking nodes that each include: multiple memory qubits, and one or more communication qubits, the multiple memory qubits and the one or more communication qubits in each of the first quantum networking nodes comprise a first set of different species; one or more second quantum networking nodes that each include: multiple memory qubits, and one or more communication qubits, the multiple memory qubits and the one or more communication qubits in each of the second quantum networking nodes comprise a second set of different species that are different from the first set of different species; and a photonic entangler optically coupled to each of the one or more first quantum networking nodes and each of the one or more second quantum networking nodes, the photonic entangler including one or more optical switches that are reconfigurable to provide a connection between any two quantum networking nodes from the one or more first quantum networking nodes and the one or more second quantum networking nodes. 9. The quantum computing system of claim 8 , wherein the connection between the two quantum networking nodes is a connection between any of the one or more communication qubits of one of the two quantum networking nodes and any of the one or more communication qubits of the other one of the two quantum networking nodes. 10. The quantum computing system of claim 8 , wherein the connection between the two quantum networking nodes is via one or more optical fibers. 11. The quantum computing system of claim 10 , wherein the one or more optical fibers are configured to operate at an optical communications spectrum. 12. The quantum computing system of claim 11 , wherein: the connection between the two quantum networking nodes is a connection between a first communication qubit of one of the two quantum networking nodes and a second communication qubit of the other one of the two quantum networking nodes, and the quantum computing system further comprising a wavelength converter configured to convert a spectrum of a photon emitted by the first communication qubit to the optical communications spectrum of the one or more optical fibers. 13. The quantum computing system of claim 12 , wherein the spectrum of the photon emitted by the first communication qubit is a visible spectrum and the optical communications spectrum includes wavelengths of approximately 1300-1550 nm. 14. The quantum computing system of claim 8 , wherein: the multiple memory qubits and the one or more communication qubits in each of the first quantum networking nodes are part of a lattice in an ion trap, and the one or more quantum communication qubits in each of the first quantum networking nodes are positioned at any end of the lattice, and the multiple memory qubits and the one or more communication qubits in each of the second quantum networking nodes are part of a lattice in an ion trap, and the one or more quantum communication qubits in each of the second quantum networking nodes are positioned at any end of the lattice. 15. A quantum computing system having a modular optical architecture, comprising: one or more first quantum networking nodes that each include: multiple memory qubits, and one or more communication qubits, the multiple memory qubits and the one or more communication qubits in each of the first quantum networking nodes comprising different isotopes of a same first species; one or more second quantum networking nodes that each include: multiple memory qubits, and one or more communication qubits, the multiple memory qubits and the one or more communication qubits in each of the second quantum networking nodes comprising different isotopes of a same second species; and a photonic entangler optically coupled to each of the one or more first quantum networking nodes and each of the one or more second quantum networking nodes, the photonic entangler includes one or more optical switches that are reconfigurable to provide a connection between any two quantum networking nodes from the one or more first quantum networking nodes and the one or more second quantum networking nodes. 16. The quantum computing system of claim 15 , wherein the connection between the two quantum networking nodes is a connection between any of the one or more communication qubits of one of the two quantum networking nodes and any of the one or more communication qu