Quantum-Grade Nanodiamonds and Related Methods

1 . A method of forming quantum-grade nanodiamonds (Q-NDs), the method comprising: providing a plasma volume in a reaction chamber of a plasma reactor; providing molecular seeds in the plasma volume; providing a carbon precursor and hydrogen in the plasma volume to grow diamond around each of the molecular seeds in the plasma volume to provide nanodiamonds (NDs); passing ones of the nanodiamonds out of the plasma volume based on the respective ones of the nanodiamonds reaching a size greater than a threshold size; and collecting the respective ones of the nanodiamonds reaching the size greater than the threshold size. 2 . The method according to claim 1 , wherein providing the molecular seeds comprises providing the molecular seeds in a vapor state in a flow of a carrier gas, wherein the flow of the carrier gas is provided through the plasma volume. 3 . The method according to claim 1 , wherein the molecular seeds comprise diamondoid seeds. 4 . The method according to claim 3 , wherein each of the diamondoid seeds comprise a diamondoid derivative seed include a non-carbon dopant atom having an atomic weight greater than 2. 5 . The method according to claim 4 , wherein each of the diamondoid derivative seeds includes the non-carbon dopant atom substituted for a carbon atom in the structure of the diamondoid seed. 6 . The method according to claim 5 , wherein the diamondoid derivative seeds comprise azaadamantane (C 9 H 15 N) seeds. 7 . The method according to claim 4 , wherein each of the diamondoid derivative seeds includes the non-carbon dopant atom added to the carbon atoms in the structure of the diamondoid derivative seed. 8 . The method according to claim 7 , wherein the diamondoid derivative seeds comprise aminoadamantane (C 10 H 17 N) seeds. 9 . The method according to claim 1 , wherein the threshold size is defined as a nanodiamond diameter greater than 5 nm. 10 . The method according to claim 1 further comprising: providing a dopant precursor for a dopant element in the plasma volume, wherein the dopant element is included in the diamond grown around each of the molecular seeds. 11 . The method according to claim 1 further comprising: after passing the respective ones of the nanodiamonds reaching the size greater than the threshold size out of the plasma volume, forming a non-diamond nanoshell on the respective ones of the nanodiamonds having the size greater than the threshold size to provide nanoshell-coated nanodiamonds. 12 . The method according to claim 11 , wherein the non-diamond nanoshell comprises at least one of an n- or p-type semiconductor nanoshell, oxide nanoshell, a nitride nanoshell, a fluoride nanoshell, and/or a metal nanoshell. 13 . A quantum-grade nanodiamond (Q-ND) comprising: a nanodiamond having only a single impurity defect therein. 14 . The Q-ND according to claim 13 , wherein the single impurity defect is a dopant atom of nitrogen. 15 . The Q-ND according to claim 14 , wherein the single impurity defect is a single NV or NV − center. 16 . The Q-ND according to claim 13 further comprising: a non-diamond nanoshell on the nanodiamond. 17 . The Q-ND according to claim 16 , wherein the nanoshell comprises an n-type or p-type semiconductor nanoshell. 18 . The Q-ND according to claim 17 , wherein the n-type or p-type semiconductor nanoshell comprises a metal oxide nanoshell. 19 . The Q-ND according to claim 13 , wherein the nanodiamond has a diameter of at least 5 nm. 20 . A quantum-grade nanodiamond (Q-ND) comprising: a nanodiamond; and a non-diamond nanoshell on the nanodiamond. 21 . The Q-ND according to claim 20 , wherein the wherein the non-diamond nanoshell comprises an n- or p-type semiconductor nanoshell. 22 . The Q-ND according to claim 21 , wherein the n- or p-type semiconductor nanoshell comprises a semiconductor metal oxide nanoshell.