Root pass welding solution

The invention claimed is: 1. A tubular welding wire comprising: a core and a sheath disposed around the core, wherein the core of the tubular welding wire comprises: a first agglomerate comprising lithium oxide, lithium fluoride, iron oxides, sodium oxide, and silicon dioxide; and a second agglomerate comprising lithium oxide, iron oxides, sodium oxide, silicon dioxide, and manganous oxide; wherein the tubular welding wire comprises greater than approximately 2.4% glassy slag promoter by weight. 2. The tubular welding wire of claim 1 , wherein the tubular welding wire comprises between approximately 2.5% and approximately 3.3% glassy slag promoter by weight. 3. The tubular welding wire of claim 1 , wherein the tubular welding wire comprises between approximately 2.9% and approximately 3.2% glassy slag promoter by weight. 4. The tubular welding wire of claim 1 , wherein the glassy slag promoter comprises one or more of silicon dioxide, titanium dioxide, a borate, or sodium oxide. 5. The tubular welding wire of claim 1 , wherein the glassy slag promoter is silicon dioxide. 6. The tubular welding wire of claim 1 , wherein the glassy slag promoter is selected from the group consisting of: titanium dioxide, a borate, and sodium oxide. 7. The tubular welding wire of claim 1 , wherein the tubular welding wire comprises between approximately 2.6% and approximately 3.7% aluminum powder by weight. 8. The tubular welding wire of claim 1 , wherein the tubular welding wire comprises between approximately 3.2% and approximately 3.6% aluminum powder by weight. 9. The tubular welding wire of claim 1 , wherein the tubular welding wire comprises between approximately 0.8% and approximately 1.3% lithium compounds by weight. 10. The tubular welding wire of claim 1 , wherein the tubular welding wire comprises between approximately 1% and approximately 1.25% lithium compounds by weight. 11. The tubular welding wire of claim 1 , wherein the tubular welding wire comprises one or more shielding gas agents configured to decompose to provide a shielding gas near a welding arc. 12. A method of manufacturing a welding electrode, comprising: forming a first agglomerate by sintering a mixture comprising sodium silicate, iron oxide, and lithium carbonate to form an intermediate agglomerate, and then sintering a mixture comprising the intermediate agglomerate, lithium fluoride, and sodium silicate to form the first agglomerate, wherein the first agglomerate comprises lithium oxide, lithium fluoride, iron oxides, sodium oxide, silicon dioxide, and manganous oxide; providing a granular core, wherein providing the granular core comprises mixing the first agglomerate with a glassy slag promoter; and disposing the granular core within a metallic sheath to form the welding electrode, wherein the welding electrode comprises greater than approximately 2.4% glassy slag promoter by weight. 13. The method of claim 12 , wherein the welding electrode comprises between approximately 2.6% and approximately 3.7% aluminum by weight and between approximately 0.8% and approximately 1.3% lithium compounds by weight. 14. The method of claim 12 , comprising forming a second agglomerate by sintering a mixture comprising iron oxides, sodium silicate, silica, and lithium carbonate. 15. The method of claim 14 , wherein providing the granular core comprises mixing the second agglomerate with the first agglomerate and the glassy slag promoter, wherein the second agglomerate comprises lithium oxide, iron oxides, sodium oxide and silicon dioxide. 16. The tubular welding wire of claim 1 , wherein the at least one agglomerate further comprises lithium fluoride and manganous oxide. 17. A method of manufacturing a welding electrode, comprising: sintering a mixture comprising iron oxides, sodium silicate, silica, and lithium carbonate to form a first agglomerate, wherein the first agglomerate comprises lithium oxide, iron oxides, sodium oxide and silicon dioxide; providing a granular core, wherein providing the granular core comprises mixing the first agglomerate with a glassy slag promoter; and disposing the granular core within a metallic sheath to form the welding electrode, wherein the welding electrode comprises greater than approximately 2.4% glassy slag promoter by weight. 18. The method of claim 17 , comprising forming a second agglomerate by sintering a mixture comprising sodium silicate, iron oxide, and lithium carbonate to form an intermediate agglomerate, and then sintering a mixture comprising the intermediate agglomerate, lithium fluoride, and sodium silicate to form the second agglomerate. 19. The method of claim 18 , wherein providing the granular core comprises mixing the second agglomerate with the first agglomerate and the glassy slag promoter, wherein the second agglomerate comprises lithium oxide, lithium fluoride, iron oxides, sodium oxide, silicon dioxide, and manganous oxide.