Horizontally fired burner with a perforated flame holder

What is claimed is: 1. A horizontally-fired burner comprising: a horizontally-fired fuel nozzle configured to output, in a horizontal direction, a pure fuel jet selected to entrain oxidant; a flame holder positioned laterally from the horizontally-fired fuel nozzle, the flame holder including: an input surface facing the horizontally-fired fuel nozzle; an output surface opposite the flame holder; and a plurality of perforations extending from the input surface to the output surface and collectively configured to promote a combustion reaction of the fuel within the perforations; and a preheating mechanism configured to heat the flame holder prior to starting the combustion reaction; wherein the horizontally-fired fuel nozzle comprises an adjustable fuel nozzle; and wherein the preheating mechanism is configured to move the adjustable fuel nozzle closer to the flame holder during a preheating period and to retract the adjustable fuel nozzle away from the flame holder after the preheating period. 2. The horizontally-fired burner of claim 1 , wherein the flame holder is configured to contain a majority of the combustion reaction within the perforations. 3. The horizontally-fired burner of claim 1 , wherein the flame holder is configured to contain 80% or more of the combustion reaction within the perforations. 4. The horizontally-fired burner of claim 1 , wherein the flame holder is a refractory material. 5. The horizontally-fired burner of claim 1 , wherein the flame holder is an integral structure. 6. The horizontally-fired burner of claim 1 , wherein the flame holder is configured to initiate the combustion reaction. 7. The horizontally-fired burner of claim 1 , wherein the preheating mechanism comprises a second fuel nozzle configured to generate a flame adjacent the flame holder. 8. The horizontally-fired burner of claim 1 , wherein the preheating mechanism comprises a laser configured to irradiate the flame holder. 9. The horizontally-fired burner of claim 1 , comprising: a temperature sensor configured to measure a temperature of the flame holder; and a control circuit coupled to the temperature sensor, the fuel nozzle, and the preheating mechanism and configured to cause the fuel nozzle to output the fuel when the temperature of the flame holder is above a threshold temperature. 10. The horizontally-fired burner of claim 9 , wherein the threshold temperature corresponds to a combustion temperature at which the flame holder can initiate combustion of the fuel. 11. The horizontally-fired burner of claim 1 , comprising a control circuit coupled to the preheating mechanism and the fuel nozzle and configured to initiate the fuel nozzle after the preheating mechanism has operated for longer than a threshold time. 12. The horizontally-fired burner of claim 1 , wherein the perforations are isolated from each other by a body of the flame holder. 13. The horizontally-fired burner of claim 1 , wherein the input and output surfaces of the flame holder are substantially rectangular. 14. The horizontally-fired burner of claim 1 , wherein the input and output surfaces of the flame holder are circular, elliptical, or ovular. 15. The horizontally-fired burner of claim 1 , wherein a width of the flame holder in a vertical direction is more than twice as large as thickness of the flame holder in a horizontal direction. 16. A method comprising: using a preheating mechanism configured for heating a flame holder having a plurality of perforations each extending from an input surface of the flame holder to an output surface of the flame holder to heat the flame holder prior to starting a combustion reaction; outputting pure fuel from a first nozzle in a horizontal direction, in a fuel jet selected to entrain oxidant, onto the input surface of the flame holder from an adjustable fuel nozzle; igniting the combustion reaction of the fuel in the plurality of perforations; containing the combustion reaction of the fuel substantially in the perforations in the flame holder; and moving the adjustable fuel nozzle closer to the flame holder during a preheating period and retracting the adjustable fuel nozzle away from the flame holder after the preheating period. 17. The method of claim 16 , comprising: measuring a temperature of the flame holder; and outputting the fuel onto the flame holder after the temperature of the flame holder has reached a threshold temperature. 18. The method of claim 17 , wherein the threshold temperature is a temperature at which the combustion reaction will ignite in the flame holder. 19. The method of claim 16 , wherein heating the flame holder comprises applying heat to the flame holder by flail the preheating mechanism being positioned adjacent the flame holder. 20. The method of claim 16 , comprising heating the flame holder by irradiating the flame holder with a laser. 21. The method of claim 16 , comprising heating the flame holder with a second fuel nozzle positioned adjacent the flame holder. 22. The method of claim 16 , comprising heating the flame holder by passing a current through an electrical resistor coupled to the flame holder. 23. The method of claim 16 , comprising outputting oxygen in a horizontal direction from a second nozzle onto the first surface of the flame holder. 24. The method of claim 16 , comprising outputting the oxygen in an airstream. 25. The method of claim 16 , wherein the combustion reaction is a reaction of the fuel with the oxygen. 26. The method of claim 16 , wherein the flame holder is of a refractory material. 27. The method of claim 16 , wherein the perforations are isolated from each other by a body of the flame holder. 28. A system comprising: a horizontally facing fuel nozzle configured to output pure fuel in a horizontal direction, in a jet selected to entrain oxidant; a flame holder positioned laterally from the horizontally facing fuel nozzle, the flame holder including: an input surface; an output surface; and a plurality of perforations between the input and output surfaces, the flame holder being configured to confine a majority of a combustion reaction of the fuel within the perforations; and a preheating mechanism configured to heat the flame holder prior to starting the combustion reaction; wherein the horizontally-facing fuel nozzle comprises an adjustable fuel nozzle; and wherein the preheating mechanism is configured to move the adjustable fuel nozzle closer to the flame holder during a preheating period and to retract the adjustable fuel nozzle away from the flame holder after the preheating period. 29. The system of claim 28 , wherein the perforations of the flame holder are isolated from each other. 30. The system of claim 29 , wherein the flame holder is configured to convey heat between the plurality of perforations. 31. The system of claim 28 , comprising a wherein the preheating mechanism is positioned adjacent to the flame holder and is configured to preheat the flame holder to a threshold temperature prior to outputting the fuel from the fuel nozzle. 32. The system of claim 31 , wherein the threshold temperature is a temperature at which the flame holder can ignite the combustion reaction of the fuel.