Substrate processing apparatus and method of manufacturing semiconductor device

What is claimed is: 1. A substrate processing apparatus comprising: a substrate holder configured to hold plurality of substrates in array at respective positions with predetermined intervals and used to hold a plurality of product substrates at all the positions where the substrates are allocable; a tubular reactor including an opening through which the substrate holder can be carried in and out at a lower side and a ceiling with a flat inner surface and houses the substrate holder; a furnace body surrounding an upper side and a lateral side of the tubular reactor; a main heater provided in the furnace body and configured to heat the side portion of the tubular reactor; a ceiling heater provided in the furnace body and configured to heat the ceiling; a lid that closes the opening; a cap heater arranged inside the tubular reactor and also located below the substrate holder and configured to perform heating; and a gas supply mechanism configured to individually supply a gas to a top side of each of the plurality of product substrates held by the substrate holder inside the tubular reactor, wherein when a source gas decomposable in a gas phase is supplied from the gas supply mechanism in a state where the product substrates are held at all of the positions in the substrate holder, a partial pressure of a species of a product gas generated by the decomposition becomes uniform at all of the positions; wherein the substrate holder includes a plurality of upstanding support columns and a disk-shaped top plate that fixes upper ends of the plurality of support columns; wherein a diameter of the top plate is set to 90% or more and 98% or less of an inner diameter of the tubular reactor substrate; and wherein volume of an upper end space partitioned from others by the top plate and interposed between the ceiling and the top plate is set to 1 time or more and 3 times or less volume of a space interposed between the product substrates adjacent to each other and held by the substrate holder. 2. The substrate processing apparatus according to claim 1 , wherein the substrate holder includes a plurality of upstanding support columns and a disk-shaped top plate that fixes upper ends of the plurality of support columns; wherein a diameter of the top plate is set to 90% or more and 98% or less of an inner diameter of the tubular reactor and a pitch between the adjacent product substrates held by the substrate holder is set to 6 mm or more and 16 mm or less; and wherein volume of an upper end space partitioned from others by the top plate and interposed between the ceiling and the top plate is set to 1 time or more and 3 times or less volume of a space interposed between the product substrates adjacent to each other and held by the substrate holder. 3. The substrate processing apparatus according to claim 2 , wherein: the substrate holder further includes a disk-shaped or annular bottom plate that fixes lower ends of the plurality of support columns to each other and is fitted to an upper surface of the insulation structure; volume of a lower end space interposed between the bottom plate or the upper surface of the heat insulation structure and the product substrate held at a lowermost position in the substrate holder where the substrate can be held is set to 0.5 times or more and 1.5 times or less volume of a space interposed between the product substrates adjacent to each other and held by the substrate holder; and the gas supply mechanism individually supplies the source gas to the lower end space. 4. The substrate processing apparatus according to claim 1 , wherein the gas supply mechanism comprises a nozzle that is located beside the array of the plurality of substrates, fed the gas flow-controlled from a single pipe, distributes the gas into nozzle holes and discharges the gas through the nozzle holes toward spaces above or edges of all the plurality of product substrates held by the substrate holder inside the tubular reactor. 5. A method of manufacturing a semiconductor device, using the substrate processing apparatus according to claim 1 , the method sequentially repeating: a first process in which a gas supply mechanism supplies a first source gas to a plurality of product substrates; a second process in which the gas supply mechanism supplies a purge gas to the plurality of product substrates; a third process in which the gas supply mechanism supplies a second source gas to the plurality of product substrates; and a fourth process in which the gas supply mechanism supplies a purge gas to the plurality of product substrates. 6. A substrate processing apparatus comprising: a substrate holder configured to hold plurality of substrates in array at respective positions with predetermined intervals and used to hold a plurality of product substrates at all the positions where the substrates are allocable; a tubular reactor including an opening through which the substrate holder can be carried in and out at a lower side and a ceiling with a flat inner surface and houses the substrate holder; a furnace body surrounding an upper side and a lateral side of the tubular reactor; a main heater provided in the furnace body and configured to heat the side portion of the tubular reactor; a ceiling heater provided in the furnace body and configured to heat the ceiling; a lid that closes the opening; a cap heater arranged inside the tubular reactor and also located below the substrate holder and configured to perform heating; and a gas supply mechanism configured to individually supply a gas to a top side of each of the plurality of product substrates held by the substrate holder inside the tubular reactor, wherein when a source gas decomposable in a gas phase is supplied from the gas supply mechanism in a state where the product substrates are held at all of the positions in the substrate holder, a partial pressure of a species of a product gas generated by the decomposition becomes uniform at all of the positions; wherein the substrate holder further includes a disk-shaped or annular bottom plate that fixes lower ends of the plurality of support columns to each other and is fitted to an upper surface of the insulation structure; volume of a lower end space interposed between the bottom plate or the upper surface of the heat insulation structure and the product substrate held at a lowermost position in the substrate holder where the substrate can be held is set to 0.5 times or more and 1.5 times or less volume of a space interposed between the product substrates adjacent to each other and held by the substrate holder; and the gas supply mechanism individually supplies the source gas to the lower end space. 7. The substrate processing apparatus according to claim 6 , wherein the opening of the main exhaust vent further faces the lower end space.