There is provided technique including: forming film on substrate by performing cycle, predetermined number of times, including non-simultaneously performing: (a) supplying precursor gas and inert gas to the substrate; and (b) supplying reaction gas to the substrate, wherein in (a), at least one selected from the group of the precursor gas and the inert gas stored in first tank is supplied to the substrate, and at least one selected from the group of the precursor gas and the inert gas stored in second tank is supplied to the substrate, and concentration of the precursor gas in the first tank while at least one selected from the group of the precursor gas and the inert gas is stored in the first tank differs from that in the second tank while at least one selected from the group of the precursor gas and the inert gas is stored in the second tank.

According to one aspect of the technique, there is provided a method of manufacturing a semiconductor device, including checking a leak from a process furnace before a substrate is processed. The checking includes: (a) measuring, by a partial pressure sensor provided at an exhaust pipe, an oxygen partial pressure value of a residual oxygen after the process furnace is vacuum-exhausted; (b) comparing the oxygen partial pressure value measured by the partial pressure sensor with a threshold value; and (c) when the oxygen partial pressure value is higher than the threshold value in (b), performing at least one among: purging the process furnace and evacuating the process furnace.

A carrier spacer includes an annular main body, a first tapered part formed on an inner peripheral part of a front surface of the main body, a second tapered part formed on the inner peripheral part of a reverse surface of the main body, a flat surface formed on the outer peripheral side of the first tapered part on the front surface of the main body and holding the reverse surface of the outer peripheral part of a semiconductor wafer, a peripheral edge part formed on the outer peripheral side of the flat surface of the main body and provided with a step having a height position higher than a height position of the flat surface, an arcuate cutout part formed from the peripheral edge part to the flat surface of the main body, and a pair of handles protruding from the peripheral edge part toward the outer peripheral side.

A vertical batch furnace assembly for processing wafers comprising a cassette handling space, a wafer handling space, and an internal wall separating the cassette handling space and the wafer handling space. The cassette handling space is provided with a cassette storage configured to store a plurality of wafer cassettes provided with a plurality of wafers. The cassette handling space is also provided with a cassette handler configured to transfer wafer cassettes between the cassette storage and a wafer transfer position. The wafer handling space is provided with a wafer handler configured to transfer wafers between a wafer cassette in the wafer transfer position and a wafer boat in a wafer boat transfer position. The internal wall is provided with a wafer transfer opening adjacent the wafer transfer position for a wafer cassette from or to which wafers are to be transferred. The cassette storage comprises two cassette storage carousels.

A vertical batch furnace assembly for processing wafers comprising a cassette handling space, a wafer handling space, and a first wall separating the cassette handling space from the wafer handling space. The wall having a wafer transfer opening. The wafer transfer opening is associated with a cassette carrousel comprising a carrousel stage having a plurality of cassette support surfaces each configured for supporting a wafer cassette. The carrousel stage is rotatable by an actuator around a substantially vertical axis to transfer each cassette support surface to a wafer transfer position in front of the wafer transfer opening and to at least one cassette load/retrieve position, wherein the vertical batch furnace assembly is configured to load or retrieve a wafer cassette on or from a cassette support surface of the carrousel stage which is in the at least one load/retrieve position.

A technique for connecting a nozzle to a reaction tube while preventing the nozzle from collapsing includes a substrate processing apparatus including: a gas introduction structure comprising a non-metallic material penetrating a side wall of a process vessel and integrated with the side wall as a single structure, wherein a front end thereof protrudes into the process vessel; a nozzle made of a non-metallic material and including: a first straight portion inserted into the gas introduction structure and fluidically communicating with the gas introduction structure; and a second straight portion fluidically communicating with the first straight portion and extending along an inner wall of the process vessel; and a fixing block provided at an inner side of the process vessel and above the gas introduction structure, wherein the fixing block has a groove where the nozzle can be moved in a radial direction of the process vessel.

The application relates to the technical field of semiconductor manufacturing, and in particular relates to a front opening unified pod, a wafer transfer system and a wafer transfer method. The front opening unified pod includes a body, a wafer scanning device and a cover. The body is provided with an opening communicating with an interior of the body. The wafer scanning device includes a first wafer scanning device, is arranged on an inner wall of the body, and is configured to scan a storage condition of wafers in the body. The cover is fastened at the opening. The wafer scanning device is arranged on the inner wall of the body of the front opening unified pod, and the wafer scanning device scans and confirms the storage condition of the wafers in the front opening unified pod in real time.

The present application discloses a diffusion furnace, including: a furnace tube structure including a furnace tube body and a furnace bottom, a bottom of the furnace tube body being connected to the furnace bottom to form a reaction chamber; and a carrying structure including a pedestal and a plurality of cassettes disposed on the pedestal, the pedestal being disposed on the furnace bottom. By disposing the plurality of the cassettes, a height of the furnace tube body can be decreased and a width of the furnace tube body can be increased, thus enlarging a space of equipment repair and maintenance, which is favorable for the repair and maintenance of the equipment.

A substrate processing apparatus includes: a first boat configured to hold substrates in a shelf shape; a second boat provided coaxially with the first boat and configured to hold substrates in a shelf shape; and a drive configured to rotate the first boat and the second boat in a synchronized manner and configured to raise and lower the second boat relative to the first boat.

There is provided a technique capable of capable of preventing a substrate from being metal-contaminated by a component constituting a furnace opening. According to one aspect thereof, there is provided a furnace opening structure including: an upper inlet structure connected to a first protrusion provided at a lower portion of a reaction tube via a first seal, and configured to support the reaction tube; a lower inlet structure connected to the upper inlet structure via a second seal; and a fixing structure connected to the upper inlet structure and configured to fix the first protrusion, wherein the upper inlet structure is provided below an exhaust pipe provided at the lower portion of the reaction tube, and wherein the first protrusion is configured to be capable of being cooled by circulating a cooling medium through flow paths provided inside the upper inlet structure and the fixing structure, respectively.