A development processing apparatus includes: a substrate holder that holds a substrate horizontally wherein the substrate includes a resist film; a rotator that rotates the substrate holder; first and second developer supplies that supply a developer to the substrate; and a liquid receiver that receives the developer from the substrate. The first developer supply is formed to have a length smaller than a diameter of the substrate. The second developer supply is formed to have a length equal to or larger than the diameter of the substrate. The liquid receiver includes first and second annular walls that are formed in an annular shape having a circular opening having a diameter larger than the diameter of the substrate. The first and second annular walls are movable up and down independently of each other, and a vertical distance between the first annular wall and the second annular wall is variable.

Substrates can be suppressed from being separated from supporting grooves. A substrate processing apparatus includes a substrate holding unit and a processing tub. The substrate holding unit is configured to hold multiple substrates. The processing tub is configured to store a processing liquid therein. The substrate holding unit comprises a supporting body, an elevating device and a restriction unit. The supporting body has multiple supporting grooves and is configured to support the multiple substrates with a vertically standing posture from below in the multiple supporting grooves, respectively. The elevating device is configured to move the supporting body between a standby position above the processing tub and a processing position within the processing tub. The restriction unit is configured to be moved up and down along with the supporting body by the elevating device and configured to restrict an upward movement of the substrates with respect to the supporting body.

A module tray for a semiconductor device includes a case and an insert block. The case includes a base plate, first and second sidewalls extending from opposite sides of the base plate in a vertical direction to define an accommodation space, and first and second fastening grooves respectively formed in inner surfaces of the first and second sidewalls. The first and second fastening grooves have upper ends opened to upper surfaces of the first and second sidewalls, respectively. The insert block has a substrate accommodating space for accommodating a semiconductor substrate. The insert block is detachably inserted into the first and second fastening grooves of the case. The insert block has first and second fastening joints extending in the vertical direction such that the first and second fastening joint are respectively inserted through the upper ends of the first and second fastening grooves.

Described herein is a technique capable of processing a substrate uniformly using microwaves. According to one aspect of the technique of the present disclosure, there is provided a heating element used in a substrate processing apparatus configured to heat a substrate supported by a substrate retainer by microwaves and process the substrate, the heating element including a dielectric material of an annular shape capable of generating heat by the microwaves. An inner circumferential portion of the heating element is located outer than an outer circumferential portion of the substrate, and the heating element is supported by the substrate retainer without contacting the substrate.

The substrate liquid processing apparatus includes a processing bath that accommodates substrates, and a plurality of gas supply pipes provided in a processing bath. Ejection holes of one gas supply pipe and ejection holes of another adjacent gas supply pipe do not overlap each other in a direction parallel to the circuit-formed surfaces of the substrates.

In one embodiment, a semiconductor manufacturing apparatus includes a container to contain wafers, and supporting tables provided in the container so as to be stacked on one another, and each including a supporting face that comes into contact with a wafer to support the wafer. The apparatus further includes supporting columns to join the supporting tables together and provided at positions where the supporting columns are contained inside outer circumferences of the supporting tables. The apparatus further includes a gas feeder to feed a gas to the wafers on the supporting tables, and a gas discharger to discharge the gas fed to the wafers on the supporting tables. Each of the supporting tables includes a first upper face as the supporting face, and a second upper face provided so as to surround the first upper face at a level higher than a level of the first upper face.

Presented herein is a device processing boat comprising a base and at least one unit retainer disposed in the base. The device further comprises a cover having at least one recess configured to accept and retain at least one unit. The at least one recess is aligned over, and configured to hold the at least one unit over, at least a portion of the at least one unit retainer. The cover is retained to the device processing boat by the at least one unit retainer. At least one pressure sensor having at least one sensel is disposed in the base. The sensel is configured to sense a clamping force applied by the cover to the at least one unit.

Semiconductor substrate adaptor configured to adapt a substrate of a first dimension to a second dimension, such that the substrate can be properly supported by a supporting mechanism (e.g., a wafer cassette) customized for substrates of the second dimension. The substrate adaptor may be made of quartz. The combination of the substrate adaptor and a substrate fitting therein causes no perturbation in various aspects of a semiconductor process. Therefore, the substrate adaptor conveniently enables a substrate of the first dimension to be processed in the same processing equipment and conditions as a substrate of the second dimension. A vertical substrate adaptor may have a semicircular body with a semicircular cutout for accommodating a wafer and can support a wafer vertically. A horizontal substrate adaptor may have a circular body with a circular cutout for accommodating an entire wafer and supporting the wafer horizontally.

A substrate heating apparatus includes: a substrate support configured to substantially horizontally support a substrate; a heater provided below the substrate support substantially parallel to the substrate, and having a predetermined planar shape; and a side portion extending downward from an outer peripheral portion of the heater.

Semiconductor substrate adaptor configured to adapt a substrate of a first dimension to a second dimension, such that the substrate can be properly supported by a supporting mechanism (e.g., a wafer cassette) customized for substrates of the second dimension. The substrate adaptor may be made of quartz. The combination of the substrate adaptor and a substrate fitting therein causes no perturbation in various aspects of a semiconductor process. Therefore, the substrate adaptor conveniently enables a substrate of the first dimension to be processed in the same processing equipment and conditions as a substrate of the second dimension. A vertical substrate adaptor may have a semicircular body with a semicircular cutout for accommodating a wafer and can support a wafer vertically. A horizontal substrate adaptor may have a circular body with a circular cutout for accommodating an entire wafer and supporting the wafer horizontally.