This application is based upon and claims the benefit of priority from Japanese Patent Application No. 2013-024831, filed Feb. 12, 2013, the entire contents of which are incorporated herein by reference.
Embodiments described herein relate generally to a substrate treatment apparatus.
A substrate treatment apparatus with a wafer-by-wafer wafer system has been used in some cases when a substrate is processed with a treatment liquid supplied to the surface of a semiconductor wafer that is a substrate to be treated in a manufacturing process of a semiconductor device. Whether or not the target substrate put on the substrate treatment apparatus is normally held, is determined according to various methods.
In the substrate treatment apparatus, there may occur such an error that the target substrate is not properly held by the holding unit of the substrate holding unit but held in an inclined state, and that the substrate falls down on the bottom surface of the holding unit. This failure (error) in holding a substrate may be detected through measuring by an optical sensor whether or not a light illuminating the substrate holding unit in a substantially horizontal direction is transmitted without being disturbed by the target substrate.
In processing the back surface of the target substrate, in other words, a surface opposite to the surface (front surface) where a circuit is formed, using a treatment liquid, the front surface of the target substrate has to be held with no contact. As a non-contact substrate holding method, Bernoulli chuck of holding the target substrate by Bernoulli Effect may be used after injecting a gas toward the surface opposite to the surface to be processed of the target substrate. In a substrate processor of holding a substrate by Bernoulli chuck, for example, when a target substrate is carried from a carrying device to the substrate processor, even when the target substrate is not normally held because of the abnormal transfer operation, the conventional optical sensor cannot detect an error of holding the substrate because the target substrate is kept floating, namely, it does not incline nor fall down to the holding unit.
In general, according to one embodiment, there is provided a substrate treatment apparatus includes a substrate holding unit including a holding unit configured to hold a target substrate, a base unit which has the holding unit on a peripheral portion thereof, and a hollow rotation shaft, which contains a gas supply channel, configured to rotate together with the holding unit and the base unit, the substrate holding unit configured to hold the target substrate by supplying to the target substrate gas supplied from the gas supply channel, a substrate rotating unit, which is connected to the rotation shaft through a belt, configured to rotate the substrate holding unit, and a first substrate holding detecting unit, which is connected to the substrate rotating unit, configured to detect whether or not the target substrate is held by the substrate holding unit, by measuring a rotational frequency or a roll acceleration of the rotating substrate holding unit.
An embodiment will be described below in detail with reference to the attached drawings mentioned above.
A substrate treatment apparatus 1 is provided with a substrate holding unit 2 including a holding unit 21, a base unit 22, and a rotation shaft 23, a belt 31 which connects the rotation shaft 23 and a motor 4 (rotating unit), and a pulley 32 and a pulley 33 for connecting the belt 31. Further, the substrate treatment apparatus 1 is provided with a substrate holding detecting unit 5 which is adjacent to the motor 4 and a control unit 6 for controlling the substrate holding detecting unit 5.
The substrate holding unit 2 is provided with the holding unit 21 which guides and holds the target substrate W. Further, the substrate holding unit 2 is provided with the base unit 22 connected to the lower end of the holding unit 21. The holding unit 21 is provided on the peripheral portion of the base unit 22. The holding unit 21 and the base unit 22 do not have to be formed separately but may be formed integrally.
As described later, a gas supply channel 22a capable of supplying a gas flow is provided inside the base unit 22 so that the target substrate W can be held by the substrate holding unit 2 on a basis of to Bernoulli effect. As illustrated in
The rotation shaft 23 is provided in the substrate holding unit 2 at the lower end of the base unit 22 in its substantial central portion. The rotation shaft 23 rotates due to the transmission of the power of the motor 4, hence to rotate the substrate holding unit 2 on the whole. Inside the rotation shaft 23, a gas supply channel 23a is provided in the extending direction of the rotation shaft 23, in order to supply gas to the gas supply channel 22a of the base unit 22.
The pulley 32 is provided on the lower end of the rotation shaft 23. The pulley 32 is connected to the pulley 33 connected to the motor 4, through the belt 31, to transmit the power caused by the rotation of the motor 4 to the rotation shaft 23. The belt 31 is provided to circle around the pulley 32 and the pulley 33.
Further, the substrate holding detecting unit 5 is provided to measure a rotational frequency or a roll acceleration of the motor 4. The substrate holding detecting unit 5 is, for example, an accelerometer which measures the acceleration of the motor 4, or a frequency sensor which measures the rotational frequency of the motor 4.
The substrate holding detecting unit 5 according to the embodiment is to detect a change of the value in the roll acceleration or the rotational frequency of the motor 4 varying according to whether or not the substrate holding unit 2 is holding the target substrate W. Concretely, the roll acceleration or the rotational frequency is previously measured in the case of holding the target substrate W by the substrate holding unit 2 and in the case of not holding the above, and the result is stored in a library (not shown). Then, the control unit 6 associates the value actually measured in the semiconductor manufacturing process with the value stored in the library, to determine whether or not the target substrate W is held by the substrate holding unit 2. The roll acceleration is measured, for example, by measuring a change in the speed for a predetermined time from starting the rotation of the motor 4. Concretely, when the rotational frequency or the roll acceleration measured by the substrate holding detecting unit 5 is larger than a predetermined value as compared with the value in a state of the target substrate W being held by the substrate holding unit 2, the control unit 6 stops the rotation of the motor 4.
Whether or not the target substrate W is held may be determined through the above measurement by providing the substrate holding detecting unit 5 on the rotation shaft 23. However, the roll acceleration or the rotational frequency of the rotation shaft 23 fluctuates larger caused by the weight of the base unit 22 and the target substrate W; therefore, it is difficult to determine a difference of fine value indicating whether or not the target substrate W is held by the substrate holding unit 2 by measuring the roll acceleration or the rotational frequency of the rotation shaft 23 by the substrate holding detecting unit 5.
According to the substrate treatment apparatus 1 of the embodiment, the substrate holding detecting unit 5 is connected to the motor 4 connected to the rotation shaft 23 through the belt 31, to measure the rotational frequency or the roll acceleration. Since the substrate holding unit 2 is connected to the motor 4 through the belt 31, the rotational frequency and the acceleration rarely fluctuate. Therefore, in a case that a substrate holding detecting unit 5 having a high resolution is used, the roll acceleration or the rotational frequency of the motor 4 is measured by the substrate holding detecting unit 5 connected to the motor 4, which can normally determine whether or not the target substrate W is held by the substrate holding unit 2.
Separately from the substrate holding detecting unit 5 connected to the motor 4, an optical sensor 7 may be provided in the substrate treatment apparatus 1. Holding of a substrate is detected by the optical sensor 7; whether or not a light illuminating the substrate holding unit 2 from a light illuminating unit 8 in a substantially horizontal direction is transmitted without being disturbed by the target substrate W is measured by the optical sensor 7. In such a manner, a more accurate substrate holding detection is enabled in combination with the above substrate holding detecting unit 5.
After determining that the target substrate W is held by the substrate holding unit 2, according to the above mentioned substrate treatment apparatus 1, a treatment liquid is supplied to the target substrate W from a treatment liquid supply nozzle (not illustrated), thereby processing the target substrate W.
As mentioned above, according to the substrate treatment apparatus of the embodiment, the substrate holding detecting unit is provided adjacent to the motor connected to the rotation shaft through the belt. In such a manner, since the substrate holding unit is connected to the motor through the belt, the rotational frequency and the acceleration hardly fluctuate, so that whether or not the target substrate W is held by the substrate holding unit can be normally determined.
While certain embodiments have been described, these embodiments have been presented by way of example only, and are not intended to limit the scope of the inventions. Indeed, the novel embodiments described herein may be embodied in a variety of other forms; furthermore, various omissions, substitutions and changes in the form of the embodiments described herein may be made without departing from the spirit of the inventions. The accompanying claims and their equivalents are intended to cover such forms or modifications as would fall within the scope and spirit of the inventions.
Number | Date | Country | Kind |
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2013-024831 | Feb 2013 | JP | national |