DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0034] Embodiments of the invention will be described hereinbelow.

[0035] First Embodiment

[0036] FIG. 1 is a diagram showing a cleaning flow of the embodiment.

[0037] FIG. 2 is a conceptual diagram of a cleaning apparatus. The cleaning apparatus has a motor (not shown) for rotating a semiconductor wafer 1. The apparatus has a wafer surface-side discharge nozzle 2 for discharging N₂, dry air, or pure water toward the surface of semiconductor wafer 1, thereby protecting the surface of semiconductor wafer 1, and a wafer back-side discharge nozzle 3 for discharging a chemical or pure water toward the back of semiconductor wafer 1.

[0038] The operation will now be described. On the surface of semiconductor wafer 1, a BST film having a thickness of 60 mm is formed (not shown). After that, a Pt film having a thickness of 50 mm is formed (not shown). Wafer 1 is rotated at an arbitrary rotational speed in a range from 500 to 1000 rpm. At a time point when the rotational speed reaches the arbitrary rotational speed in the range from 500 to 1000 rpm, pure water is started to be discharged from wafer surface-side discharge nozzle 2 toward the surface of wafer 1 and a solution of hydrochloric acid and hydrogen peroxide (hereinbelow, described as HPM) is discharged from wafer back-side discharge nozzle 3 toward the back of wafer 1.

[0039] The pure water discharged toward the surface side of wafer 1 is used to protect the surface of the wafer. The flow rate of the pure water is 1 to 3 l/min. The mixture ratio of HPM to the back of the wafer, that is, hydrochloric acid (having concentration of hydrogen chloride of 30 wt %): hydrogen peroxide water (having concentration of hydrogen peroxide of 30 wt %):pure water is 1:1:5, and the temperature of the HPM is 75° C.

[0040] By the process, the HPM is applied to only the whole back and bevel of the wafer, and the Pt contaminant on the portions is dissolved and removed.

[0041] The diameter of the discharge hole of each of nozzles 2 and 3 on the surface and back sides is 3 to 10 mm. The discharge hole is positioned over the center of the wafer. The distance from wafer 1 to each of nozzles 2 and 3 is 100 mm or shorter and is arbitrary as long as nozzles 2 and 3 do not come into contact with wafer 1.

[0042] Referring to FIG. 3, in 60 seconds from the start of discharge of the HPM, the discharge of the HPM from back-side nozzle 3 is stopped and discharge of pure water from back-side nozzle 3 is started. The flow rate of the pure water is 1 to 3 l/min. During this period, the pure water remains discharged from surface-side nozzle 2.

[0043] Referring to FIG. 4, in 30 seconds from the start of the discharge of pure water from back-side nozzle 3, the discharge of the pure water from back-side nozzle 3 is stopped, and discharge of dilute hydrogen fluoride (abbreviated as DHF) is started from back-side nozzle 3. The mixing ratio of DHF is hydrofluoric acid (having concentration of hydrogen fluoride of 50 wt %):pure water=1:10, and the temperature of the DHF is 25° C. The flow rate of the DHF is 1 to 3 l/min. During this period as well, pure water remains discharged from surface-side nozzle 2.

[0044] By the process, the DHF is applied on the whole back and the bevel of the wafer and the Ba, Sr, and Ti contaminants in this portions are dissolved and removed.

[0045] Referring to FIG. 5, in 30 seconds after the start of discharge of DHF, the discharge of DHF from back-side nozzle 3 is stopped and discharge of pure water from back-side nozzle 3 is started. The flow rate of the pure water is 1 to 3 l/min. During this period as well, the pure water remains discharged from surface-side nozzle 2.

[0046] In 30 seconds after the start of the discharge of pure water from back-side nozzle 3, the discharge of the pure water from both surface-side and back-side nozzles 2 and 3 is stopped, and the rotational speed of the wafer is increased from an arbitrary rotational speed in a range from 500 to 1000 rpm to an arbitrary rotational speed in a range from 1500 to 2000 rpm. From the time point when the rotational speed reaches the arbitrary rotational speed in the range from 1500 to 2000 rpm, the state is kept for 30 seconds to dry the surface and back of wafer 1.

[0047] By performing the process of the flow once, the Pt, Ba, Sr, and Ti contaminants on the back and bevel of the wafer are removed.

[0048] Also in the case where the Pt film formed on the BST film is a Pt—Ir film, by performing the process of the flow once, the Pt, Ir, Ba, Sr, and Ti contaminants on the back and the bevel of the wafer are removed. On the other hand, since a chemical or the like is not applied on the surface of wafer 1, the surface of wafer 1 is protected.

[0049] Although the case where the DHF is obtained by dissolving hydrogen fluoride into pure water has been described in the embodiment, any chemical which dissolves hydrogen fluoride can be used. In this case, proper processing parameters have to be set for each chemical.

[0050] In the flow, when the order of discharging the chemicals toward the back of the wafer is reversed (DHF→HPM), although the Pt contaminant can be removed, the Ba, Sr, and Ti contaminants cannot be removed and remain.

[0051] This occurs for the following reason. The Pt contaminant (Pt film and Pt) existing on the BST film cannot be removed by etching using the DHF, and the remained Pt becomes a protection mask of the BST film, so that the Ba, Sr, and Ti contaminants (BST film) remain. By the subsequent discharge of the HPM, the Pt contaminant as the mask when the DHF is discharged is removed. However, since the etching rate of the BST film which remains due to the Pt contamination is low, even after the HPM process, the Ba, Sr, and Ti contaminants (BST film) remain. It is therefore important that the discharge order of the chemicals from back nozzle 3 is HPM and then DHF.

[0052] Second Embodiment

[0053] The first embodiment is modified by setting the rotational speed of the wafer to 200 rpm in the processes other than the drying process and setting the discharge flow rate of the chemical toward the back to 2.0 l/min. With the parameters, the chemicals (HPM and DHF) toward the back are also applied to the surface edge, to thereby remove the Pt, Ir, Ba, Sr, and Ti contaminants on the surface edge, back, and bevel portion of the wafer.

[0054] Third Embodiment

[0055] Although pure water is discharged from the wafer surface-side nozzle in the first embodiment, in place of pure water, nitrogen may be discharged. The flow rate of nitrogen is 200 l/min. In place of nitrogen, dry air may be discharged. Also in the case of discharging nitrogen or dry air, by adjusting the rotational speed and the discharge amount of the chemical toward the back, the range of removing a contaminant (chemical application range) is not limited to only the wafer back and bevel but can be expanded to the surface edge. Also by adjusting the flow rate of nitrogen or dry air, the range in which contaminants are removable can be adjusted.

[0056] Fourth Embodiment

[0057] Although the chemical discharged first toward the back is HPM in the first embodiment, in place of the HPM, a solution of nitric acid and hydrochloric acid may be discharged. The discharge time is 30 seconds and the discharge flow rate is 1.0 l/min. The mixture ratio of the solution between nitric acid (having concentration of nitric acid: 70 wt %) and hydrochloric acid (having concentration of hydrogen chloride: 30 wt %) is 1:3. The solution is commonly called aqua regia. The temperature of the solution is 45° C. By using aqua regia in place of the HPM, improved removability of the Pt contaminant is achieved, and discharge time can be shortened to 30 seconds.

[0058] In a manner similar to the second and third embodiments, by adjusting the rotational speed, the flow rate of the chemical on the back side, and flow rate of each of the pure water, nitrogen, and dry air on the surface side, the range of removing contaminants (chemical application range) can be adjusted.

[0059] The embodiments disclosed herein are to be considered in all respects as illustrative and not restrictive. The scope of the invention is indicated by the appended claims rather than by the foregoing description and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.

[0060] As described above, by the method of cleaning a semiconductor device according to the invention, only the surface edge, back, and bevel of a wafer are selectively cleaned. Thus, while protecting the surface of the wafer, contaminants can be removed.

[0061] The apparatus for cleaning a semiconductor device according to the invention selectively cleans only the surface edge, back, and bevel of a wafer, so that contaminants can be removed while protecting the surface of the wafer.

[0062] In the method of manufacturing a semiconductor device according to the invention, only the surface edge, back, and bevel of a wafer are selectively cleaned. Thus, contaminants can be removed while protecting the surface of the wafer.

[0063] Although the present invention has been described and illustrated in detail, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, the spirit and scope of the present invention being limited only by the terms of the appended claims.