JP2008108751A - Processing/observing device, and processing/observing method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a processing/observing device of a semiconductor that can reduce time spent for drawing processing and has high precision in the processing/observation of a sample. <P>SOLUTION: The processing/observing device of a semiconductor comprises: a processing device irradiating ion beams for drawing processing including Ga ion beams; a scanning electron microscope device irradiating electron beams; a powder removing device irradiating ion beams for powder removal including Ar ion beams; a vacuum vessel storing the three devices together; and a placement table that is placed in the vacuum vessel and places a sample. The processing/observing device is arranged so that each beam emitted by the three devices gathers at the sample, has a detector detecting secondary electrons generated from the sample with the irradiation of electron beams, and allows the acceleration voltage of the scanning electron microscope device irradiating electron beams to be approximately 0.6-3 keV. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a semiconductor processing and observation apparatus capable of observing a drawing process of a semiconductor wafer (sample) and defects in the processed part.

  In the conventional technique, in order to observe the cross section of the defect portion, the sample is subjected to drawing processing by FIB (Ga ion beam processing apparatus), the processed cross section is subjected to surface finishing by flat milling, and SEM (scanning electron microscope apparatus) or It was observed with a SIM (scanning ion beam microscope).

  Also, as described in Japanese Patent Laid-Open No. 4-1166843 (Patent Document 1), a sample is irradiated with a focused Ga ion beam to form a drawing, and the surface of the formed cross section is subjected to ion-assisted etching using an etching gas. Alternatively, there is a method in which cleaning is performed by etching using an ion beam and observation is performed with an SEM.

  A semiconductor processing apparatus disclosed in Japanese Patent Application Laid-Open No. 58-164135 (Patent Document 2) is a processing ion beam generating means for processing a sample, an electron beam generating means for observing the processed portion, and a processed portion. The laser beam generating means for repairing these defects is provided, and these three beam generating means are housed in one vacuum processing chamber.

Japanese Patent Laid-Open No. 4-1166843 JP 58-164135 A

  In the above prior art, three devices (FIB, flat milling device, SEM) are used. After processing with FIB, the sample is replaced with a flat milling device, and after surface finishing, it is further replaced with SEM. It took a long time to change the air pressure to vacuum and to return to atmospheric pressure.

  In the description of Patent Document 1 (Japanese Patent Laid-Open No. 4-1166843), after processing the sample with FIB, the sample is moved into the chamber of an Ar ion beam gun to remove the processing powder. Further, the processed cross section must be observed by moving the sample into the SEM chamber.

  Since the above operation is a repetitive process of digging the position of the processed cross section little by little while sequentially observing the processed cross section, a lot of time is spent. Further, there is a problem that displacement due to movement is likely to occur, and accuracy of processing and observation is inferior.

  In addition, when a semiconductor wafer or the like is observed by SEM at a high acceleration voltage (5 to 30 keV), there is a problem that the sample is charged up (charged) and the image moves, and it is difficult to observe the image. However, in order to prevent the charge-up of the sample, when it is performed at a low acceleration voltage (0.6 to 3 keV), there is a problem that a clear SEM image of the processing cross section cannot be obtained due to the influence of the processing powder adhering.

  Patent Document 2 (Japanese Patent Application Laid-Open No. 58-164135) performs observation using a phenomenon in which a defect portion extends due to heat generated by irradiation with an electron beam or a laser beam, or repairs a processed cross section with a laser beam. Therefore, it is not intended to obtain a clear image of the processed cross section.

  In view of the above problems, the present invention can observe the observation point (location) of the processed cross section processed by the FIB with a clear SEM image, and can reduce the time spent in the work of digging the processing position little by little while sequentially observing, An object of the present invention is to provide a semiconductor processing and observation apparatus with high accuracy in processing and observing a sample.

  The present invention relates to a processing apparatus that irradiates a drawing ion beam containing a Ga ion beam, a scanning electron microscope apparatus that irradiates an electron beam, and a powder removal that irradiates a dust removing ion beam that includes an Ar ion beam. The apparatus, a vacuum container that collectively stores these three apparatuses, and a mounting table that is placed in the vacuum container and on which the sample is placed, and the beams irradiated by the three apparatuses are collected on the sample. The detector has a detector that detects secondary electrons generated from the sample by electron beam irradiation, and the acceleration voltage of the scanning electron microscope apparatus that irradiates the electron beam is set to about 0.6 keV to 3 keV. It is characterized by.

  The present invention also provides a scanning electron microscope apparatus after removing a processing powder adhering to a sample with a dust removing ion beam of a dust removing device after drawing the sample with a drawing ion beam of the processing device. It is characterized by observing the image drawn and processed.

  ADVANTAGE OF THE INVENTION According to this invention, the time spent for drawing process can be shortened and the semiconductor processing observation apparatus with the high precision of a process and observation of a sample can be provided.

  Embodiments of the present invention will be described with reference to the drawings.

  First, a semiconductor processing observation apparatus according to the present invention will be described with reference to FIG.

  This semiconductor processing observation apparatus includes an FIB 11 (processing apparatus that irradiates a Ga ion beam) that performs drawing processing on a semiconductor wafer, and an SEM 1 that performs observation of a processing section processed by the FIB (scanning electron microscope that irradiates an electron beam). Apparatus) and FIB 21 (powder removal apparatus for irradiating an Ar ion beam) for removing the processing powder adhering to the processing cross section.

FIB 11, SEM 1, and FIB 21 are stored together in the vacuum container 50 of the processing observation apparatus. This one vacuum container 50 has an upper container part and a lower container part, and the FIB 11, SEM1, and FIB 21 are attached to the upper container part. The vacuum container 50 is kept at a vacuum degree of about 10 ⁻⁷ Torr.

  A sample placement table 31 is provided in the lower container portion of the vacuum container 50. A sample 32 is placed on the sample placement table 31. The sample 32 is a semiconductor wafer. The FIB 11, SEM 1, and FIB 21 are arranged so that the beams irradiated by the FIB 11, SEM 1, and FIB 21 are collected on the sample 32.

  The sample mounting table 31 is reciprocally movable in the vertical direction (Y direction) and the horizontal direction (X direction) as well as rotating.

  The FIB 11 includes an ion beam irradiation source 12 that irradiates a Ga ion beam 13 (an ion beam for drawing processing). The ion beam for drawing processing to be irradiated is focused by the FIB electromagnetic lens 14 and the FIB objective lens 16, deflected by the FIB deflection lens 15, and scans the upper surface of the sample 32.

  Drawing (drawing processing) is formed on the upper surface of the sample 32 by irradiation of the ion beam for drawing processing. Further, secondary electrons are generated from the sample 32 by irradiation of the ion beam for drawing processing. The detector 34 provided on the upper container portion side of the vacuum container 50 detects the secondary electrons. The detection signal detected by the detector 34 is image-processed by the image processing device 35 and displayed on the image display monitor 36 by the processed signal.

  The FIB 21 includes an ion beam irradiation source 22 that irradiates a Ga ion beam 23 (a powder ion beam for dust removal). The ion beam for powder removal to be irradiated is narrowed down by the Ar electromagnetic lens 24 and the Ar objective lens 26 and deflected by the Ar deflection lens 25 to scan the upper surface of the sample 32.

  Drawing is not performed by the irradiation of the ion beam for powder removal, but cleaning is performed to repel the powder of the drawing processing that adheres to the processing portion that has come out in the drawing processing by the FIB 11. Further, secondary electrons are generated from the sample 32 by irradiation with the ion beam for powder removal. The secondary electrons are detected by the detector 34, and the detection signal is subjected to image processing by the image processing device 35 and displayed on the image display monitor 36 by the processing signal.

  The SEM 1 has an electron beam irradiation source that irradiates the electron beam 3. The irradiated electron beam is focused by the SEM electromagnetic lens 4 and the SEM objective lens 6 and deflected by the SEM deflection lens 5 to scan the upper surface of the sample 32.

The secondary electron 33 generated from the sample 32 is detected by the detector 34 by the scanning of the electron beam 3, and the detection signal is subjected to image processing by the image processing device 35 and displayed on the image display monitor 36 by the processing signal. I can observe.
The SEM 1 is used to observe the processing location of the sample 32 (semiconductor wafer) while the SEM acceleration voltage is maintained at a low acceleration voltage of 0.6 to 3 keV. Since the acceleration voltage is low, charge-up (charging) is difficult to be performed on a semiconductor wafer (low conductivity unlike metal such as iron). For this reason, the movement (fluctuation etc.) of the image does not occur, and a stable image can be observed. In addition, the irradiation of the ion beam for powder removal by the FIB 21 is used to repel and clean the drawing processing powder adhering to the processing site, so that a clear SEM image is obtained despite the low acceleration voltage. The processing cross section of the drawing processing by the FIB 11 can be better observed, and the observation accuracy is improved.

  Drawing processing and observation will be described with reference to FIG.

  FIG. 2A shows a state where the defect portion of the wafer 41 is processed by irradiating the ion beam by the FIB 11. The ion beam irradiation scan is performed with a width in the A direction. FIG. 2B shows a state when the FIB 11 is used as a SIM (microscope using an ion beam scan). In this observation, the SIM image is observed by adjusting the acceleration voltage of the FIB to be low. However, a defect that the defective portion is scraped off occurs due to repeated scanning of the ion beam irradiation (X2 direction).

  On the other hand, since the observation with the SEM 1 is irradiation with an electron beam, the processed cross section drawn can be examined carefully in detail including the presence or absence of defects without fear of cutting the defective portion. In response to the observation result, more accurate drawing processing by FIB can be performed.

  The powder removal will be described with reference to FIGS. 3 and 4.

  As shown in FIG. 3, a processing hole 42 can be formed in the wafer 41 with a Ga ion beam 13 (an ion beam for drawing processing). As shown in FIG. 4, the processed hole 42 has a structure in which the surface side layer of the wafer 41 is formed by stacking multilayer films such as tungsten (w) and carbon (c). The laminated section of this section is observed and analyzed with the SEM 1, and the processing powder 45 by FIB processing is attached to the laminated section 43 as shown in FIG. In this state, the attached processing powder 45 becomes an obstacle and a clear observation image by SEM cannot be obtained.

  Therefore, as shown in FIG. 4 (b), the cross section of the multilayer film to be observed is irradiated with an Ar ion beam 23 (ion removal ion beam), and the adhering processing powder 45 is removed as shown in FIG. 4 (c). A clear observation image by SEM is obtained. It is desirable to clean the debris by the ion beam for dedusting by squeezing it by SEM observation.

  In other words, since cleaning is performed so that the powder of drawing processing attached by irradiation of the ion beam for powder removal is repelled, if the Ar ion beam is irradiated over a wide range, the processing powder scatters from the other cross section or the bottom surface of the processing hole 42. The problem is that the processed powder re-adheres to the observation site. As shown in FIG. 4 (d), the surface treatment is performed by scanning the Ar ion beam 23 only on the observation surface 46, thereby obtaining a clean surface-treated (cleaned) observation surface, and a clear observation image by SEM. Can be obtained.

  As described above, the processing apparatus (FIB11) for irradiating the Ga ion beam, the scanning electron microscope apparatus (SEM1) for irradiating the electron beam, and the dust removing apparatus (FIB21) for irradiating the Ar ion beam are collectively put in the vacuum vessel 50. Since these three devices are arranged so that the beams irradiated by these three devices are collected on the sample 32, the time spent can be shortened, and drawing processing with high processing accuracy can be performed.

  That is, since the FIB 11, the SEM 1, and the FIB 21 are housed in one vacuum vessel 50 and are arranged so that each beam is gathered on the sample 32, the drawing process, the powder removal process, and the observation This eliminates the need to move in and out of the sample 32 that is performed every time the process moves to the process, and the work time spent in these series of processes is shortened. Since these steps are sequentially repeated through the process of digging the drawing processing position little by little, the time is greatly reduced.

  The sample mounting table 31 is reciprocally movable in the vertical direction (Y direction) and the horizontal direction (X direction) as well as rotating. This rotation and reciprocal movement are performed on a stationary platen that stably supports the sample mounting table within a range of one wafer, so that there is almost no displacement due to movement, and processing is performed. The accuracy and observation accuracy can be improved, and the observation site can be cleaned accurately. This is a semiconductor processing observation apparatus with high drawing processing accuracy.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic configuration diagram of a semiconductor processing observation apparatus according to an embodiment of the present invention. The figure which shows a state when a semiconductor wafer is processed and observed with FIB with the conventional apparatus. The figure which concerns on the Example of this invention and shows the semiconductor wafer processed by FIB. Sectional drawing of a process part by FIB concerning the Example of this invention.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... SEM, 2 ... Electron gun, 3 ... Electron beam, 4 ... SEM electromagnetic lens, 5 ... SEM deflection lens, 6 ... SEM objective lens, 11 ... FIB (Ga ion), 12 ... Ga ion gun, 13 ... Ga ion Beam, 14 ... FIB electromagnetic lens, 15 ... FIB deflection lens, 16 ... FIB objective lens, 21 ... FIB (Ar ion), 22 ... Ar ion gun, 23 ... Ar ion beam, 24 ... Electromagnetic lens for Ar, 25 ... Ar Deflection lens, 26 ... objective lens, 31 ... sample holder, 32 ... sample, 33 ... secondary electron, 34 ... secondary electron detector, 35 ... image processing device, 36 ... image display monitor, 41 ... wafer, 42 ... Processed hole, 43 ... Laminated surface, 44 ... Fracted surface, 45 ... Processed powder, 46 ... Observation surface.

Claims (3)

A processing apparatus for irradiating a drawing ion beam including a Ga ion beam, a scanning electron microscope apparatus for irradiating an electron beam, a powder removing apparatus for irradiating a powder ion beam including an Ar ion beam, and the like A vacuum container that collectively stores the three devices, and a placement table that is placed in the vacuum container and places a sample,
The three devices are arranged so that each beam to irradiate gathers on the sample,
It has a detector for detecting secondary electrons generated from the sample by irradiation of the electron beam, and the acceleration voltage of the scanning electron microscope apparatus for irradiating the electron beam is set to about 0.6 keV to 3 keV. Semiconductor processing observation equipment. In the semiconductor processing observation apparatus according to claim 1,
An apparatus for processing and observing a semiconductor, comprising: an image processing device that performs image processing on a detection signal detected by the detector; and an image display monitor that displays an image using the processing signal processed by the image processing device. A processing apparatus for irradiating a drawing ion beam including a Ga ion beam, a scanning electron microscope apparatus for irradiating an electron beam, a powder removing apparatus for irradiating a powder ion beam including an Ar ion beam, and the like A vacuum vessel in which the three devices are housed together, and a placement table placed in the vacuum vessel and on which a sample is placed,
The three devices are arranged so that each beam to irradiate gathers on the sample,
The detector has a detector that detects secondary electrons generated from the sample by irradiation of the electron beam, and the acceleration voltage of the scanning electron microscope apparatus that irradiates the electron beam is about 0.6 keV to 3 keV,
The scanning electron microscope after removing the processing powder adhering to the sample with the ion beam for dust removal of the powder removal device after drawing the sample with the ion beam Ga ion beam for the drawing processing of the processing device An operation method of a semiconductor processing and observation apparatus, characterized by performing observation of a drawing processed by the apparatus.

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