Abstract: Apparatus and method for exposing a selected feature of an integrated circuit device such as a selected portion of the metallization layer, from the backside of the integrated circuit substrate without disturbing adjacent features of the device such as the active semiconductor regions. This is performed using an FIB (focused ion beam) etching process in conjunction with observation by an optical microscope to form a trench through the substrate. The process includes a precise optical endpointing technique to monitor the remaining thickness of the semiconductor substrate at the floor of the trench. It is important to terminate etching of the trench so that the trench floor extends as close to the active semiconductor structures as desired and yet is not detrimental to device operation. This is done without introducing a need for any additional tool.

Abstract: An apparatus and method for detecting an endpoint for an etching process utilize a reaction chamber with an ion source and detector placed within the reaction chamber. The ion source directs a primary beam of ions towards a wafer so that the ion beam impacts the top layer of the wafer. A detector detects primary ions reflected from the wafer and secondary ions scattered from the wafer. A value is determined that corresponds to the amount of reflected and scattered ions. A change in the value indicates that the ion beam is impacting a layer beneath the top layer of the wafer, and signifies the reaching of the etch process endpoint.

Abstract: A semiconductor process recording apparatus comprises a buffer circuit and a endpoint recording device. The input terminal of the buffer circuit is connected to an external endpoint apparatus for receiving a first signal output from the endpoint apparatus. The output terminal of the buffer circuit is connected to the endpoint recording device for outputting a second signal representative of the first signal in response to the first signal. When receiving the second signal, the endpoint recording device outputs a feedback signal to the buffer circuit on the basis of the second signal. Because the feedback signal is blocked by the buffer circuit, the external endpoint apparatus is protected from the damage caused by the feedback signal, thereby greatly reducing the production cost and rate of semiconductor manufacturing.

Abstract: Apparatus for processing semiconductor wafers includes a processing chamber, a chuck within the chamber for supporting a wafer during processing, a fiberoptic cable having a first end positioned at the surface of the chuck, and an optical pyrometer connected to a second end of the cable. The optical pyrometer measures the temperature of a wafer during processing and measures in situ temperature of plasma-excited cleaning gas introduced into the chamber during subsequent cleaning from walls thereof of unwanted solid deposits within the chamber. The pyrometer is connected to a computer which controls the flow of cleaning gases. When the temperature of the plasma-excited gas reaches a steady-state value the computer stops the flow of cleaning gases into the chamber and thereby stops the cleaning operation.

Abstract: A method for monitoring an etch process of a substrate that includes receiving a first signal having a first wavelength, deriving a second signal based on the first signal and combining the first signal with the second signal to produce a composite signal having a composite wavelength less than the first wavelength. The method further includes identifying one or more inflection points of the composite signal and determining an etch rate of an etch process by evaluating the inflection points and elapsed time between the inflection points.

Abstract: A plasma processing apparatus for processing an object arranged within a chamber by utilizing the plasma caused within the chamber, the apparatus including: a sensor having plural lines of a plurality of elements for detecting a plurality of strip-like beams; an application unit for applying the plurality of strip-like beams generated from the light within the chamber in such a way that each of the illumination faces of the strip-like beams makes an angle with respect to each of the lines of the elements; and a control unit for adjusting the operation of the apparatus using outputs from the sensor.

Abstract: A method and apparatus for monitoring a process by employing principal component analysis are provided. Correlated attributes are measured for the process to be monitored (the production process). Principal component analysis then is performed on the measured correlated attributes so as to generate at least one production principal component; and the at least one production principal component is compared to a principal component associated with a calibration process (a calibration principal component). The calibration principal component is obtained by measuring correlated attributes of a calibration process, and by performing principal component analysis on the measured correlated attributes so as to generate at least one principal component. A principal component having a feature indicative of at least one of a desired process state, process event and chamber state then is identified and is designated as the calibration principal component.

Abstract: A system and method for determining precisely in-situ the endpoint of halogen-assisted charged particle beam milling of a hole or trench in the backside of the substrate of a flipchip packaged IC. The backside of the IC is mechanically thinned. Optionally, a coarse trench is then milled in the thinned backside of the IC using either laser chemical etching or halogen-assisted charged particle beam milling. A further small trench is milled using a halogen-assisted charged-particle beam (electron or ion beam). The endpoint for milling this small trench is determined precisely by monitoring the power supply leakage current of the IC induced by electron-hole pairs created by the milling process. A precise in-situ endpoint detection signal is generated by modulating the beam at a reference frequency and then amplifying that frequency component in the power supply leakage current with an amplifier, narrow-band amplifier or lock-in amplifier.

Abstract: At each measurement time, reflected light from a semiconductor wafer W or the like by measurement light from a measurement light source 11 is coupled to reference light from a reference light generating section 14, and interference light is detected by a photodetector 15. A raw thickness value calculating section 16b selects two light intensity peaks corresponding to the upper and lower surfaces of the wafer W from a light intensity distribution between an interference light intensity and a reference optical path length and calculates a raw thickness value. A statistical thickness value calculating section 16c executes statistical processing including data sorting, determination whether the raw thickness value falls within an allowable numerical value range, and determination of a thickness change line, thereby obtaining a statistical thickness value.

Abstract: The present invention is a method for end point detection where emission spectra are detected during etching of an object to be processed, such as a semiconductor wafer, by a spectrometer, and an end point of the etching is detected, comprising performing etching of a sample, corresponding to a product, prior to etching of a semiconductor wafer which is the product, sequentially measuring full-spectra of plasma, performing principal component analysis of the emission spectra using the emission intensities of all wavelengths of each of the full-spectra, holding the results as data, thereafter obtaining a principal component score for each of the full-spectra sequentially measured during etching of a semiconductor wafer to be manufactured on the basis of the emission intensities of all the wavelengths, and then detecting an end point of etching on the basis of a substantial change of the principal component score for each of the full-spectra sequentially measured.

Abstract: A plasma etching apparatus for a semiconductor wafer generates plasma in a plasma generation space between a susceptor and a showerhead. A shield member is detachably disposed inside the sidewall of a process chamber to prevent reaction products from sticking to the sidewall. A window device is arranged to lead plasma light emitted from plasma out of the process chamber. The window device includes a quartz window plate airtightly attached to the sidewall of the process chamber. The window device also includes an aluminum light guide having a number of capillary through holes for guiding the plasma light to the window plate, and a sapphire cover plate disposed between the window plate and the light guide and covering the openings of the through holes. The light guide and the cover plate are attached to the shield member.

Abstract: An etching end point detector and its related method of use detect a point of time when an etching process ends by using plasma light generated during a plasma process in a chamber of plasma etching equipment. The detector comprises an optical device receiving light generated in a chamber during the etching process and producing from the light a plurality of optical signals having different corresponding wavelengths; signal converting means receiving the plurality of optical signals and converting the plurality of optical signals into corresponding light intensity values indicating an intensity of the corresponding optical signal; and a signal processor accumulating selected ones of the light intensity values corresponding to predetermined wavelengths to produce an EPD value, and in response to the EPD value, determining an end point of the etching process.

Abstract: The present invention is related to a method of monitoring a semiconductor wafer (10) plasma etch process, comprising the steps of projecting light (12) on a wafer surface (14) during plasma etching, so that the light (12) is scattered by the wafer surface (14), detecting the scattered light (16), determining intensities of the detected light with dependence on at least one varying parameter, thereby creating a spectrum, and comparing the spectrum with stored data. The present invention further relates to a system for monitoring a semiconductor wafer plasma etch process.

Abstract: The present invention is directed to optimization of the optical detection system for the use of optical emission spectroscopy in end-point detection. The optimization specifically addresses the needs of a radiant heated wafer system in a downstream process chamber environment. The present invention maximizes signal light from relevant reactions, maximizes signal-to noise and signal-to-background ratios, utilizes very small diagnostics access, collects light from the region of most intense light emission from endpoint processes, collects light from representative parts of an entire wafer with just one diagnostic access port to ensure complete end-point, and eliminates light signals from sources other than the wafer.

Abstract: A semiconductor processing apparatus can be gained that allows an increase in the yield of semiconductor devices with respect to a process carried out on the semiconductor substrate on which a semiconductor device is formed. A semiconductor processing apparatus is provided with the irradiation unit for irradiating the surface of the semiconductor substrate, on which a plurality of semiconductor chips are to be formed, with light at the time when a process is carried out on the semiconductor substrate, with the reflected light detection unit for detecting a plurality of reflected light beams, that are respectively reflected from the regions in which a plurality of semiconductor chips are to be formed and with the determination unit for detecting a plurality of termination points based on information gained by detecting the plurality of reflected light beams.

Abstract: A method and apparatus for cleaning a CVD chamber including optoelectronic detection of the completion or endpoint of the cleaning procedure once a ratio of emission lines reaches a threshold value. The method comprises the steps of: providing a plasma of a cleaning gas into the chamber and creating a plasma from the cleaning gas. The intensity of emission lines of the cleaning gas and of at least one background gas in the chamber are monitored. A ratio of the intensity of the cleaning gas emission line to the intensity of the background gas emission line is determined and monitored as a function of time. The determined ratio is compared to a preset threshold calibration value. The flow of gas is controlled based on the comparing step. The apparatus includes a cleaning gas supply with a valved inlet providing an entrance to the interior of the chamber for passing cleaning gas to the interior of the chamber. A detector having an optical input is disposed for sensing the electromagnetic radiation.

Abstract: A vacuum treatment system in which a part (9) is provided inside a vacuum treatment chamber (1). A potential (&phgr;9) which deviates from the system reference potential (&phgr;0) by approximately at least ±12 V is applied to said part. A sensor and/or an actuator (11) is/are arranged on said part. In addition, the invention comprises an electronic unit (13) which is connected to the sensor and/or actuator. Processing signals on the unit (13) is considerably simplified in that the electronic unit (13) is operated as a reference potential on the potential (&phgr;9) of said part (9).

Abstract: A method and apparatus for monitoring a process by employing principal component analysis are provided. Correlated attributes are measured for the process to be monitored (the production process). Principal component analysis then is performed on the measured correlated attributes so as to generate at least one production principal component; and the at least one production principal component is compared to a principal component associated with a calibration process (a calibration principal component). The calibration principal component is obtained by measuring correlated attributes of a calibration process, and by performing principal component analysis on the measured correlated attributes so as to generate at least one principal component. A principal component having a feature indicative of at least one of a desired process state, process event and chamber state then is identified and is designated as the calibration principal component.

Abstract: A system detects the clearing of a dielectric at a plurality of contact sites by measuring the surface voltage of the dielectric and comparing the surface voltage to a reference voltage set to a value that relates to the cleared contact sites. Another system detects the clearing of a dielectric at a plurality of contact sites on a substrate by measuring the rate of change of a substrate current during an etch process and ending the etch process when the rate of change is approximately zero. Another system detects the clearing of a dielectric at a contact site by measuring a substrate current during an etch process and ends the etch process when the measured substrate current exceeds a predetermined value.

Abstract: A method and apparatus for endpointing a planarization process of a microelectronic substrate. In one embodiment, the apparatus may include a species analyzer that receives a slurry resulting from the planarization process and analyzes the slurry to determine the presence of an endpointing material implanted beneath the surface of the microelectronic substrate. The species analyzer may include a mass spectrometer or a spectrum analyzer. In another embodiment, the apparatus may include a radiation source that directs impinging radiation toward the microelectronic substrate, exciting atoms of the substrate, which in turn produce an emitted radiation. A radiation detector is positioned proximate to the substrate to receive the emitted radiation and determine the endpoint by determining the intensity of the radiation emitted by the endpointing material.

Abstract: A method and system for determining a dry etching endpoint, at which a dry etching process should be terminated. The dry etching process is carried out in a plasma etching system and comprises the steps of detecting an intensity of light emission generated in the dry etching process, the light emission being extracted through a window located on a side wall portion of a reaction chamber below a horizontal plane which is defined by a surface of a body to be etch treated. The detected intensity is compared to a predetermined threshold level.

Abstract: A system for characterizing an etch process via scatterometry based real time imaging is provided. The system includes one or more light sources, each light source directing light to one or more features and/or gratings on a wafer. Light reflected from the features and/or gratings is collected by a measuring system, which processes the collected light. The collected light is indicative of the etch results achieved at respective portions of the wafer. The measuring system provides etching related data to a processor that determines the desirability of the etching of the respective portions of the wafer. The system also includes one or more etching devices, each such device corresponding to a portion of the wafer and providing for the etching thereof. The processor produces a real time etch image to characterize the progress of the etching and, in one example, produces suggested adaptations to the etch process.

Abstract: A system for monitoring and/or controlling an etch process associated with a dual damascene process via scatterometry based processing is provided. The system includes one or more light sources, each light source directing light to one or more features and/or gratings on a wafer. Light reflected from the features and/or gratings is collected by a measuring system, which processes the collected light. The collected light is indicative of the etch results achieved at respective portions of the wafer. The measuring system provides etching related data to a processor that determines the desirability of the etching of the respective portions of the wafer. The system also includes one or more etching devices, each such device corresponding to a portion of the wafer and providing for the etching thereof. The processor produces a real time feed forward information to control the etch process, in particular, terminating the etch process when desired end points have been encountered.

Abstract: A method for detecting an end point of an etching step conducted in an etching chamber. A target emission intensity level is selected for the etching step, and the etching step is performed in the etching chamber. A raw emission intensity level is sensed from the etching chamber during the etching step with an emission intensity level detector. The raw emission intensity level sensed from the etching chamber by the emission detector is modified with an emission intensity level modifier. The raw emission intensity level sensed with the emission intensity level detector from the etching chamber during the etching step is adjusted to the target emission intensity level by adjusting the emission intensity level modifier. The etching process is stopped upon occurrence of a predetermined spectral event sensed by the emission intensity level detector.

Abstract: An organic polymer film can be completely decomposed and removed from a substrate surface by exposing the film to ultraviolet radiation having a wavelength of 180 nm or less. Also, ultraviolet radiation not longer than 180 nm in wavelength is scarcely transmitted through a transparent conductive oxide such as ITO and, thus, can be used for eliminating a defective polyimide alignment film formed on a color filter substrate and an array substrate having a transparent electrode pattern of ITO formed on the surface of a pigment portion and a TFT structure, respectively. According to the present invention, the defective alignment film on the substrates can be removed completely without any damage such as discoloring of the pigment portion and/or changing the TFT characteristics.

Abstract: Methods and apparatuses for mechanical and/or chemical-mechanical planarization of semiconductor wafers, field emission displays and other microelectronic substrate assemblies. One method of planarizing a microelectronic substrate assembly in accordance with the invention includes pressing a substrate assembly against a planarizing surface of a polishing pad at a pad/substrate interface defined by a surface area of the substrate assembly contacting the planarizing surface. The method continues by moving the substrate assembly and/or the polishing pad with respect to the other to rub at least one of the substrate assembly and the planarizing surface against the other at a relative velocity. As the substrate assembly and polishing pad rub against each other, a parameter indicative of drag force between the substrate assembly and the polishing pad is measured or sensed at periodic intervals. The measured drag force can be used to generate a plot of work versus time.