The present invention is directed to methods and systems for the inspection of surfaces and materials, including semiconductor surfaces and semiconductor materials. More particularly, the present invention is directed to methods for the classification of surface or subsurface non-uniformities and/or charges detected using at least one of a vibrating and a non-vibrating contact potential difference sensor.
The function, reliability and performance of semiconductor devices depend on the use of semiconductor materials and surfaces which are clean and uniform. Billions of dollars and countless man-hours have been spent developing, characterizing, and optimizing systems and processes for fabricating and processing semiconductor materials. A primary goal of this activity has been the fabrication of materials and surfaces that are extremely clean and that have properties that are uniform, or vary uniformly, across the entire wafer. In order to characterize and optimize these processes it is necessary to be able to inspect and measure surface or bulk cleanliness and uniformity. For real-time process control, it is necessary to be able to make many measurements across a surface at high speed, and to do so in a manner that does not damage or contaminate the semiconductor surface. It is also highly desirable to be able to discriminate and classify different types of non-uniformities or contaminants. Classification is extremely important. Information on the nature of a non-uniformity can be used to determine if the non-uniformity might impact device performance or manufacturing yield. Classification information can also be used to identify the source of the non-uniformity.
One method of inspecting and measuring surfaces utilizes a non-vibrating contact potential difference sensor. The non-vibrating contact potential difference sensor consists of a conductive probe that is positioned close to a surface, and is electrically connected to the surface. The probe and the surface form a capacitor. A potential difference is formed between the probe tip and the surface due to the difference in work functions or surface potentials of the two materials. The probe tip is translated parallel to the surface, or the surface is translated beneath the probe. Changes in the work function or surface potential at different points on the surface result in changes in potential between the surface and the probe tip. Also, changes in the distance between the probe tip and the wafer surface results in changes in the capacitance. Changes in either the potential or capacitance between the probe tip and the wafer surface causes a current to flow into the probe tip. This current is amplified, converted to a voltage, and sampled to form a continuous stream of data which represents changes across the surface. The non-vibrating contact potential difference sensor can provide a continuous stream of data at rates greater than 100,000 samples per second. High data acquisition rates permit high-resolution images of whole semiconductor wafers to be acquired in only a few minutes.
The non-vibrating contact potential difference sensor produces a signal that is a combination of two characteristics of the measured surface-changes in surface potential and changes in surface height. The charge on the probe tip is determined as follows:
Q=CV (1)
Where Q is the charge on the probe tip, C is the capacitance between the probe tip and the measured surface, and V is the potential difference between the probe tip and the surface.
The current, i, into the probe tip is the derivative of the charge on the probe tip and is given by the following formula:
The current, i, is the sum of two terms: the dV/dt term and the dC/dt term. The dV/dt term represents changes in the voltage between the probe tip and the wafer surface, and the dC/dt term represents changes in the capacitance between the probe tip and the wafer surface. The potential of the probe tip is fixed during the scanning operation, so changes in the dV/dt term arise from changes in the potential of the measured surface. Changes in capacitance result from changes in the distance between the probe tip and the wafer surface, which most often result from changes in the height of the wafer surface. This formula illustrates how the current into the sensor is a combination of changes in the potential and height of the measured surface.
Changes in surface potential can result from a variety of changes in surface and subsurface conditions. These include; but are not limited to; contamination by metals, contamination by non-metals or organics, changes in surface chemistry, changes in the number or type of molecules from the environment that adsorb on the surface, changes in the chemical termination of the surface, charging on the surface, charging in a dielectric deposited on the surface, changes in the atomic roughness of the surface, changes in surface film stress, changes in subsurface doping density or implant dose, changes in subsurface doping or implant depth, changes in potential at subsurface interfaces, changes in subsurface electrical conductivity, changes in crystalline structure or damage, changes in surface illumination, or some combination of these factors.
The non-vibrating contact potential difference sensor system can detect a wide range of surface and subsurface non-uniformities. However, it would be desirable to enhance the capabilities of the non-vibrating contact potential difference sensor inspection system to enable the discrimination and classification of different types of non-uniformities. For example, it would be desirable to discriminate between surface potential non-uniformities resulting from metallic contamination and surface potential non-uniformities resulting from organic contamination. As a second example, it would be desirable to discriminate between surface chemical contamination and variations in the height of the wafer surface.
The system and methods described in this invention provide an enhanced application of at least one of a vibrating and a non-vibrating contact potential difference inspection system that allows the discrimination and classification of different types of surface and subsurface non-uniformities. Hereinafter, material susceptible to inspection by the system herein described will be denoted generally as a “wafer”. The invention includes at least one of a vibrating and a non-vibrating contact potential difference sensor scanning system that generates data representative of surface potential and height variations across the wafer surface. This apparatus consists of at least one of a vibrating and a non-vibrating contact potential difference sensor, a system for mechanically fixturing the wafer, a system for positioning the sensor a fixed distance above the wafer surface and generating relative motion between the probe tip and wafer surface such that the sensor probe tip moves parallel to the wafer surface, and a system for acquiring and processing the output signal from the sensor to identify and classify wafer non-uniformities.
In one embodiment, the system includes the ability to apply a bias voltage to either the sensor probe tip or the wafer surface to modify the electrical potential between the probe tip and wafer. In this case the dC/dt term in equation 2 includes a bias voltage as shown in the following formula:
In equation 3, VCPD is the voltage between the probe tip and wafer surface that results solely from electrically connecting the probe tip and the wafer surface. This voltage is called the Contact Potential Difference, or CPD. Vbias is an additional voltage that is applied to the probe tip or wafer by the inspection system to facilitate detection and classification of wafer non-uniformities. If Vbias is constant during the scanning operation, then it does not affect the dV/dt term because dVbias/dt=0.
In an alternative embodiment the system includes a mechanism for positioning the sensor above a point on the wafer and vibrating the sensor perpendicular to the wafer surface while the bias voltage is adjusted. Vibrating the probe tip perpendicular to the wafer surface causes changes in the capacitance between the probe tip and the wafer surface, which results in a signal due to the VdC/dt term in equations 2 and 3. This signal is proportional to the contact potential difference (V) between the probe tip and the wafer surface. The variable bias is adjusted to determine the bias voltage that matches the potential of the probe tip to the potential of the wafer surface. When the bias voltage is equal and opposite to the contact potential difference between the probe and the wafer then the signal from the sensor goes to zero. By adjusting the bias voltage, the bias that results in zero signal is determined, and the contact potential difference is calculated as the negative of this bias voltage. This method of operation is known as a vibrating Kelvin probe or Kelvin-Zisman probe.
In another alternative embodiment the system includes the ability to control the illumination of the wafer surface near the probe tip. This capability allows the wavelength, light intensity or angle of illumination to be configured prior to, as well as during, scanning the surface using the non-vibrating contact potential difference sensor. In yet another alternative embodiment the system includes the ability to deposit charge on the wafer surface prior to the surface being scanned by the non-vibrating contact potential difference sensor. A non-uniformity can also be evaluated by measuring a charge which is deposited or otherwise present on the wafer, or on or in a dielectric layer on the wafer. The non-uniformity can include a charge itself on or in the wafer, or on or in the dielectric layer itself. In addition a change of signal arising from the deposited charge can enable identification of the type and amount of the non-uniformity.
The invention includes a system and methods for processing the resulting non-vibrating contact potential difference data to discriminate between a wide range of different types of surface non-uniformities. In an alternative embodiment, the system includes the ability to obtain multiple scans of the same wafer, or multiple scans of the same part of the same wafer. Each of the multiple scans can be acquired with different bias voltages, illumination wavelengths, illumination intensities, illumination angles; and/or with different amounts of charge applied to, or otherwise present on the surface or embedded into selected layers of a wafer and deposited layers, such as dielectrics. Data from these multiple scans can be processed separately or combined to discriminate between different types and relative amounts of non-uniformities, such as chemical, mechanical and charges.
The non-vibrating contact potential difference data is processed to identify regions of wafer non-uniformity. In one embodiment, this is accomplished by thresholding the differential non-vibrating contact potential difference image. Thresholding involves identifying those data points with specific values, where the specific values are defined as those signal values that are greater than a particular value, less than a particular value, or within some range of values. The particular values used to define areas of wafer non-uniformity are referred to as thresholds. In an alternative embodiment, non-uniformities are identified by integrating the differential data to form an image that represents relative surface potential values. The resulting integrated image can be thresholded to identify regions with specific relative surface potential values or ranges of values. Once regions of non-uniformity are identified, additional processing is performed to classify each region.
In one embodiment, the integrated image data for regions of non-uniformity are compared to the integrated image data for other parts of the wafer to determine if the non-uniformity results in a positive or negative change in surface potential or capacitance. If a non-uniformity represents a change in surface potential, then the direction (positive or negative) of the signal indicates whether the surface potential is increasing or decreasing. If a non-uniformity represents a change in surface height, then the direction of the signal indicates whether the wafer height is increasing or decreasing. This information is then used to classify non-uniformities based on the direction of surface potential or surface height change. For example, surface contamination may result in an increase or decrease in wafer surface potential. Many, but not all, types of metal contamination on silicon surfaces result in an increase in surface potential, while many types of organic contamination on silicon surfaces results in a decrease in surface potential. In inspection applications where likely metal contaminants increase surface potential and likely organic contaminants decrease surface potential, the direction of surface potential change can be used to distinguish between metallic surface contamination and organic surface contamination. Independent data can be used to assist in determining the likelihood of contaminants or non-uniformities being of a particular class, such as metal, non-metal, semiconductor dopants, insulators and ionic impurities. Such independent data can arise from use of other conventional devices, such as SEM, X-ray fluorescence, ion probe, and straightforward evaluation of the likely contaminants from a particular manufacturing process.
The signal component that results from changes in the distance between the probe tip and the wafer surface varies linearly with the voltage between the probe tip and the wafer surface, while the signal component resulting from changes in surface potential is unaffected by a constant bias voltage. As a result, the same wafer can be scanned twice with two different bias voltages, and the resulting images subtracted from each other, to form an image that has minimal signal from surface potential changes and an increased signal from height changes. This is illustrated by the following equations:
In this case, i1 is the current into the probe tip when a bias voltage of Vbias1 is applied, and i2 is the current into the probe tip when a bias voltage of Vbias2 is applied. Because the derivative of the bias voltages is 0, subtracting the two currents results in a new signal that is unaffected by changes in contact potential difference and is formed solely from changes in capacitance between the probe tip and wafer surface. The resulting signal or image can be used to detect and classify non-uniformities as variations in wafer height as opposed to changes in wafer surface potential. Likewise, non-uniformities that appear in an image acquired with no bias voltage, but do not appear in an image that is formed by subtracting two images acquired with different bias voltages, can be classified as a surface potential change as opposed to a surface height change.
The average contact potential difference between the probe tip and the wafer surface can be determined by making vibrating Kelvin probe measurements at one or more points on the wafer surface. A bias voltage which is equal in magnitude, but opposite in polarity, can then be applied to the probe tip to minimize the average difference in potential between the probe tip and wafer surface. The wafer can then be scanned using this bias voltage, and the signal component due to changes in the distance between the probe tip and the wafer surface will be minimized. Subsequent wafers with similar surfaces can also be scanned using the same bias voltage without the need to make additional vibrating Kelvin probe measurements. The use of a bias voltage which minimizes the average potential between the probe tip and the wafer surface permits the formation of a signal and image which can be used to identify non-uniformities in surface potential while minimizing the signal due to changes in the height.
One advantage of the non-vibrating contact potential difference sensor is that it can acquire data relatively quickly, so that whole-wafer images can be acquired in only a few minutes. The availability of high-resolution images permits the use of image processing algorithms to classify non-uniformities based on features associated with their shape or signal levels. For example, the differential or integrated image can be thresholded, and the resulting defect map can be segmented to identify connected regions of non-uniformity. Each region can then be associated with a list of features; such as area, perimeter, height, width, signal range, average signal value, minimum and maximum signal values, and many others. These features can be calculated from the differential or integrated images of the non-uniformities, or from images acquired with different bias voltages, illumination configurations, surface charge conditions, or combinations of these images. This list of features can then be used to classify the defect based on a mathematical algorithm or set of rules. For example, in the simplest case non-uniformities can be classified based on size or standard deviation of the non-vibrating contact potential difference sensor signal.
The ability to control the intensity, wavelength, and angle of illumination; and the amount of charge on the wafer surface or embedded in dielectric or other layers present on the wafer provides additional methods of classifying defects or location and amounts of charge. The surface potential change resulting from some types of defects is sensitive to surface illumination or charging. Illumination can be used to vary the surface potential by reducing the effect of electric fields in the semiconductor, while charge deposited or otherwise present on the surface, or in or on a dielectric layer, can be used to induce electric fields and vary the distribution of charge within the semiconductor. The ability to control the illumination and surface charge allows two or more scans to be acquired with different illumination and/or charge conditions. These scans can then be combined mathematically, for example by subtracting one scan image from another, to determine the change in signal due to changes in illumination or charge. Surface non-uniformities can then be classified based on the magnitude and polarity of the change in signal that results from changing illumination or changing surface charge conditions.
The vibrating Kelvin probe measurement capability provides yet another method of classifying defects. Once a defect has been detected and located within a non-vibrating contact potential difference image, one or more vibrating Kelvin probe measurements can be made to determine the contact potential difference at the location of the defect. The resulting contact potential difference data can be correlated to specific types or concentrations of defects, and this information can be used to identify or quantify the detected defect. Also, vibrating Kelvin probe measurements can be made with different surface charge or illumination conditions to determine the absolute change in surface potential with changing illumination variables or charging of the wafer or other attached layer. This information can also be used to classify the type of defect.
Another method of defect classification involves integrating the signal obtained from the non-vibrating contact potential difference sensor, and then making two or more vibrating Kelvin probe measurements at different points on the wafer. The integrated signal represents relative surface potential values, but does not represent absolute contact potential difference values. The vibrating Kelvin probe measurements can be used to scale the integrated signal values so that they represent absolute contact potential difference values. This is accomplished by calculating a linear or curve fit between the vibrating Kelvin probe measurements and the signal values at the same locations within the integrated image. This transformation is then applied to all integrated signal values. The resulting integrated image values can then be used to classify surface non-uniformities based on their absolute contact potential difference values.
The present invention provides an enhanced inspection system that uses a non-vibrating contact potential difference sensor system to detect surface and sub-surface non-uniformities, including deposited (or otherwise present) charge, and a system for processing data from the non-vibrating contact potential difference sensor to classify different types and relative amounts of non-uniformities. This invention is not limited to the measurement of semiconductors with bare, clean surfaces. The chemical state of the surface may vary, or surface contamination may be present. Also, the wafer surface may be covered with a coating or film. For example, a silicon wafer surface is often coated with a silicon oxide or other dielectric or metal film. This invention can be used to inspect a wafer covered with a film to detect defects in the underlying semiconductor or at the semiconductor-film interface. In addition, this invention can be used to detect or classify defects in, or on, a film.
Referring to
In one embodiment, a semiconductor wafer 105 is placed on a conductive wafer fixture 103. This may be done manually or using an automated process such as, but not limited to, a wafer handling robot. The wafer 105 is held in place such as by using vacuum. Alternative methods of holding the wafer 105 include, but are not limited to, electrostatic forces and edge gripping. In one embodiment, the fixture 103 is mounted to a spindle which can rotate the wafer 105 about its center. The non-vibrating contact potential difference sensor 101 is attached to a positioning system 107 that can adjust the height of the sensor 101 above the wafer surface 106 and can move the sensor 101 radially from at least the center of the wafer 105 to one edge of the wafer 105. The non-vibrating contact potential difference sensor 101 is electrically connected to the wafer surface 106 via the conductive wafer fixture 103. This connection can be resistive or capacitive. In one embodiment, a height sensor 111 that has been calibrated to the height of the non-vibrating contact potential difference sensor probe tip 102 is also mounted on the same positioning system 107 as the non-vibrating contact potential difference sensor 101.
Alternately, a light source 109 with variable intensity, wavelength or angle may be mounted on the positioning system such that the illuminated area includes at least the area next to the non-vibrating contact potential difference sensor probe tip 102. Alternately, a light source can be mounted separate from the positioning system so that it illuminates at least the entire area scanned by the non-vibrating contact potential difference sensor. Alternately, a source of controlled charge may be mounted on the positioning system so that a known amount of charge can be deposited on the wafer surface, or on or in a dielectric layer present on the wafer, prior to, or even during, scanning by the non-vibrating contact potential difference sensor.
In an alternate embodiment, a system 104 for vibrating the sensor 101 perpendicular to the wafer surface 106 is attached to the contact potential difference sensor. This system is used to make vibrating Kelvin probe measurements of the contact potential difference between the probe tip 102 and the wafer surface 106.
After the wafer 105 is secured to the fixture, the height sensor 111 is positioned above one or more points on the wafer surface 106 and the height of the wafer surface 106 is measured. These wafer height measurements are used to calculate the position of the non-vibrating contact potential difference sensor 101 that will produce the desired distance between the probe tip 102 and the wafer surface 106. This information is used to position the probe tip 102 at a fixed height above the wafer surface 106, and the probe tip 102 is moved to a point above the outside edge of the wafer 105. Illumination of the wafer surface may be enabled and the appropriate intensity and wavelength selected for the inspection application. Also, the appropriate amount of charge may be selected for the inspection application.
As shown for example in
One aspect of this invention is the identification or classification of non-uniformities based on the polarity of the surface potential or capacitance change. The differential non-vibrating contact potential difference sensor signal can be integrated to form a signal that represents relative surface potential or capacitance values. As shown in
A second aspect of the invention relates to the discrimination and classification of non-uniformities as resulting from changes in capacitance between the probe tip and the wafer surface or resulting from changes in potential between the probe tip and the wafer surface (see, for example,
The wafer may be scanned twice with different bias voltages and one image subtracted from the other to form a new image that minimizes the signal resulting from surface potential non-uniformities and increases the signal resulting from wafer height non-uniformities. Non-uniformities which are detected in the resulting image are classified as height non-uniformities (see also
A third aspect of this invention is the identification or classification of non-uniformities based on shape or signal value statistics. After non-uniformities in or on the wafer have been identified from the non-vibrating contact potential difference image, or from an integrated version of the image, then these non-uniformities can be classified based on features extracted from the differential image, the integrated image or from an integrated image scaled to vibrating Kelvin probe measurements. These features can consist of values describing the shape of the non-uniformity; such as area, perimeter, height and width; or the signal values associated with the non-uniformity; such as standard deviation, maximum, minimum, range, and average. In addition, features describing the position of the non-uniformity on the wafer or the relative positions of non-uniformities can be used to classify non-uniformities.
A fourth aspect of this invention is the classification of non-uniformities based on the sensitivity of the non-uniformity to light or surface deposited charge. Some types of non-uniformities, such as doping or implant non-uniformities, or charging in or on a dielectric film on or in a semiconductor substrate, are sensitive to surface illumination or charging. Two images can be acquired with different surface illumination conditions and the images subtracted. The resulting image shows changes in surface potential with illumination (see
A fifth aspect of this invention is the classification of non-uniformities based on the results of subsequent vibrating contact potential difference measurements. The non-vibrating contact potential difference sensor produces differential data that represents changes in surface potential or height across the wafer. Vibrating Kelvin probe measurements, however, provide a measure of the absolute contact potential difference between the sensor probe tip and the wafer surface (see
A sixth aspect of this invention is the classification of non-uniformities based on contact potential difference values obtained by scaling integrated non-vibrating contact potential difference image to two or more vibrating contact potential difference measurements (see
There are many alternate mechanical configurations and scanning operations that would accomplish the same result as the embodiment described above. For example, the non-vibrating contact potential difference sensor 101, height sensor 111, illumination source 109, charge source 110, and system for vibrating the sensor 104 could all be mounted at fixed locations, and the wafer 105 could be moved and rotated beneath these stationary elements. Instead of stepping from one radius to the next, the non-vibrating contact potential difference sensor 101 could be moved continuously along the wafer 105 radius while the wafer 105 is spinning to create a continuous stream of data that spirals across the whole surface of the wafer 105. Also, instead of the radial scanning operation described above, the non-vibrating contact potential difference sensor 101 could be moved linearly across the wafer 105 in a back-and-forth manner to scan the entire wafer surface 106. Also, multiple non-vibrating contact potential difference sensors and illumination sources could be used to acquire multiple measurements simultaneously to reduce the time required to measure a wafer.
The foregoing description of embodiments of the present invention have been presented for purposes of illustration and description. It is not intended to be exhaustive or to limit the present invention to the precise form disclosed, and modifications and variations are possible in light of the above teachings or may be acquired from practice of the present invention. The embodiments were chosen and described in order to explain the principles of the present invention and its practical application to enable one skilled in the art to utilize the present invention in various embodiments, and with various modifications, as are suited to the particular use contemplated