For the sake of convenience, the current description focuses on systems and techniques that may be realized in a particular embodiment of cantilever-based instruments, the atomic force microscope (AFM). Cantilever-based instruments include such instruments as AFMs, molecular force probe instruments (1D or 3D), high-resolution profilometers (including mechanical stylus profilometers), surface modification instruments, chemical or biological sensing probes, and micro-actuated devices. The systems and techniques described herein may be realized in such other cantilever-based instruments.
An AFM is a device used to produce images of surface topography (and/or other sample characteristics) based on information obtained from scanning (e.g., rastering) a sharp probe on the end of a cantilever relative to the surface of the sample. Topographical and/or other features of the surface are detected by detecting changes in deflection and/or oscillation characteristics of the cantilever (e.g., by detecting small changes in deflection, phase, frequency, etc., and using feedback to return the system to a reference state). By scanning the probe relative to the sample, a “map” of the sample topography or other sample characteristics may be obtained.
Changes in deflection or in oscillation of the cantilever are typically detected by an optical lever arrangement whereby a light beam is directed onto the cantilever in the same reference frame as the optical lever. The beam reflected from the cantilever illuminates a position sensitive detector (PSD). As the deflection or oscillation of the cantilever changes, the position of the reflected spot on the PSD changes, causing a change in the output from the PSD. Changes in the deflection or oscillation of the cantilever are typically made to trigger a change in the vertical position of the cantilever base relative to the sample (referred to herein as a change in the Z position, where Z is generally orthogonal to the XY plane defined by the sample), in order to maintain the deflection or oscillation at a constant pre-set value. It is this feedback that is typically used to generate an AFM image.
AFMs can be operated in a number of different sample characterization modes, including contact mode where the tip of the cantilever is in constant contact with the sample surface, and AC modes where the tip makes no contact or only intermittent contact with the surface.
Actuators are commonly used in AFMs, for example to raster the probe or to change the position of the cantilever base relative to the sample surface. The purpose of actuators is to provide relative movement between different parts of the AFM; for example, between the probe and the sample. For different purposes and different results, it may be useful to actuate the sample, the cantilever or the tip or some combination of both. Sensors are also commonly used in AFMs. They are used to detect movement, position, or other attributes of various components of the AFM, including movement created by actuators.
For the purposes of the specification, unless otherwise specified, the term “actuator” refers to a broad array of devices that convert input signals into physical motion, including piezo activated flexures, piezo tubes, piezo stacks, blocks, bimorphs, unimorphs, linear motors, electrostrictive actuators, electrostatic motors, capacitive motors, voice coil actuators and magnetostrictive actuators, and the term “position sensor” or “sensor” refers to a device that converts a physical parameter such as displacement, velocity or acceleration into one or more signals such as an electrical signal, including capacitive sensors, inductive sensors (including eddy current sensors), differential transformers (such as described in co-pending applications US20020175677A1 and US20040075428A1, Linear Variable Differential Transformers for High Precision Position Measurements, and US20040056653A1, Linear Variable Differential Transformer with Digital Electronics, which are hereby incorporated by reference in their entirety), variable reluctance, optical interferometry, optical deflection detectors (including those referred to above as a PSD and those described in co-pending applications US20030209060A1 and US20040079142A1, Apparatus and Method for Isolating and Measuring Movement in Metrology Apparatus, which are hereby incorporated by reference in their entirety), strain gages, piezo sensors, magnetostrictive and electrostrictive sensors.
In both the contact and AC sample-characterization modes, the interaction between the probe and the sample surface induces a discernable effect on a probe-based operational parameter, such as the cantilever deflection, the cantilever oscillation amplitude, the phase of the cantilever oscillation relative to the drive signal driving the oscillation or the frequency of the cantilever oscillation, all of which are detectable by a sensor. In this regard, the resultant sensor-generated signal is used as a feedback control signal for the Z actuator to maintain a designated probe-based operational parameter constant.
In contact mode, the designated parameter may be cantilever deflection. In AC modes, the designated parameter may be oscillation amplitude, phase or frequency. The feedback signal also provides a measurement of the sample characteristic of interest. For example, when the designated parameter in an AC mode is oscillation amplitude, the feedback signal may be used to maintain the amplitude of cantilever oscillation constant to measure changes in the height of the sample surface or other sample characteristics.
The periodic interactions between the tip and sample in AC modes induces cantilever flexural motion at higher frequencies. Measuring the motion allows interactions between the tip and sample to be explored. A variety of tip and sample mechanical properties including conservative and dissipative interactions may be explored. Stark, et al., have pioneered analyzing the flexural response of a cantilever at higher frequencies as nonlinear interactions between the tip and the sample. In their experiments, they explored the amplitude and phase at numerous higher oscillation frequencies and related these signals to the mechanical properties of the sample.
Unlike the plucked guitar strings of elementary physics classes, cantilevers normally do not have higher oscillation frequencies that fall on harmonics of the fundamental frequency. The first three modes of a simple diving board cantilever, for example, are at the fundamental resonant frequency (f0), 6.19f0 and 17.5 f0. An introductory text in cantilever mechanics such as Sarid has many more details. Through careful engineering of cantilever mass distributions, Sahin, et al., have developed a class of cantilevers whose higher modes do fall on higher harmonics of the fundamental resonant frequency. By doing this, they have observed that cantilevers driven at the fundamental exhibit enhanced contrast, based on their simulations on mechanical properties of the sample surface. This approach is has the disadvantage of requiring costly and difficult to manufacture special cantilevers.
The simple harmonic oscillator (SHO) model gives a convenient description at the limit of the steady state amplitude A of the eigenmode of a cantilever oscillating in an AC mode:
where F0 is the drive amplitude (typically at the base of the cantilever), m is the mass, ω is the drive frequency in units of rad/sec, ω0 is the resonant frequency and Q is the “quality” factor, a measure of the damping.
If, as is often the case, the cantilever is driven through excitations at its base, the SHO expression becomes
where F0/m has been replaced with Adriveω02, where Adrive is the drive amplitude.
The phase angle φ is described by an associated equation
When these equations are fulfilled, the amplitude and phase of the cantilever are completely determined by the user's choice of the drive frequency and three independent parameters: Adrive, ω0 and Q.
In some very early work, Martin, et al., drove the cantilever at two frequencies. The cantilever response at the lower, non-resonant frequency was used as a feedback signal to control the surface tracking and produced a topographic image of the surface. The response at the higher frequency was used to characterize what the authors interpreted as differences in the non-contact forces above the Si and photo-resist on a patterned sample.
Recently, Rodriguez and Garcia published a theoretical simulation of a non-contact, attractive mode technique where the cantilever was driven at its two lowest eigen frequencies. In their simulations, they observed that the phase of the second mode had a strong dependence on the Hamaker constant of the material being imaged, implying that this technique could be used to extract chemical information about the surfaces being imaged. Crittenden et al. have explored using higher harmonics for similar purposes.
There are a number of techniques where the instrument is operated in a hybrid mode where a contact mode feedback loop is maintained while some parameter is modulated. Examples include force modulation and piezo-response imaging.
Force modulation involves maintaining a contact mode feedback loop while also driving the cantilever at a frequency and then measuring its response. When the cantilever makes contact with the surface of the sample while being so driven, its resonant behavior changes significantly. The resonant frequency typically increases, depending on the details of the contact mechanics. In any event, one may learn more about the surface properties because the elastic response of the sample surface is sensitive to force modulation. In particular, dissipative interactions may be measured by measuring the phase of the cantilever response with respect to the drive.
A well-known shortcoming of force modulation and other contact mode techniques is that the while the contact forces may be controlled well, other factors affecting the measurement may render it ill-defined. In particular, the contact area of the tip with the sample, usually referred to as contact stiffness, may vary greatly depending on tip and sample properties. This in turn means that the change in resonance while maintaining a contact mode feedback loop, which may be called the contact resonance, is ill-defined. It varies depending on the contact stiffness. This problem has resulted in prior art techniques avoiding operation at or near resonance.
Cantilevers are continuous flexural members with a continuum of vibrational modes. The present invention describes different apparatus and methods for exciting the cantilever simultaneously at two or more different frequencies and the useful information revealed in the images and measurements resulting from such methods. Often, these frequencies will be at or near two or more of the cantilever vibrational eigenmodes
Past work with AC mode AFMs has been concerned with higher vibrational modes in the cantilever, with linear interactions between the tip and the sample. The present invention, however, is centered around non-linear interactions between the tip and sample that couple energy between two or more different cantilever vibrational modes, usually kept separate in the case of linear interactions. Observing the response of the cantilever at two or more different vibrational modes has some advantages in the case of even purely linear interactions however. For example, if the cantilever is interacting with a sample that has some frequency dependent property, this may show itself as a difference in the mechanical response of the cantilever at the different vibrational modes.
The motion imparted to the cantilever chip 1030 by actuator 1040 is controlled by excitation electronics that include at least two frequency synthesizers 1080 and 1090. There could be additional synthesizers if more than two cantilever eigenmodes are to be employed. The signals from these frequency synthesizers could be summed together by an analog circuit element 1100 or, preferably, a digital circuit element that performs the same function. The two frequency synthesizers 1080 and 1090 provide reference signals to lockin amplifiers 1110 and 1120, respectively. In the case where more than two eigenmodes are to be employed, the number of lockin amplifiers will also be increased. As with other electronic components in this apparatus, the lockin amplifiers 1110 and 1120 can be made with analog circuitry or with digital circuitry or a hybrid of both. For a digital lockin amplifier, one interesting and attractive feature is that the lockin analysis can be performed on the same data stream for both eigenmodes. This implies that the same position sensitive detector and analog to digital converter can be used to extract information at the two distinct eigenmodes.
The lockin amplifiers could also be replaced with rms measurement circuitry where the rms amplitude of the cantilever oscillation is used as a feedback signal.
There are a number of variations in the
In one method of using the
Because higher eigenmodes have a significantly higher dynamic stiffness, the energy of these modes can be much larger that that of lower eigenmodes.
The method may be used to operate the apparatus with one flexural mode experiencing a net attractive force and the other a net repulsive force, as well as operating with each mode experiencing the same net sign of force, attractive or repulsive. Using this method, with the cantilever experiencing attractive and repulsive interactions in different eigenmodes, may provide additional information about sample properties.
One preferred technique for using the aforesaid method is as follows. First, excite the probe tip at or near a resonant frequency of the cantilever keeping the tip sufficiently far from the sample surface that it oscillates at the free amplitude A10 unaffected by the proximity of the cantilever to the sample surface and without making contact with the sample surface. At this stage, the cantilever is not touching the surface; it turns around before it interacts with significant repulsive forces.
Second, reduce the relative distance in the Z direction between the base of the cantilever and the sample surface so that the amplitude of the probe tip A1 is affected by the proximity of the sample surface without the probe tip making contact with the sample surface. The phase p1 will be greater than p10, the free first eigenmode phase. This amplitude is maintained at an essentially constant value during scanning without the probe tip making contact with the sample surface by setting up a feedback loop that controls the distance between the base of the cantilever and the sample surface.
Third, keeping the first eigenmode drive and surface controlling feedback loop with the same values, excite a second eigenmode of the cantilever at an amplitude A2. Increase A2 until the second eigenmode phase p2 shows that the cantilever eigenmode is interacting with predominantly repulsive forces; that is, that p2 is less than p20, the free second eigenmode phase. This second amplitude A2 is not included in the feedback loop and is allowed to freely roam over a large range of values. In fact, it is typically better if variations in A2 can be as large as possible, ranging from 0 to A20, the free second eigenmode amplitude.
Fourth, the feedback amplitude and phase, A1 and p1, respectively, as well as the carry along second eigenmode amplitude and phase, A2 and p2, respectively, should be measured and displayed.
Alternatively, the drive amplitude and/or phase of the second frequency can be continually adjusted to maintain the second amplitude and/or phase at an essentially constant value. In this case, it is useful to display and record the drive amplitude and/or frequency required to maintain the second amplitude and/or phase at an essentially constant value.
A second preferred technique for using the aforesaid method follows the first two steps of first preferred technique just described and then continues with the following two steps:
Third, keeping the first eigenmode drive and surface controlling feedback loop with the same values, excite a second eigenmode (or harmonic) of the cantilever at an amplitude A2. Increase A2 until the second eigenmode phase p2 shows that the cantilever eigenmode is interacting with predominantly repulsive forces; that is, that p2 is less than p20, the free second eigenmode phase. At this point, the second eigenmode amplitude A2 should be adjusted so that the first eigenmode phase p1 becomes predominantly less than p10, the free first eigenmode phase. In this case, the adjustment of the second eigenmode amplitude A2 has induced the first eigenmode of the cantilever to interact with the surface in a repulsive manner. As with the first preferred technique, the second eigenmode amplitude A2 is not used in the tip-surface distance feedback loop and should be allowed range widely over many values.
Fourth, the feedback amplitude and phase, A1 and p1, respectively, as well as the carry along second eigenmode amplitude and phase, A2 and p2, respectively, should be measured and displayed.
Either of the preferred techniques just described could be performed in a second method of using the
Relative changes in various parameters such as the amplitude and phase or in-phase and quadrature components of the cantilever at these different frequencies could also be used to extract information about the sample properties.
A third preferred technique for using the first method of using the
1. Both eigenmodes are in the attractive mode, that is to say that the phase shift of both modes is positive, implying both eigenmode frequencies have been shifted negatively by the tip-sample interactions. Generally, this requires a small amplitude for the second eigenmode.
2. The fundamental eigenmode remains attractive while the second eigenmode is in a state where the tip-sample interactions cause it to be in both the attractive and the repulsive modes as it is positioned relative to the surface.
3. The fundamental eigenmode is in an attractive mode and the second eiegenmode is in a repulsive mode.
4. In the absence of any second mode excitation, the first eigenmode is interacting with the surface in the attractive mode. After the second eigenmode is excited, the first eigenmode is in a repulsive mode. This change is induced by the addition of the second eigenmode energy. The second eigenmode is in a state where the tip-sample interactions cause it to be attractive and/or repulsive.
5. The first eigenmode is in a repulsive mode and the second mode is in a repulsive mode.
The transition from attractive to repulsive mode in the first eigenmode, as induced by the second eigenmode excitation, is illustrated in
More complicated feedback schemes can also be envisioned. For example, one of the eigenmode signals can be used for topographical feedback while the other signals could be used in other feedback loops. An example would be that A1 is used to control the tip-sample separation while a separate feedback loop was used to keep A2 at an essentially constant value rather than allowing it to range freely over many values. A similar feedback loop could be used to keep the phase of the second frequency drive p2 at a predetermined value with or without the feedback loop on A2 being implemented.
As another example of yet another type of feedback that could be used, Q-control can also be used in connection with any of the techniques for using the first method of using the
In addition to driving the cantilever at or near more than one eigenmode, it is possible to also excite the cantilever at or near one or more harmonics and/or one or more eigenmodes. It has been known for some time that nonlinear interactions between the tip and the sample can transfer energy into cantilever harmonics. In some cases this energy transfer can be large but it is usually quite small, on the order of a percent of less of the energy in the eigenmode. Because of this, the amplitude of motion at a harmonic, even in the presence of significant nonlinear coupling is usually quite small. Using the methods described here, it is possible to enhance the contrast of these harmonics by directly driving the cantilever at the frequency of the harmonic. To further enhance the contrast of this imaging technique it is useful to adjust the phase of the higher frequency drive relative to that of the lower. This method improves the contrast of both conventional cantilevers and the specially engineered “harmonic” cantilevers described by Sahin et al and other researchers.
On many samples, the results of imaging with the present invention are similar to, and in some cases superior to, the results of conventional phase imaging. However, while phase imaging often requires a judicious choice of setpoint and drive amplitude to maximize the phase contrast, the method of the present invention exhibits high contrast over a much wider range of imaging parameters. Moreover, the method also works in fluid and vacuum, as well as air and the higher flexural modes show unexpected and intriguing contrast in those environments, even on samples such as DNA and cells that have been imaged numerous times before using more conventional techniques.
Although there is a wide range of operating parameters that yield interesting and useful data, there are situations where more careful tuning of the operational parameters will yield enhanced results. Some of these are discussed below. Of particular interest can be regions in set point and drive amplitude space where there is a transition from attractive to repulsive (or vice versa) interactions in one or more of the cantilever eigenmodes or harmonics.
The superior results of imaging with the present invention may be seen from an inspection of the images. An example is shown in
When an AFM is operated in conventional amplitude modulated (AM) AC mode with phase detection, the cantilever amplitude is maintained constant and used as a feedback signal. Accordingly, the values of the signal used in the loop are constrained not only by energy balance but also by the feedback loop itself. Furthermore, if the amplitude of the cantilever is constrained, the phase will also be constrained, subject to conditions discussed below. In conventional AC mode it is not unusual for the amplitude to vary by a very small amount, depending on the gains of the loop. This means that, even if there are mechanical properties of the sample that might lead to increased dissipation or a frequency shift of the cantilever, the z-feedback loop in part corrects for these changes and thus in this sense, avoids presenting them to the user.
If the technique for using the present invention involves a mode that is excited but not used in the feedback loop, there will be no explicit constraints on the behavior of this mode. Instead it will range freely over many values of the amplitude and phase, constrained only by energy balance. That is to say, the energy that is used to excite the cantilever motion must be balanced by the energy lost to the tip-sample interactions and the intrinsic dissipation of the cantilever. This may explain the enhanced contrast we observe in images generated with the techniques of the present invention.
The present invention may also be used in apparatus that induce motion in the cantilever other than through a piezoelectric actuator. These could include direct electric driving of the cantilever (“active cantilevers”), magnetic actuation schemes, ultrasonic excitations, scanning Kelvin probe and electrostatic actuation schemes.
Direct electric driving of the cantilever (“active cantilevers”) using the present invention has several advantages over conventional piezo force microscopy (PFM) where the cantilever is generally scanned over the sample in contact mode and the cantilever voltage is modulated in a manner to excite motion in the sample which in turn causes the cantilever to oscillate.
In one method of using the
The
Another example of a preferred embodiment of an apparatus and method for using the present invention is from the field of ultrasonic force microscopy. In this embodiment, one or more eigenmodes are used for the z-feedback loop and one or more additional eigenmodes can be used to measure the high frequency properties of the sample. The high frequency carrier is amplitude modulated and either used to drive the sample directly or to drive it using the cantilever as a waveguide. The cantilever deflection provides a rectified measure of the sample response at the carrier frequency.
Another group of embodiments for the present invention has similarities to the conventional force modulation technique described in the Background to the Invention and conventional PFM where the cantilever is scanned over the sample in contact mode and a varying voltage is applied to the cantilever. In general this group may be described as contact resonance embodiments. However, these embodiments, like the other embodiments already described, make use of multiple excitation signals.
In one method of using the
DFRT PFM is very stable over time in contrast to single frequency techniques. This allows time dependent processes to be studied as is demonstrated by the sequence of images, 19010, 19050, 19060, 19070 and 19080 taken over the span of about 1.5 hours. In these images, the written domains are clearly shrinking over time.
In AC mode atomic force microscopy, relatively tiny tip-sample interactions can cause the motion of a cantilever probe oscillating at resonance to change, and with it the resonant frequency, phase, amplitude and deflection of the probe. Those changes of course are the basis of the inferences that make AC mode so useful. With contact resonance techniques the contact between the tip and the sample also can cause the resonant frequency, phase and amplitude of the cantilever probe to change dramatically.
The resonant frequency of the cantilever probe using contact resonance techniques depends on the properties of the contact, particularly the contact stiffness. Contact stiffness in turn is a function of the local mechanical properties of the tip and sample and the contact area. In general, all other mechanical properties being equal, increasing the contact stiffness by increasing the contact area, will increase the resonant frequency of the oscillating cantilever probe. This interdependence of the resonant properties of the oscillating cantilever probe and the contact area represents a significant shortcoming of contact resonance techniques. It results in “topographical crosstalk” that leads to significant interpretational issues. For example, it is difficult to know whether or not a phase or amplitude change of the probe is due to some sample property of interest or simply to a change in the contact area.
The apparatus used in contact resonance techniques can also cause the resonant frequency, phase and amplitude of the cantilever probe to change unpredictably. Examples are discussed by Rabe et al., Rev. Sci. Instr. 67, 3281 (1996) and others since then. One of the most difficult issues is that the means for holding the sample and the cantilever probe involve mechanical devices with complicated, frequency dependent responses. Since these devices have their own resonances and damping, which are only rarely associated with the sample and tip interaction, they may cause artifacts in the data produced by the apparatus. For example, phase and amplitude shifts caused by the spurious instrumental resonances may freely mix with the resonance and amplitude shifts that originate with tip-sample interactions.
It is advantageous to track more than two resonant frequencies as the probe scans over the surface when using contact resonance techniques. Increasing the number of frequencies tracked provides more information and makes it possible to over-constrain the determination of various physical properties. As is well known in the art, this is advantageous since multiple measurements will allow better determination of parameter values and provide an estimation of errors.
Since the phase of the cantilever response is not a well behaved quantity for feedback purposes in PFM, we have developed other methods for measuring and/or tracking shifts in the resonant frequency of the probe. One method is based on making amplitude measurements at more than one frequency, both of which are at or near a resonant frequency.
There are many methods to track the resonant frequency with information on the response at more than one frequency. One method with DFRT PFM is to define an error signal that is the difference between the amplitude at f1 and the amplitude at f2, that is A1 minus A2. A simpler example would be to run the feedback loop such that A1 minus A2=0, although other values could equally well be chosen. Alternatively both f1 and f2 could be adjusted so that the error signal, the difference in the amplitudes, is maintained. The average of these frequencies (or even simply one of them) provides the user with a measure of the contact resonant frequency and therefore the local contact stiffness. It is also possible to measure the damping and drive with the two values of amplitude. When the resonant frequency has been tracked properly, the peak amplitude is directly related to the amplitude on either side of resonance. One convenient way to monitor this is to simply look at the sum of the two amplitudes. This provides a better signal to noise measurement than does only one of the amplitude measurements. Other, more complicated feedback loops could also be used to track the resonant frequency. Examples include more complex functions of the measured amplitudes, phases (or equivalently, the in-phase and quadrature components), cantilever deflection or lateral and/or torsional motion.
The values of the two amplitudes also allow conclusions to be drawn about damping and drive amplitudes. For example, in the case of constant damping, an increase in the sum of the two amplitudes indicates an increase in the drive amplitude while the difference indicates a shift in the resonant frequency.
Finally, it is possible to modulate the drive amplitude and/or frequencies and/or phases of one or more of the frequencies. The response is used to decode the resonant frequency and, optionally, adjust it to follow changes induced by the tip-sample interactions.
Another multiple frequency technique is depicted in
As noted, the user often does not have independent knowledge about the drive or damping in contact resonance. Furthermore, models may be of limited help because they too require information not readily available. In the simple harmonic oscillator model for example, the drive amplitude Adrive, drive phase φdrive, resonant frequency ω0 and quality factor Q (representative of the damping) will all vary as a function of the lateral tip position over the sample and may also vary in time depending on cantilever mounting schemes or other instrumental factors. In conventional PFM, only two time averaged quantities are measured, the amplitude and the phase of the cantilever (or equivalently, the in-phase and quadrature components). However, in dual or multiple frequency excitations, more measurements may be made, and this will allow additional parameters to be extracted. In the context of the SHO model, by measuring the response at two frequencies at or near a particular resonance, it is possible to extract four model parameters. When the two frequencies are on either side of resonance, as in the case of DFRT PFM for example, the difference in the amplitudes provides a measure of the resonant frequency, the sum of the amplitudes provides a measure of the drive amplitude and damping of the tip-sample interaction (or quality factor), the difference in the phase values provides a measure of the quality factor and the sum of the phases provides a measure of the tip-sample drive phase.
Simply put, with measurements at two different frequencies, we measure four time averaged quantities, A1, A2, φ1, φ2 that allow us to solve for the four unknown parameters Adrive, φdrive, f0 and Q.
This difficulty is surmounted by measuring the phase. Curves 18020, 18040 and 18060 are the phase curves corresponding to the amplitude curves 18010, 18030 and 18050 respectively. As with the amplitude measurements, the phase is measured at discrete frequency values, f1 and f2. The phase curve 18020 remains unchanged 18060 when the drive amplitude Adrive increases from 0.06 nm to 0.09 nm. Note that the phase measurements 18022 and 18062 at f1 for the curves reflecting an increase in drive amplitude but with the same quality factor are the same, as are the phase measurements 18024 and 18064 at f2. However, when the quality factor Q increases, the f1 phase 18042 decreases and the f2 phase 18044 increases. These changes clearly separate drive amplitude changes from Q value changes.
In the case where the phase baseline does not change, it is possible to obtain the Q value from one of the phase measurements. However, as in the case of PFM and thermal modulated microscopy, the phase baseline may well change. In this case, it is advantageous to look at the difference in the two phase values. When the Q increases, this difference 18080 will also increase. When the Q is unchanged, this difference 18070 is also unchanged.
If we increase the number of frequencies beyond two, other parameters can be evaluated such as the linearity of the response or the validity of the simple harmonic oscillator model
Once the amplitude, phase, quadrature or in-phase component is measured at more than one frequency, there are numerous deductions that can be made about the mechanical response of the cantilever to various forces. These deductions can be made based around a model, such as the simple harmonic oscillator model or extended, continuous models of the cantilever or other sensor. The deductions can also be made using a purely phenomenological approach. One simple example in measuring passive mechanical properties is that an overall change in the integrated amplitude of the cantilever response, the response of the relevant sensor, implies a change in the damping of the sensor. In contrast, a shift in the “center” of the amplitude in amplitude versus frequency measurements implies that the conservative interactions between the sensor and the sample have changed.
This idea can be extended to more and more frequencies for a better estimate of the resonant behavior. It will be apparent to those skilled in the art that this represents one manner of providing a spectrum of the sensor response over a certain frequency range. The spectral analysis can be either scalar or vector. This analysis has the advantage that the speed of these measurements is quite high with respect to other frequency dependent excitations.
In measuring the frequency response of a sensor, it is not required to excite the sensor with a constant, continuous signal. Other alternatives such as so-called band excitation, pulsed excitations and others could be used. The only requirement is that the appropriate reference signal be supplied to the detection means.
Scanning ion conductance microscopy, scanning electrochemical microscopy, scanning tunneling microscopy, scanning spreading resistance microscopy and current sensitive atomic force microscopy are all examples of localized transport measurements that make use of alternating signals, again sometimes with an applied dc bias. Electrical force microscopy, Kelvin probe microscopy and scanning capacitance microscopy are other examples of measurement modes that make use of alternating signals, sometimes with an applied dc bias. These and other techniques known in the art can benefit greatly from excitation at more than one frequency. Furthermore, it can also be beneficial if excitation of a mechanical parameter at one or more frequencies is combined with electrical excitation at the same or other frequencies. The responses due to these various excitations can also be used in feedback loops, as is the case with Kelvin force microscopy where there is typically a feedback loop operating between a mechanical parameter of the cantilever dynamics and the tip-sample potential.
Perhaps the most popular of the AC modes is amplitude-modulated (AM) Atomic Force Microscopy (AFM), sometimes called (by Bruker Instruments) tapping mode or intermittent contact mode. Under the name “tapping mode” this AC mode was first coined by Finlan, independently discovered by Gleyzes, and later commercialized by Digital Instruments.
AM AFM imaging combined with imaging of the phase, that is comparing the signal from the cantilever oscillation to the signal from the actuator driving the cantilever and using the difference to generate an image, is a proven, reliable and gentle imaging/measurement method with widespread applications. The first phase images (of a wood pulp sample) were presented at a meeting of Microscopy and Microanalysis. Since then, phase imaging has become a mainstay in a number of AFM application areas, most notably in polymers where the phase channel is often capable of resolving fine structural details.
The phase response has been interpreted in terms of the mechanical and chemical properties of the sample surface. Progress has been made in quantifying energy dissipation and storage between the tip and sample which can be linked to specific material properties. Even with these advances, obtaining quantitative material or chemical properties remains problematic. Furthermore, with the exception of relatively soft metals such as In-Tn solder, phase contrast imaging has been generally limited to softer polymeric materials, rubbers, fibrous natural materials. On the face of it this is somewhat puzzling since the elastic and loss moduli of harder materials can vary over many orders of magnitude.
The present invention adapts techniques used recently in research on polymers, referred to there as loss tangent imaging, to overcome some of these difficulties. Loss tangent imaging recasts our understanding of phase imaging by linking energy dissipation and energy storage into one term that includes both the dissipated and the stored energy of the interaction between the tip and the sample. The linkage becomes a fundamental material property—if for example the dissipation increases because of an increase in the indentation depth, the stored elastic energy will also increase. In the case of linear viscoelastic materials, the ratio between the dissipated energy and elastically stored energy is the loss tangent. This is similar to other dimensionless approaches to characterizing loss and storage in materials such as the coefficient of restitution. The loss tangent approach to materials has very early roots, dating back at least to the work of Zener in 1941. One should note however that many materials are not linear viscoelastic materials, especially in the presence of large strains (>1%). The degree of deviation from the behavior of linear viscoelastic materials exhibited by other materials is in itself useful and interesting to measure.
In addition to loss tangent imaging, the present invention includes the quantitative and high sensitivity of simultaneous operation in a frequency modulated (FM) mode. For this purpose the AFM is set up for bimodal imaging with two feedback loops, the first using the first resonance of the cantilever and the second another higher resonance. The first loop is an AM mode feedback loop that controls the tip-sample separation by keeping the amplitude of the cantilever constant (and produces a topographic image from the feedback signals) and at the same time compares the signal from the cantilever oscillation to the signal from the actuator driving the cantilever to measure changes in phase as the tip-sample separation is maintained constant. The second feedback loop is a FM mode feedback loop that controls the tip-sample separation by varying the drive frequency of the cantilever. The frequency is varied in FM mode through a phase-locked loop (PLL) that keeps the phase—a comparison of the signal from the cantilever oscillation to the signal from the actuator driving the cantilever at the second resonance—at 90 degrees by adjusting the frequency. It is also possible to implement another feedback loop to keep the amplitude of the cantilever constant through the use of automatic gain control (AGC). If the AGC is implemented, output amplitude is constant. Otherwise, if the amplitude is allowed to vary, it is termed constant excitation mode.
Much of the initial work with FM mode was in air and it has a long tradition of being applied to vacuum AFM studies (including UHV), routinely attaining atomic resolution and even atomic scale chemical identification. Recently there has been increasing interest in the application of this technique to various samples in liquid environments, particularly biological samples. Furthermore, FM AFM has demonstrated true atomic resolution imaging in liquid where the low Q results in a reduction in force sensitivity. One significant challenge of FM AFM has been with stabilizing feedback loops.
Briefly, when AM mode imaging with phase is combined with FM mode imaging using bimodal imaging techniques, the topographic feedback operates in AM mode while the second resonant mode drive frequency is adjusted to keep the phase at 90 degrees. With this approach, frequency feedback on the second resonant mode and topographic feedback on the first are decoupled, allowing much more stable, robust operation. The FM image returns a quantitative value of the frequency shift that in turn depends on the sample stiffness and can be applied to a variety of physical models.
Bimodal imaging involves using more than one resonant vibrational mode of the cantilever simultaneously. A number of multifrequency AFM schemes have been proposed to improve high resolution imaging, contrast and quantitative mapping of material properties, some of which have already been discussed above.
With bimodal imaging the resonant modes can be treated as independent channels, with each channel having separate observables, generally the amplitude and phase. The cantilever is driven at two flexural resonances, typically the first two, as has been described above. The response of the cantilever at the two resonances is measured and used in different ways as shown in
The motion imparted to the cantilever chip 1030 by actuator 1040 is controlled by excitation electronics that include at least two frequency synthesizers 1080 and 1090. The signals from these frequency synthesizers could be summed together by an analog circuit element 1100 or, preferably, a digital circuit element that performs the same function. The two frequency synthesizers 1080 and 1090 provide reference signals to lockin amplifiers 1110 and 1120, respectively. As with other electronic components in this apparatus, the lockin amplifiers 1110 and 1120 can be made with analog circuitry or with digital circuitry or a hybrid of both. For a digital lockin amplifier, one interesting and attractive feature is that the lockin analysis can be performed on the same data stream for both flexural resonances. This implies that the same position sensitive detector and analog to digital converter can be used to extract information at the two distinct resonances.
Resonance 1: As shown in the upper shaded area of
Resonance 2: As shown in the lower shaded area of
The foregoing bimodal imaging approach to quantitative measurements has the great advantage of stability when used with Loss Tangent and AM/FM imaging techniques. With topographic feedback confined to the first resonant mode and FM control to the second resonant mode, even if the PLL or AGC control loops become unstable and oscillate, there is little or no effect on the ability of the first mode to stably track the surface topography. As is well known in the art, AM mode AFM imaging, where the topographic feedback is controlled by the oscillations of the first mode is extremely robust and stable. Thus, the overall imaging performance, where topographic and other information are gathered simultaneously, is very stable and robust.
In order to highlight some important limitations it is useful to take a mathematical approach to Loss Tangent imaging. As already noted in the discussion of AM AFM operation, the amplitude of the first resonant mode is used to maintain the tip-sample distance. The control voltage, typically applied to a z-actuator, results in a topographic image of the sample surface. At the same time, the phase of the first resonant mode will vary in response to the tip-sample interaction. This phase reflects both dissipative and conservative interactions. A tip which indents a surface will both dissipate viscous energy and store elastic energy—the two are inextricably linked. The loss tangent can be employed to measure the tip-sample interaction. As mentioned, the loss tangent is a dimensionless parameter which measures the ratio of energy dissipated to energy stored in a cycle of a periodic deformation. The following relation involving the measured cantilever amplitude V and phase φ defines the loss tangent for tip-sample interaction:
In this expression, Fts is the tip-sample interaction force, z is the tip motion, ż is the tip velocity, ω is the angular frequency at which the cantilever is driven and represents a time-average. The parameter Vfree is the “free” resonant amplitude of the first mode, measured at a reference position. Note that because the amplitudes appear as ratios in Equation (1), they can be either calibrated or uncalibrated in terms of optical detector sensitivity. In the final expression in (FullTand) we have defined the ratios Ω≡ω/ωfree and a α≡A/Afree=V/Vfree. If we operate on resonance (Ω=1), the expression can be simplified to:
Equation FullTand differs by a factor of −1 from an earlier version, because it is assumed here that the virial Fts·z is positive for repulsive mode operation, which means tan δ>0 in repulsive mode.
There are some important implications of these equations:
1. Attractive interactions between the tip and the sample will in general make the elastic denominator Fts·z of equations FullTand and SimpleTand smaller. This will increase the cantilever loss tangent and therefore over-estimate the sample loss tangent.
2. Tip-sample damping with origins other than the sample loss modulus, originating from interactions between, for example, a water layer on either the tip or the sample will increase the denominator in equations FullTand and SimpleTand.
These implications point out an important limitation of loss tangent imaging. Equations (FullTand) and (SimpleTand) really represent the loss tangent of the cantilever, but not necessarily the loss tangent originating from the linear viscoelastic behavior of the sample mechanics: G″ and G′.
Loss tangent analysis has been under-utilized. In the past twenty plus years of tapping mode imaging, there are many examples of phase imaging of polymeric materials and very few of metals and ceramics with a loss tangent less than 0.01, that is, tan δ{tilde under (<)}10−2. There appears to be an impression that less elastic materials are more lossy. However, there are many examples where a stiffer material might also exhibit higher dissipation. This underscores the danger in simply interpreting phase contrast only in terms of sample elasticity.
Furthermore experimentalists bear the burden of setting up the AFM and its control algorithms such that the loss tangent of interest is being measured. As mentioned above, a number of conservative and dissipative interactions contribute to loss tangent estimation in addition to the linear viscoelastic interactions between the tip and the sample. In fact, depending on the experimental parameters and settings, the sample loss and storage moduli may contribute only a small portion of the signal in the loss tangent estimation. For example, when imaging the mechanical loss tangent of a polymer surface it is important to operate in repulsive mode, so that the cantilever interacts with the short-range repulsive forces controlled by the sample's elastic and loss moduli properties. In this section we consider some of these contributions, including experimental factors such as air damping and surface hydration layers and material effects such as viscoelastic nonlinearity.
Proper choice of the zero-dissipation point is critical for proper calibration of the tip-sample dissipation. In particular, squeeze film damping, C. P. Green and J. E. Sader, Frequency response of cantilever beams immersed in viscous fluids near a solid surface with applications to the atomic force microscope, J. Appl. Phys. 98, 114913 (2005); M. Bao and H. Yang, Squeeze film air damping in MEMS, Sens. Actuators, A 136, 3 (2007), can have a strong effect on the measured dissipation. Squeeze film damping causes the cantilever damping to increase as the body of the cantilever moves closer to the sample surface. For rough or uneven surfaces, this can mean that the cantilever body height changes with respect to the average sample position enough to cause crosstalk artifacts in the measured dissipation and therefore the measured loss tangent.
An example of squeeze film damping effects is shown in
The loss tangent image 2102 in
To correct for squeeze film damping effects in loss tangent measurements, we use the two-pass imaging technique depicted in
In order to provide a concrete demonstration of the result of two-pass imaging technique, we applied the technique to the Si/SU-8 sample described above. Image 2103 of
Another improvement in loss tangent imaging is to include energy being transferred to higher harmonics of the cantilever. This can be a significant effect at low Q values. Energy losses to higher harmonics of the cantilever are more significant at lower Q than at higher Q. J. Tamayo, et al., High-Q dynamic force microscopy in liquid and its application to living cells, Biophysical J., 81, 526-37 (2001), has accounted for this energy dissipation by including the harmonic response of the cantilever. By extending this analysis to storage, we derived an extension of the SimpleTand expression of the loss tangent that now includes harmonic correction terms:
In equation HarmTand, n is the order of the harmonic (ranging from the fundamental at n=1 up to the limit N) and An the amplitude at the nth harmonic. In the case of the dissipation term (the numerator), the harmonics behave as a “channel” for increased damping. Specifically, if energy goes into the harmonics at the fundamental mode, damping will appear to increase. In the case of the storage term (the denominator), energy going into the harmonics looks like a reduction in the kinetic energy of the cantilever. This also has the effect of reducing the apparent storage power in equations FullTand and SimpleTand. The two effects act in concert to increase the measured loss tangent.
In addition to measuring many of the harmonics of the loss tangent, the error associated with energy losses can be estimated and improved upon by simply measuring the response of the cantilever at a harmonic, for example the 6th or 4th harmonic, that is close to the next highest resonant mode.
Here we discuss two aspects of the behavior of materials that affect loss tangent estimates. The first concerns the viscoelastic response of a material. Implicit in our definition and use of the loss tangent expression is the assumption that a sample measured with an AFM indenting tip is a linear viscoelastic material. In this limit, the strains would remain small and follow a linear stress-strain relationship, so that an increase in stress would increase strain by the same factor. However, the assumption of linear viscoelasticity may not always hold. For instance, the experimental settings may apply sufficiently large stresses to cause a nonlinear response. In such cases, loss tangent measurements will not accurately represent the tan δ of the material. One test for the linearity of the response, or improper experimental parameters in general, is to try to measure the loss tangent as a function of indentation depth. In the limit that the interaction is governed by linear viscoelastic theory, there should not be a depth dependence in the estimated mechanical parameters such as loss tangent or modulus.
The results of
Finally, the graph 2950 inserted at the upper right of
The other aspect of the behavior of materials which affects loss tangent estimates that we will discuss concerns the potential for plastic deformation of the tip of the cantilever or the sample. At the extreme limit of nonlinear viscoelasticity, plastic deformation of the sample represents irreversible work that will appear in the numerator of the loss tangent. If the tip does plastic work on the sample, or vice versa in the case of hard samples, this will be indistinguishable from sample dissipation (i.e. G″). Thus, plasticity should lead to an overestimation of the loss tangent. The complex theory of indentation-induced plasticity in materials is strongly dependent on indenter shape and is beyond the scope of this work. K. L. Johnson, Contact Mechanics (Cambridge University Press, Cambridge, UK, 1985); C. M. Mate, Tribology on the Small Scale (Oxford University Press, Oxford, UK, 2008) However, we can estimate the yield stress Y from its relation to the force Fplastic needed for plastic deformation:
where R is the radius of curvature of the hemispherical indenter tip and Ec is the elastic modulus.
We can use the equation Fplastic to explore the relationship between Young's modulus and strength for a range of common materials. Here, the term “strength” corresponds to yield strength for metals and polymers, compressive crushing strength for ceramics, tear strength for elastomers and tensile strength for composites and woods. With R=10 nm and Fplastic=1 pN, 1 nN and 1 μN in Fplastic, we find that a significant fraction of materials is expected to plastically yield for loading forces between 1 and 10 nN, a range typical in AM mode AFM experiments. This illustrates the importance of using the appropriate operating forces when performing experiments.
Furthermore, plastic deformation can lead to the formation of surface debris, which may also result in contamination of the AFM tip. In this case, dissipation at the debris-sample and debris-tip interfaces may provide additional unwanted contributions to the loss tangent measurement. It is therefore important to understand and minimize contaminants on the surface.
We now consider another method of estimating loss tangent which we refer to as the differential loss tangent method.
The impedance of a freely vibrating cantilever −1(ω) with effective stiffness kc, mass mc, and damping bc which is driven at some angular frequency ω is −1(ω)=kc−mcω2+iωbc (where i=√{square root over (−1)}) with a corresponding resonant frequency ωc=√{square root over (kc/mc)} and a quality factor Qc=kc/ωcbc. The impedance describes the complex-valued driving force Fd necessary to excite the cantilever with some oscillation amplitude A. The impedance has units of N/m. The magnitude spectrum of the cantilever |(ω)| can be expressed as
where θ(ω) is the phase spectrum given by
It is also convenient to express the magnitude spectrum as:
The impedance −1(ω) is measured experimentally by exciting the cantilever with a driving force Fd through a variety of means known to those skilled in the art at a range of frequencies and fitting the observed amplitude A(ω) and phase φ(ω) to the equation
This fit (or only fitting A(ω)) allows the extraction of the cantilever parameters kc, mc, and bc. Note that −1(ω)=|(ω)|−1· is a theoretical true impedance profile which is inferred by an experimental measurement
In the presence of an actual tip-sample impedance interaction profile, −1(ω,z), defined as
−1(ω,z)=ki(z)+iωbi(z),
where z is a generalized position coordinate, this profile can be assumed to be the true impedance interaction profile that has not yet been subject to convolution due to cantilever amplitude. The impedance of this interacting cantilever is
i−1(ω,zc)=−1(ω)+−1(ω,z)=kc+ki(zc)−mcω2+iω[bc+bi(zc)],
where zc is the instantaneous position of the cantilever tip. Panel 3610 of
The impedance interaction can be extracted from a measurement by taking the difference between an interacting cantilever i−1, and the same cantilever at some reference position r−1 with no interaction
−1(ω,z)=i−1(ω,zc)−r−1(ω).
Experimentally, this is performed at a single drive frequency ωd at some distance zc from the sample
where the reference amplitude Ar and reference phase φr are measured with no tip-sample interaction at some distance z>>zc, and the interaction amplitude Ai and interaction phase φi are measured at a distance zc. This complex-valued equation can be split into its real and imaginary components. Any change in the real components relates to interaction stiffness
Changes in the imaginary components relate to interaction damping
The conserved energy of an interacting cantilever averaged over one cycle is
Econs=½kiA2+½kcA2,
while the dissipated energy averaged over one cycle is
Ediss=½ωbiA2+½ωbcA2.
The loss tangent isolates the energy conserved and dissipated by the interaction alone, resulting in
Assuming some arbitrary, but fixed, drive frequency ω=ωd and some driving force Fd
which simplifies to
Panel 3620 of
For convenience we have summarized the steps required to calibrate an AFM for operation in AM mode and measuring loss tangent, followed by the additional steps required for measuring differential loss tangent. We assume that the AFM in question is equipped with course-positioning and fine-positioning systems for maneuvering the cantilever and the sample.
Basic AFM Calibration Protocol
Data Acquisition Protocol
Data Processing Protocol for Sample Approach Curves
Data Processing Protocol for 2D Images
Bringing the discussion of loss tangent to a close we now consider how error and noise affect estimates of loss tangent.
Thermal and other random errors set a minimum detectable threshold for the loss tangent, typically in the range of tan δ≈10−2. This random noise is typically dominated by Brownian motion of the cantilever for the Asylum Research Cypher AFM in AM mode. Other random noise such as shot noise might become significant and if it were it would have to be included as well.
Systematic errors are typically associated with choosing the appropriate point for zero dissipation. It is convenient to divide into two tasks. First, the task of correctly tuning the cantilever at the reference position, that is, defining the resonant frequency, the quality factor, the free amplitude and the phase offset to correct for ubiquitous instrumental phase shifts. In particular, the most accurate estimates of the loss
tangent require higher precision in these tune parameters than commonly practiced in the art. Second, the task of accounting for non-linear viscoelastic contact mechanical forces between the tip and the sample. In particular, we describe improvements in the estimation of the loss tangent that comprise (i) a novel method for measuring the cantilever free amplitude and resonant frequency at every pixel with use of an interleaved scanning technique and (ii) methods of accounting for the presence of forces other than linear viscoelastic interactions between the tip and the sample.
To understand how noise estimates affect the loss tangent, it is useful to map amplitude and phase onto an equation for the loss tangent.
Above the no-loss boundary 3015 in image 3020 of
It is useful to perform a standard error analysis to understand the importance of the parameters in the FullTand and SimpleTand and their impact on practical loss tangent imaging. As seen from the above discussion, there are two types of error to be addressed: random and systematic.
With standard error analysis, the random uncertainty in loss tangent imaging Δr(tan δ) due to uncorrelated random uncertainty Δrφ, is given by ΔrΩ, Δraα and ΔrQ in φ, Ω, α and Q, respectively, from
Similarly, the systematic uncertainty in loss tangent imaging Δs(tan δ) due to systematic uncertainty Δsφ, is given by ΔsΩ, Δsα and ΔsQ respectively, for small uncertainty values from
For the case of both systematic and random uncertainty, the total uncertainty is determined by
Δtot(tan δ)=√{square root over ([Δs(tan δ)]2+[Δr(tan δ)]2)}
The separate derivatives in the above two equations for random and systematic uncertainty can be evaluated as
As a specific example comparing the relative weights of the foregoing terms, we assume a cantilever similar to those used in the experiments discussed above, the AC240 from Olympus, with the following operating parameters: Ω=1, α=0.5, Q=150 and ω=2π75 kHz. These conditions correspond to operating on resonance with a setpoint ratio of 0.5, (i.e., AM mode amplitude is 50% of the free amplitude). The sample loss tangent is assumed to be tan δ=0.1, as expected for a polymer such as high-density polyethylene. From the FullTand equation, these values yield a cantilever phase shift of φ≈36° (refer to image 3010 of
In the experience of the inventors, typical values of random uncertainty in amplitude, phase and tuning frequency are Δsφ=0.3°, Δsα=10−2, and ΔsΩ=10−3, respectively, for the first mode. These values yield a total loss tangent error estimate of Δs tan δ=0.026. This result is surprisingly large, given that the loss tangent of many polymer materials is of similar order or smaller. Of the three contributions, the largest is from the uncertainty in tuning frequency ΔsΩ. If that is improved to ΔsΩ=10−4, the loss tangent uncertainty is reduced to Δs tan δ=0.016. This somewhat unexpected result implies that careful identification of the cantilever resonance frequency is important for quantitative loss tangent estimation. While this level of tuning uncertainty is not typical for tapping mode operation, it is reasonable. An informal survey of autotune functions on a variety of commercial AFM instruments yielded scatter as large as 1 kHz and typically on the order of several hundred hertz. In the course of these investigations, we have improved our tuning routine to bring the frequency uncertainty closer to a few tens of hertz, ΔsΩ≦10−4, without adding significant time to the procedure.
It is also useful to define the signal to noise ratio (SNR) to consider how SNR affects the loss tangent:
Typically, we would like SNR≧1 so that the signal is larger than the uncertainty. For the example above with the AC240 Olympus cantilever, this corresponds to tuning the cantilever to within ˜300-400 Hz of the 75 kHz resonance. To better visualize this, images 3020, 3030 and 3040 of
Error parameters for
The graph 3050 in
We now turn to a further discussion of Frequency Modulation (FM) AFM. With FM AFM we measure the frequency shift as the tip interacts with the surface, and we can therefore quantify tip-sample interactions.
the frequency shift of a cantilever in FM mode is given by
In this equation Δf2 is the shift of the second resonant mode as the tip interacts with the surface, f0,2 is the second resonant frequency measured at a “free” or reference position, k2 is the stiffness of the second mode and A2 is the oscillation amplitude of the second mode as it interacts with the surface. Fts and z have previously been defined in connection with the presentation of the FullTand equation above. The FreqShift equation, as with the expression for the loss tangent, does not directly involve optical lever sensitivity.
In the limit that the oscillation amplitude of the second mode is much smaller than the oscillation amplitude of the first mode and is also much smaller than the length scale of Fts, the tip-sample interaction force, we can relate the measured frequency shift Δf2 to tip-sample stiffness:
This can be solved for the tip-sample stiffness as
The second mode resonant behavior provides a direct measure of the tip-sample interaction forces as shown in
In a second graph on the left side of
In the graph on the right side of
An alternative method for extracting the second mode resonance measurements just presented is to use the phase locked loop (PLL) 1160 of the apparatus for probing flexural resonances depicted in
One situation where it is advantageous to omit the use of the PLL is when the cantilever actuation mechanism includes a frequency-dependent amplitude and phase transfer function. This prerequisite may exist with a large variety of cantilever actuation means including acoustic, ultrasonic, magnetic, electric, photothermal, photo-pressure and other means known in the art. Operation in this mode is essentially bimodal, and is variously called DualAC mode, or AM/AM. The principal inventions describing this mode are U.S. Pat. No. 7,921,466, Method of Using an Atomic Force Microscope and Microscope; and U.S. Pat. No. 7,603,891, Multiple Frequency Atomic Force Microscope.
As noted above the phase shift which occurs when the amplitude and phase of the second mode resonance were measured while the first mode was held essentially constant by adjusting the z-height of the cantilever while the second mode frequency was ramped is accompanied by a stiffer interaction during the repulsive portion of the interaction. We can exploit this relationship between the phase shift and stiffness of the sample starting with the relationship between the frequency and phase shifts for a simple harmonic oscillator:
where Ω≡fdrive/f0 is the ratio of the drive frequency to the resonant frequency. Using the SimpleTand equation, this relationship can be manipulated to give the tip-sample interaction stiffness in terms of the phase shift measured at a fixed drive frequency:
It will be noted that this expression is only valid for small frequency shifts.
The expression of tip-sample interaction stiffness in terms of the phase shift can be extremely sensitive, down to the level of repeating images of single atomic defects. In
Since loss tangent is measurable using the first resonant mode of the cantilever and the frequency shift just described is measured using the second resonant mode, both measurements can be made simultaneously. We have found however that there are some practical experimental conditions to consider when applying this bimodal technique to nano-mechanical material property measurements. To begin with, the cantilever tip is sensitive to the G′ and G″ factors of the FullTand equation only in repulsive mode. This means that the following conditions favoring repulsive mode should be present:
Furthermore, in net-repulsive mode, the phase of the first mode should always be <90° and typically <50° for most materials; good feedback tracking (that is, for example, avoiding parachuting and making sure trace and retrace match) is important to assure good sampling of mechanical properties; and careful tuning of the cantilever resonances is particularly important to assure the accuracy of both techniques. Relative to this last point, the error for the resonances should be <10 Hz and the phase should be within 0.5 degrees. These are more stringent conditions than usual for AM mode but are well within the capabilities of commercial AFMs, given proper operation.
The measurements shown in
The stiffness measurement made with the second resonant mode depends on interaction stiffness kts. The modulus of the sample(s) in question can be mapped by applying a mechanical model. One of the simplest models is a Hertz indenter in the shape of a punch. In this case, the elasticity of the sample is related to the tip-sample stiffness by the relation kts=2aE′, where a is a constant contact area. Combining this with the SimpleTand equation above results in the expression
Thus if the contact radius and spring constant are known, the sample modulus can be calculated.
Other tip shapes could be used in the model. Calibration of the tip shape is a well-known problem. However, it is possible to use a calibration sample that circumvents this process. As a first step, we have used a NIST-traceable ultra high molecular weight high density polyethelene (UHMWPE) sample to first calibrate the response of the Olympus AC160 cantilever.
The equation immediately above can then be rewritten as E′=C2Δf2, where C2 is a constant, measured over the UHMWPE reference that relates the frequency shift to the elastic modulus. The result can be applied to unknown samples.
The foregoing bimodal technique providing for measuring stiffness with the second resonant mode can be performed at high speeds with the use of small cantilevers. The response bandwidth of the ith resonant mode of a cantilever is BWi=πfi,0/Qi where fi,0 is the resonant frequency of the ith mode and Qi is the quality factor. The resonant frequency can be increased without changing the spring constant by making smaller cantilevers. In contrast to normal AM imaging, however, the second resonant mode must still be accessible to the photodetector—which requires f2,0<10 MHz for an AFM like the Asylum Research Cypher AFM.
In general, one can choose any higher resonant mode for measuring stiffness, but the following considerations should be kept in mind:
1. Avoid modes that are at or very close to integer multiples of the first resonance. Integer multiples result in harmonic mixing between the modes which can cause instabilities. For example, it is quite common that the second resonance of an Olympic AC240 is ˜6× the first. For that reason, it is desirable to use the third resonant mode instead, which typically has a resonance of ˜15.5× the first mode. This point should be kept in mind even when the cantilever is not being driven at the second resonant mode. If a higher mode is too close to an integer multiple of the drive frequency, unwanted harmonic coupling can take place that leads to spurious, noisy or difficult to interpret results.
2. The sensitivity is optimized when the stiffness of the mode is tuned to the tip-sample stiffness.
In order to optimize the mechanical stiffness, contrast and accuracy of the tip-sample it appears to be advantageous to tune the amplitude of the second mode so that it is large enough to be above the detection noise floor of the AFM, but small enough not to affect significantly the trajectory and behavior of the fundamental mode motion as discussed above in reference to
It is also desirable to quantify the measurement of higher mode stiffness. In general, this is a challenging measurement. One method is to extend the thermal noise measurement method to higher modes. The thermal measurement depends on accurately measuring the optical lever sensitivity. This can be done by driving each resonant mode separately and then measuring the slope of the amplitude-distance curve as the cantilever approaches a hard surface. This calibrated optical sensitivity can then be used in a thermal fit as is well known in the art to get the spring constant for that particular resonant mode. Typical fits for the fundamental 2801, second resonant mode 2802 and third resonant mode 2803 are shown in
To obtain the interaction force between the tip and the sample, the FreqShift equation above has to be inverted. Initially, this would be done where the cantilever amplitude was either much smaller or much larger than the length scale of the tip-sample interaction. These limits can lead to practical errors in experimental data since the length scale of the tip-sample interaction forces is not necessarily known a priori. However, a very accurate inversion method has been developed by Sader and Jarvis which uses fractional calculus. Recently, Garcia and Heruzo have extended this method to bimodal frequency shifts. In particular, their method connects the frequency shift of the first and second resonant modes to a force model.
In these equations and D1/2 and I1/2 represent the half-derivative and half-integral operators respectively. F(dmin) is the tip-interaction force as a function of the position of closest dmin for the tip to the sample. These expressions are valid in the limit that the higher mode amplitude is much smaller than the first and also larger than the characteristic length scale of the tip-sample force.
These equations involve frequency shifts in the resonant modes of the cantilever. As such, they are directly applicable to the FM-FM imaging described by Garcia and Herruzo. For other bimodal approaches discussed above (specifically AM/AM and AM/FM) another step is required since a frequency shift observable has been replaced by a phase observable. Earlier we presented a linear approximation. Now we develop an exact conversion between the phase observable and the frequency shift observable of a simple harmonic oscillator (SHO).
For a SHO, the phase and frequency are related by tan φ=f0fi/Qtot(f02−fi2). In this expression, we have designated the quality factor as Qtot since it includes both the intrinsic damping of the cantilever and tip-sample dissipation. This expression can be inverted to yield frequency as a function of phase
For many samples, tip-sample dissipation is quite small, so that it can be neglected and the phase shift attributed only to conservative tip-sample interactions. In this situation, the Q factor for the above expression can be estimated from the free-air expression, Qtot≈Qc,i, where Qc,i is the quality factor of the ith mode of the cantilever, measured at a reference position close to the sample. It can be shown that this expression is valid when the loss tangent of the tip-sample interaction is small, of the order of the cantilever phase noise, tan δi≦10−2. For larger tip-sample losses, the tip-sample dissipation must be included in the calculation. This reduces the quality factor by
Qtot,i=Qc,i/(Qc,i tan δ+1). (QCalc1)
Using the loss tangent from above, if the cantilever is being driven at its free resonance frequency the tapping mode amplitude and phase observable yields:
As noted, this expression is valid when operating at a free resonance frequency, but is trivially generalizable to the off-resonance case. Using this formalism, it is possible to estimate the equivalent frequency shift from phase and amplitude measurements. We demonstrate this conversion for the second resonant mode of a cantilever interacting with a two-component polymer film in
In
There are many contact mechanics models that may be used for interpreting tip-sample interactions between a nano-scale indenter tip and a sample. Equations 2(a) and 2(b) provide a framework for applying these models to any tip-sample interaction that is fractionally differentiable.
An example of a power-law force between the tip-sample indentation and the applied force was postulated by Oliver and Pharr. Values of m=1, 3/2 and 2 are associated with the Hertzian Punch, Sphere and Cone (Sneddon) models respectively. In addition, the αm prefactor is replaced by the appropriate values in the expressions below:
Expression 3 just above can be applied to the fractional derivatives and integrals expressions 2(a) and (2b) above. Evaluation of the result gives the following model-dependent expressions for the indentation depth:
Here, the constants G1 and G3 from equation 4 (a) are defined as
Similarly, the effective sample modulus is given by:
Note that Equations 4 (b) and 5 (b) for the sphere model are identical to the expressions appearing in the Garcia and Tomas-Herruzo reference.
The equations above involve frequency shifts in the resonant modes of the cantilever. In bimodal and AM/FM measurements, the phase measurement of both or the first modes are measured (rather than controlled by a phase locked loop) while the drive frequency is kept constant.
One desirable quality of modulus measurements made in tapping mode is that the measured modulus be independent of the A1 setpoint value.
To test this condition the results of a series of numerical simulations of AM/AM (bimodal) tapping mode amplitude versus distance curves are shown in
Since the simulation was made in AM/AM mode, the amplitude and phase observables of both resonant modes were converted to effective resonant frequency shifts as discussed above.
This return of a substantially constant modulus versus a indicates that the tip-sample contact mechanical model is behaving properly. In the example here, the implication is that we have correctly chosen the sphere model, consistent with the model used to generate the numerical data. Tip shape characterization is a well known problem in the art and based on this observation we describe a new method of characterizing the tip shape below.
The estimation of loss tangent can be extended to sub-resonant oscillatory measurements as well. While sub-resonant measurements generally have reduced signal to noise performance and tend to exert larger forces on the sample, they can also have some advantages over resonant techniques.
With sub-resonant oscillatory measurements, we can define the virial of the tip-sample interaction by
Similarly, the dissipated power is given by Pts=<Ftsżtip>. Using these expressions, the loss tangent can be estimated by
These equations can be applied to non-resonant oscillatory motion including the sub-resonant oscillatory motion made while performing force-distance curves. These curves include so called “fast” force curves that are made at a frequencies greater than a few Hertz up to frequencies at or near the resonance frequency of the cantilever. One advantage of this approach is that the oscillatory waveform can be sinusoidal, triangular or other waveforms that could be expressed as a Fourier series.
Although only a few embodiments have been disclosed in detail above, other embodiments are possible and the inventors intend these to be encompassed within this specification. The specification describes specific examples to accomplish a more general goal that may be accomplished in another way. This disclosure is intended to be exemplary, and the claims are intended to cover any modification or alternative which might be predictable to a person having ordinary skill in the art. For example, other devices, and forms of modularity, can be used.
Also, the inventors intend that only those claims which use the words “means for” are intended to be interpreted under 35 USC 112, sixth paragraph. Moreover, no limitations from the specification are intended to be read into any claims, unless those limitations are expressly included in the claims. The computers described herein may be any kind of computer, either general purpose, or some specific purpose computer such as a workstation. The computer may be a Pentium class computer, running Windows XP or Linux, or may be a Macintosh computer. The computer may also be a handheld computer, such as a PDA, cellphone, or laptop.
The programs may be written in C, or Java, Brew or any other programming language. The programs may be resident on a storage medium, e.g., magnetic or optical, e.g. the computer hard drive, a removable disk or media such as a memory stick or SD media, or other removable medium. The programs may also be run over a network, for example, with a server or other machine sending signals to the local machine, which allows the local machine to carry out the operations described herein.
This application claims priority from provisional No. 61/995,905, filed Apr. 23, 2014, the entire contents of which are herewith incorporated by reference. This a continuation of application Ser. No. 14/694,980, filed Apr. 23, 2015, the entire contents of which are herewith incorporated by reference.
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20170131322 A1 | May 2017 | US |
Number | Date | Country | |
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Number | Date | Country | |
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Parent | 14694980 | Apr 2015 | US |
Child | 15275770 | US |