Let’s come back to the AFM mentioned at the beginning and look at an example of how scientists continuously work to improve these instruments.Since the nanoscale world is accessible only with specialized—and often very expensive—tools, the ongoing improvement of these instruments, and the development of new ones, is a crucial aspect of continuous progress in
nanosciences and nanotechnologies. Contrary to much of the hype surrounding the field, a large part of ‘nanotechnology’ today is about developing new tools,techniques, and applications to explore and understand phenomena at the nanoscale.
‘‘Children begin to learn by seeing, hearing, tasting and, above all, by touching. In a very similar approach, we are currently learning to orient ourselves in the nanoworld by ‘feeling’ materials—not with our fingers, but with microscopes that allow us to probe these materials with atomic resolution.’’4 The ability of researchers to engineer novel materials that possess superior electronic, thermal, magnetic, and mechanical properties depends on tools that can identify and characterize material components and their spatial arrangement at the nanoscale. Equally important, understanding structure–function relationships in biological systems also demands tools that can probe structural properties with molecular resolution: AFMs are the most widely used tools to image matter at the nanoscale.
The operating principle of an AFM is based on an atomically sharp tip,placed at the end of a flexible cantilever beam, that is brought into physical contact with the surface of a sample. The cantilever beam deflects in proportion to the force of interaction. Scanning across the surface, the sharp tip follows the bumps and grooves formed by the atoms on the surface. A topography of the surface can be generated by monitoring the deflections of the flexible cantilever beam.
Because of its mechanical operation, the AFM can in principle also perform nanomechanical measurements. This aspect of the AFM has been explored by researchers over the past two decades. However, current state-of-the-art techniques are very slow—it takes about a second for the AFMtip to approach,push into, and retract from the surface of a material—and rather large forces are applied during the measurement process that damage the tip and the
sample.
Researchers at Harvard and Stanford universities have developed a speciallydesigned AFM cantilever tip, the torsional harmonic cantilever (THC), which offers orders-of-magnitude improvements in temporal resolution, spatial resolution, indentation, and mechanical loading compared to conventional tools. With high operating speed, increased force sensitivity, and excellent lateral resolution, this tool facilitates practical mapping of nanomechanical
properties.
Notwithstanding all the advances that have been made in the field of AFM,Ozgur Sahin from the Nanomechanical Sensing Group at the Rowland Institute at Harvard University in the USA says that so far a technique that can quantitatively map mechanical properties in detail with nanoscale resolution is missing. ‘‘Mechanical properties of matter are largely determined by the nature of chemical bonds and their spatial organization in the material,’’ he explains.‘‘Furthermore, materials used in everyday life exhibit a huge variation in their mechanical properties. Diamond, for example, is almost a million times stiffer than rubbery materials. The spectrum of mechanical properties of materials spans the range between these two extremes. These observations tell us that there is a lot of information in mechanical properties of materials.
’’ Sahin, together with collaborators from Stanford University, led by Olav Solgaard, and Veeco Instruments, describes the design of a special cantilever tip that allows the material properties of a surface to be determined and mapped in detail with nanoscale spatial resolution. ‘‘In order to create a high-speed and sensitive nanomechanical measurement tool, we have started from the most commonly used AFM technique called the tapping mode,’’5 explains Sahin.‘‘The primary advantage of this technique is that it protects the tip and the sample during the imaging process and minimizes the interaction forces.
‘‘For our goal of performing mechanical measurements, tapping mode also provides a unique opportunity because the sharp tip is moving back and forth against the surface and feels the variation of force during the interaction. If one can detect those forces varying with tip–sample distance, one can perform a
clear and detailed mechanical analysis.
’’Unfortunately, there are major difficulties in measuring the forces between the tip and the sample. These forces change at a rate much faster than the vibration of the cantilever, therefore the force-sensing cantilever cannot respond to them. Indeed, there is a wealth of publications in the literature working on the nonlinear dynamics of tapping cantilevers that seek indirect
ways to measure these forces. ‘‘In a way, our work stands on the shoulders of these pioneers, because they have reached a very good understanding of the complicated cantilever dynamics in AFMs,’’ says Sahin. ‘‘Nevertheless, we have taken a different approach by engineering the force-sensing cantilever to measure the interaction forces directly.’’
The AFM cantilever has many vibration modes, each of which can act as an independent force sensor. The rapidly changing forces demand the use of a fast mode with high-resonance-frequency. The problem with high resonance frequency modes is that they are stiff and do not bend easily to give a good signal.
‘‘What we have noticed is that torsional vibration modes allow good signal levels and they have high enough resonance frequencies,’’ says Sahin.‘‘Unfortunately, tip sample forces do not excite torsional oscillations because the conventional cantilevers have their tips on the center line. Therefore, we designed cantilevers that have their tips off-centered. When this cantilever hits
the surface, tip–sample forces generate a torque that bends the cantilever torsionally.Torsional vibrations can be detected in a commercial AFM system simultaneously with the vertical vibrations.’’
When this cantilever is operated in conventional tapping-mode—touching the surface ever so lightly some 50 000 times per second (50 kHz)—the torsional vibrations can be simultaneously detected and translated into a time-varying tip–sample force waveform which contains detailed information about the mechanical properties of the sample. Figure 1.2
‘‘In principle, the speed of these measurements is limited by the oscillation frequency of the cantilever,’’ says Sahin. ‘‘At the moment, we are not fully benefiting from the speed enhancement. However, it is still more than a factor of 1000 times faster than conventional mechanical measurements, yet it is much gentler to the sample. Improved speed enables mapping mechanical properties across a surface with nanometer resolution. I believe that in the near future we will see mechanical measurements performed within a microsecond. This will
open up a new window to study time dependent phenomena at the nanoscale,such as protein folding and chemical reactions in general.’’
Sahin and his collaborators have demonstrated their technique on a 50 nm thick polymer composite (PMMA—a clear, hard plastic also known under its trade name Plexiglas) that has two components with submicron features. These components have different thermal characteristics. Sahin explains that as the PMMA is heated up, it goes through a glass transition at around 100 1C where the hard, brittle polymer becomes rubbery and compliant. ‘‘When you heat up a polymer composite, each component has a different glass transition temperature and therefore a bulk measurement does not tell us how individual components behave. The high-resolution mechanical measurement technique we presented allowed us to observe the changes in the two components of the polymer independently. This kind of ability is crucial for the development of
any material system with multiple components.
An intriguing application with significant potential lies in using mechanical sensing to detect biomolecular reactions. When molecules bind, their mechanical properties change dramatically and in a specific way. Sahin says that a mechanical sensing technique such as theirs could lead to label-free, yet specific, detection with single-molecule resolution.
Developing this technique further, Sahin sees two distinct paths. ‘‘One major direction will be towards biomolecular detection, and the other is material analysis,’’ he says, ‘‘but there are a number of challenges. AFM in general is difficult to work with in liquids. If this can be resolved, mechanical sensing in liquids will provide exciting opportunities in the study of biological systems and biomolecules.
’’ Featured scientist: Ozgur Sahin
Organization: Rowland Institute at Harvard, Cambridge, MA, USA
Relevant publication: Ozgur Sahin, Sergei Magonov, Chanmin Su,
Calvin F. Quate, Olav Solgaard: An atomic force microscope tip
designed to measure time-varying nanomechanical forces. Nat.
Nanotechnol., 2, 507–514.
Source
Nano-Society
www.rsc.org/nanoscience
nanosciences and nanotechnologies. Contrary to much of the hype surrounding the field, a large part of ‘nanotechnology’ today is about developing new tools,techniques, and applications to explore and understand phenomena at the nanoscale.
‘‘Children begin to learn by seeing, hearing, tasting and, above all, by touching. In a very similar approach, we are currently learning to orient ourselves in the nanoworld by ‘feeling’ materials—not with our fingers, but with microscopes that allow us to probe these materials with atomic resolution.’’4 The ability of researchers to engineer novel materials that possess superior electronic, thermal, magnetic, and mechanical properties depends on tools that can identify and characterize material components and their spatial arrangement at the nanoscale. Equally important, understanding structure–function relationships in biological systems also demands tools that can probe structural properties with molecular resolution: AFMs are the most widely used tools to image matter at the nanoscale.
The operating principle of an AFM is based on an atomically sharp tip,placed at the end of a flexible cantilever beam, that is brought into physical contact with the surface of a sample. The cantilever beam deflects in proportion to the force of interaction. Scanning across the surface, the sharp tip follows the bumps and grooves formed by the atoms on the surface. A topography of the surface can be generated by monitoring the deflections of the flexible cantilever beam.
Because of its mechanical operation, the AFM can in principle also perform nanomechanical measurements. This aspect of the AFM has been explored by researchers over the past two decades. However, current state-of-the-art techniques are very slow—it takes about a second for the AFMtip to approach,push into, and retract from the surface of a material—and rather large forces are applied during the measurement process that damage the tip and the
sample.
Researchers at Harvard and Stanford universities have developed a speciallydesigned AFM cantilever tip, the torsional harmonic cantilever (THC), which offers orders-of-magnitude improvements in temporal resolution, spatial resolution, indentation, and mechanical loading compared to conventional tools. With high operating speed, increased force sensitivity, and excellent lateral resolution, this tool facilitates practical mapping of nanomechanical
properties.
Notwithstanding all the advances that have been made in the field of AFM,Ozgur Sahin from the Nanomechanical Sensing Group at the Rowland Institute at Harvard University in the USA says that so far a technique that can quantitatively map mechanical properties in detail with nanoscale resolution is missing. ‘‘Mechanical properties of matter are largely determined by the nature of chemical bonds and their spatial organization in the material,’’ he explains.‘‘Furthermore, materials used in everyday life exhibit a huge variation in their mechanical properties. Diamond, for example, is almost a million times stiffer than rubbery materials. The spectrum of mechanical properties of materials spans the range between these two extremes. These observations tell us that there is a lot of information in mechanical properties of materials.
’’ Sahin, together with collaborators from Stanford University, led by Olav Solgaard, and Veeco Instruments, describes the design of a special cantilever tip that allows the material properties of a surface to be determined and mapped in detail with nanoscale spatial resolution. ‘‘In order to create a high-speed and sensitive nanomechanical measurement tool, we have started from the most commonly used AFM technique called the tapping mode,’’5 explains Sahin.‘‘The primary advantage of this technique is that it protects the tip and the sample during the imaging process and minimizes the interaction forces.
‘‘For our goal of performing mechanical measurements, tapping mode also provides a unique opportunity because the sharp tip is moving back and forth against the surface and feels the variation of force during the interaction. If one can detect those forces varying with tip–sample distance, one can perform a
clear and detailed mechanical analysis.
’’Unfortunately, there are major difficulties in measuring the forces between the tip and the sample. These forces change at a rate much faster than the vibration of the cantilever, therefore the force-sensing cantilever cannot respond to them. Indeed, there is a wealth of publications in the literature working on the nonlinear dynamics of tapping cantilevers that seek indirect
ways to measure these forces. ‘‘In a way, our work stands on the shoulders of these pioneers, because they have reached a very good understanding of the complicated cantilever dynamics in AFMs,’’ says Sahin. ‘‘Nevertheless, we have taken a different approach by engineering the force-sensing cantilever to measure the interaction forces directly.’’
The AFM cantilever has many vibration modes, each of which can act as an independent force sensor. The rapidly changing forces demand the use of a fast mode with high-resonance-frequency. The problem with high resonance frequency modes is that they are stiff and do not bend easily to give a good signal.
‘‘What we have noticed is that torsional vibration modes allow good signal levels and they have high enough resonance frequencies,’’ says Sahin.‘‘Unfortunately, tip sample forces do not excite torsional oscillations because the conventional cantilevers have their tips on the center line. Therefore, we designed cantilevers that have their tips off-centered. When this cantilever hits
the surface, tip–sample forces generate a torque that bends the cantilever torsionally.Torsional vibrations can be detected in a commercial AFM system simultaneously with the vertical vibrations.’’
When this cantilever is operated in conventional tapping-mode—touching the surface ever so lightly some 50 000 times per second (50 kHz)—the torsional vibrations can be simultaneously detected and translated into a time-varying tip–sample force waveform which contains detailed information about the mechanical properties of the sample. Figure 1.2
‘‘In principle, the speed of these measurements is limited by the oscillation frequency of the cantilever,’’ says Sahin. ‘‘At the moment, we are not fully benefiting from the speed enhancement. However, it is still more than a factor of 1000 times faster than conventional mechanical measurements, yet it is much gentler to the sample. Improved speed enables mapping mechanical properties across a surface with nanometer resolution. I believe that in the near future we will see mechanical measurements performed within a microsecond. This will
open up a new window to study time dependent phenomena at the nanoscale,such as protein folding and chemical reactions in general.’’
Sahin and his collaborators have demonstrated their technique on a 50 nm thick polymer composite (PMMA—a clear, hard plastic also known under its trade name Plexiglas) that has two components with submicron features. These components have different thermal characteristics. Sahin explains that as the PMMA is heated up, it goes through a glass transition at around 100 1C where the hard, brittle polymer becomes rubbery and compliant. ‘‘When you heat up a polymer composite, each component has a different glass transition temperature and therefore a bulk measurement does not tell us how individual components behave. The high-resolution mechanical measurement technique we presented allowed us to observe the changes in the two components of the polymer independently. This kind of ability is crucial for the development of
any material system with multiple components.
An intriguing application with significant potential lies in using mechanical sensing to detect biomolecular reactions. When molecules bind, their mechanical properties change dramatically and in a specific way. Sahin says that a mechanical sensing technique such as theirs could lead to label-free, yet specific, detection with single-molecule resolution.
Developing this technique further, Sahin sees two distinct paths. ‘‘One major direction will be towards biomolecular detection, and the other is material analysis,’’ he says, ‘‘but there are a number of challenges. AFM in general is difficult to work with in liquids. If this can be resolved, mechanical sensing in liquids will provide exciting opportunities in the study of biological systems and biomolecules.
’’ Featured scientist: Ozgur Sahin
Organization: Rowland Institute at Harvard, Cambridge, MA, USA
Relevant publication: Ozgur Sahin, Sergei Magonov, Chanmin Su,
Calvin F. Quate, Olav Solgaard: An atomic force microscope tip
designed to measure time-varying nanomechanical forces. Nat.
Nanotechnol., 2, 507–514.
Source
Nano-Society
www.rsc.org/nanoscience
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