KR100496457B1 - Head of atomic force microscope - Google Patents

Abstract

The present invention relates to a structure and method for the alignment between a laser of a scanning probe microscope (SPM) device and a position sensitive photodiode detector (PSPD). The present invention is directed to eliminating a phenomenon in which a reference value of a PSPD signal changes according to a slope of a specimen surface. A structural method of equipment that enables high resolution.

To this end, the present invention changes the geometric arrangement and method of the conventional laser reflection mirror to a structure that maintains parallel state while moving two mirrors at the same time unlike the conventional method (one fixed mirror, one moving mirror) As a result, the reference value of the signal adjusted to the PSPD is maintained irrespective of the shape of the specimen or the degree of inclination.

Description

Atomic Microscope Head {HEAD OF ATOMIC FORCE MICROSCOPE}

The present invention relates to the head of an atomic force microscope. In general, an atomic force microscope is used to measure the deflection of the probe by using the characteristics of attraction and repulsive force in the gap between the tip of the probe and the atom on the sample surface. Provide surface image.

An atomic microscope that detects the force between the probe and the surface is the Scanning Probe Microscope (SPM), which uses the force that appears between atoms when they are brought closer to the size of one or two atoms. Examples are atomic force microscopy (AFM), which analyzes the surface by detecting the force between atoms acting between the probe and the sample surface, and electrostatic force, which detects the charge distribution on the surface using electrostatic forces acting between the surface charge and the probe supply charge. There is a magnetic force microscope (MFM) that magnetizes the microscope (EFM) or the probe to detect the magnetic properties of the sample surface, and detects the force acting between the surface and the sample to measure the shape of the surface.

AFM uses a small bar that can be bent up and down easily by very small and minute forces of about 100 micrometers in length, 10 micrometers in width and 1 micrometer in thickness. The tip of the cantilever has a pointed needle that is very sharp, about the size of a few atoms. When the probe approaches the sample surface, the attraction or repulsive force acts on the gap between the atoms at the tip of the probe and the atoms at the sample surface. When the repulsive force is applied, the magnitude of the force is very small (1-10 nN), but the cantilever is also very sensitive and is bent by the force. To measure the cantilever's bending up and down, the laser beam is projected on the cantilever. The angle of the light reflected from the top of the cantilever is measured using a photodiode. This allows you to measure the fine movement of the needle tip to about 0.01 nm. At this time, if the bend of the cantilever is kept constant by feeding back the movement of the tip of the needle to the driver, the distance between the tip of the probe and the sample is also constant, and thus the shape of the surface of the sample can be measured.

This operation is performed in three directions perpendicular to each other. Conventionally, x, y, and z scanners have been fixed to one body for three-dimensional scanning. However, this is because the scanners in three directions are tied together and cannot move independently from one of the other two axes in one axis direction, resulting in nonlinearity and crosstalk.

In addition, in order to solve the above problems, a scanner in which the z-direction scanner is separated from the xy-direction scanner has been introduced. Since such a scanner can scan a sample in the xy direction regardless of the z-direction, not only a small sample but also a large sample You can scan as much as you want and scan without distortion. In addition, to reduce the mass driven by the separate z scanner, the z scanner only moves the cantilever and detector, and the laser and laser beam alignment system structure is fixed to another frame. In this case, however, if the cantilever needs to be replaced, the first moving mirror and the second fixed mirror, which must always be parallel when the laser beam is fixed to the center of the detector, are always slightly different from the first one. There is a problem in that the reference signal value, which has an open angle, and which is always fixed according to the magnitude of the angle, changes depending on the inclination of the specimen or the state of the surface during scanning, resulting in a deformation of the reference value. The variation of the reference value of the inverse feedback has a problem of realizing an unpredictable image by causing the scanner to sense the force caused by the error, not the force actually felt between the sample surface and the probe by having a height error in the z direction at several nanoscales. there was.

In order to solve the above problems, the present invention provides a scanning without nonlinearity in the scan in the x, y, and z directions, while completely eliminating the deformation of the basic signal resulting from the mirror movement or the degree of inclination of the sample. It is an object to provide a geometric structure and method.

In order to achieve the above object, the present invention provides an atomic microscope head, the atomic microscope head,

A laser light source for generating laser light;

A prism that refracts the direction of light emitted from the laser light source;

A cantilever having a probe interlocked with surface curvature of a sample to be measured, wherein the refracted light is seated and reflects the seated light;

At least one mirror reflecting light reflected from the cantilever;

A detector for measuring a degree of bending of the cantilever by measuring an angle of light reflected from the mirror;

A laser adjustment bar for adjusting the convergence position at which the light converges on the cantilever;

A mirror adjustment bar for adjusting the position of the mirror;

By measuring the degree of warp of the cantilever due to the change in force between the cantilever and the atoms on the sample surface, which are generated by scanning in three directions perpendicular to each other, the feedback from the initial reference signal determined by the detector is reversed. In the atomic microscope head including a scanner for correcting the small change of the cantilever,

One of the scanners is separated from the other two scanners perpendicular to each other,

The mirrors provide an atomic microscope head characterized in that they are always fixed in parallel and move together in conjunction.

In the atomic microscope head, the laser adjustment bar may be adjustable in three directions perpendicular to each other. In the conventional atomic force microscope, only the x-y direction adjustment bar is provided. However, the adjustment of the direction in the z direction has to be performed by separating and adjusting the atomic microscope, but the device according to the present invention is also easy to adjust in the z direction.

The mirror in the atomic microscope head may be two. In special cases three or more mirrors may be used, but the use of two mirrors is the most common.

The separated scanner in the atomic microscope head is coupled to the cantilever and detector and can be driven together. By separating and driving the scanners in one of the three directions perpendicular to each other, the nonlinearity that occurs when the scanners in the three directions are driven together can be eliminated.The separated scanners combine detectors and cantilevers that are relatively light in weight. This makes driving easy.

The two mirrors in the atomic microscope head may be of different sizes. By increasing the size of the mirror that is finally reflected toward the detector among the mirrors, reflection is possible even when the angle of reflection of the light reflected from the previous mirror is expanded.

The cantilever may be detachable from the atomic microscope head. By making the cantilever detachable, the cantilever can be exchanged for use in the MFM.

Desorption of the cantilever from the atomic microscope head may be detachable by a magnet. In order to facilitate the detachment of the cantilever, the detachment may be made magnetically.

The detachable tip of the cantilever from the atomic microscope head may be detachable by a screw or the like. By screwing from the bottom, it is easy to detach by removing the tip from the bottom where there is a relatively large space. In particular, in the case of a structure in which the microscope head is folded in an atomic microscope as shown in Figure 5, it is easier to detach / attach the tip because the microscope head can be folded up and detached from the tip. The same applies to the case of detaching / attaching the cantilever itself.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view of an atomic force microscope head 10 according to an embodiment of the present invention.

The head is composed of a laser light source 12, a z scanner, a detector 16, a mirror 15, a cantilever 14, a mirror adjustment bar 13, a laser adjustment bar 11 and the like. Light from the laser light source 12 is reflected through the prism onto the mirror 15 on the cantilever 14 and by the continuous reflection of the mirrors 15 the light is adjusted to the center of the detector 16 and the value is Scanning is performed with the appropriate reference signal values. At this time, the x-y scanner is driven by the x-y scan controller, and the detector measures the angle at which the laser beam reflected by the cantilever 14 is reflected. In this way, it is possible to measure even minute movements of about 0.01 nm. The movement of the tip of the needle is compared with the initial reference signal value, and the z-scanner is moved to keep the cantilever 14 bent constantly. The shape of the sample is measured at regular intervals.

Conventionally, in the case of an atomic force microscope in which an x, y, z scanner is integrally manufactured, one direction of movement of the scanner becomes independent of the other direction, resulting in a problem of nonlinearity, but in the embodiment according to the present invention, the xy scanner By operating the and z-scanner separately, the problem of nonlinearity as described above can be solved. Although atomic microscopes in which xy scanners and z scanners are separated as in the present invention have conventionally existed, even after the initial setting of the reference signal value, even if a small change occurs due to the mirror position for any reason, the reflected angle changes to reach the detector. This results in a different position, which causes deformation in the inverse feedback value and an error in the z direction, resulting in an image different from the actual one, but the device according to the present invention has a state in which mirrors are always parallel as shown in the drawing. By keeping them together, they reduce the likelihood of errors due to unexpected changes in the mirror's position.

In this embodiment, the detector 16 uses a photo sensitive photo diode (PSPD), which consists of four cells and is adapted to accurately detect the position change displacement of the laser.

Also, as shown in the above figure, the cantilever 14 and the detector 16 are driven together by the z scanner. This reduces the z servo bandwidth by reducing the mass the z servo needs to drive. In addition, the portion including the cantilever 14 can be detached from the z scanner. Therefore, the cantilever 14 may be replaced and used to determine the magnetic property of the sample by using a magnetically coated probe. In this case, as the magnetic material for coating the probe, cobalt, chromium, nickel, or the like may be used. The cantilever 14 is simultaneously influenced by the atomic force and the magnetic force, and can be distinguished because the two forces have different properties, that is, the atomic force works largely near the sample but the magnetic force works far. Therefore, a topography image is obtained by measuring the magnitude of the force near the sample, and a magnetic distribution is obtained by measuring the distance from a distance. In this way it can be used to determine the magnetic properties of the sample.

The method of joining the part including the cantilever 14 may be a clip method or a magnet method. In the same way, it is possible to use EFM instead of MFM.

2 shows another embodiment of an atomic microscope head 10 according to the present invention. 2 is a perspective view from above of an atomic microscope head 10 according to the present invention. It can be seen that there are three laser adjustment bars 11, and adjustment in three directions perpendicular to each other is possible. Conventional laser adjustment bar 11 can adjust the position of the mirror only in the x-y direction, but in the embodiment according to the present invention can also be adjusted in three directions perpendicular to each other can also be adjusted in the z direction. This minimizes the cross-section of the laser light at the spot of the reflected laser when the laser exiting the laser light source 12 is reflected by the cantilever 14. The conventional product initially has an optimal cross-section where the laser falls to the spot. Even if it is set to, it is not easy to adjust when there is a change due to the cause of equipment obsolescence, but in the apparatus according to the present invention can be adjusted in three directions perpendicular to each other, so the position of the laser is adjusted in the z direction to the spot. It is possible to adjust so that the falling section is optimal. However, the laser adjustment bar 11 in the z-direction can be seen that the handle is made small because the frequency of use is small.

3A, 3B, and 3C show an error caused by the positional shift of one of the mirrors 15 when the mirrors 15 are always parallel and do not move in the atomic microscope in which the conventional z scanner is separated. It is a figure which shows that. There is no problem when the mirrors are parallel as shown in Fig. 3A. However, if one mirror 15 is displaced by about 1 degree for some reason (b in Fig. 3), the cantilever 14 The point at which the laser reflected from) arrives at the detector 16 is different, i.e., the reference signal value is changed so that the z scanner moves down that much to correct it. In this case, the angle at which the laser reaches the detector 16 is changed due to the difference in angle between the two mirrors 15, resulting in a change in the reference value. In this case, the result is a scan of a force that does not actually exist, resulting in an error in the surface image. 3c illustrates this process. As shown in the figure, when the z-scanner is moved downward to correct the change in the reference signal value, it can be seen that the detection position in the detector is changed due to the change in the angle at which the laser reaches the detector 16.

4A and 4B show schematic views of an atomic microscope head 10 having a mirror structure according to the present invention. 4A shows a case in which the mirrors 15 move simultaneously with each other. As shown in the figure, since the mirror 15 is interlocked, the other mirror 15 has the same angle as the horizontal plane as much as the angle of one mirror 15 to the horizontal plane. Therefore, when one mirror 15 is out of the initial state and has a different angle, the other mirror 15 has the same angle.

 4B shows the case where the mirror 15 is inclined by about 1 degree from the initial angle. Even if the mirror 15 differs by about one degree from the initial angle, since the two mirrors 15 are integrated, the mirrors 15 are all inclined to the same degree and parallel to each other. In addition, even if the cantilever 14 descends by the feedback action, since the cantilever 14 and the detector 16 move together while being attached to the z scanner, the detector also descends as much as the cantilever 14 descends, and the reflection angle of the mirror is also lowered. Is constant so that the angle at which the laser reaches the detector 16 does not change and thus the position of the laser reaching the detector 16 does not change. Therefore, it can be seen that there is no difference in the initially set reference value.

Figure 5 shows one embodiment of an atomic microscope equipped with an atomic microscope head 10 according to the present invention. An example is where the atomic microscope head 10 according to the invention is attached in a folded manner. When the cantilever 14 or the tip is detachably manufactured as in the present invention, the detachment can be made easier by manufacturing the atomic microscope by folding the atomic microscope head 10 itself upward. In this case, the tip is also tightened from the top, as in the case of the prior art, if not fixed by tightening from below it is more easily removable.

The present invention provides a device in which the moving mirror is always parallel and interlocked, and the scanner in one direction is operated separately from the scanner in the other two directions, thereby providing scanning without the nonlinearity and tilting of the specimen or the tilt of the sample. It provides an atomic microscope head that eliminates errors from the degree of gin.

In addition, by allowing the laser to be adjusted in three directions perpendicular to each other, it is possible to provide an atomic microscope head that can easily adjust the cross-sectional area of the laser seated on the cantilever.

1 illustrates one embodiment of an atomic microscope head in accordance with the present invention.

2 shows another embodiment of an atomic microscope head according to the present invention;

3A, 3B, and 3C are diagrams showing that an error occurs when a conventional fixed mirror and a moving mirror move without being parallel.

4A and 4B show the operation of an atomic microscope head having a mirror structure according to the present invention.

5 shows one embodiment of an atomic microscope with an atomic microscope head in accordance with the present invention.

<Explanation of symbols for the main parts of the drawings>

10: atomic force microscope head 11: laser adjustment bar

12: laser light source 13: mirror adjustment bar

14: cantilever 15: mirror

16: Detector (PSPD)

Claims (8)

A laser light source 12 for generating laser light; A prism that refracts the direction of light emitted from the laser light 12 source; A cantilever (14) having a probe interlocked with the surface curvature of the sample to be measured, wherein the refracted light is seated and reflects the seated light; One or more mirrors (15) for reflecting light reflected from the cantilever (14); A detector (16) for measuring the degree of bending of the cantilever (14) by measuring the angle of light reflected from the mirror (15); A laser adjustment bar (11) for adjusting the convergence position at which the light converges on the cantilever (14); A mirror adjustment bar (13) for adjusting the position of the mirror (15); Initial reference signal determined by the detector 16 by measuring the degree of warpage of the cantilever 14 due to a change in the force between the cantilever 14 and the atoms on the sample surface, generated by scanning in three directions perpendicular to each other. A scanner for correcting the small change of the cantilever 14 by inverting the difference from the value; An atomic microscope head comprising: One of the scanners is separated from the other two scanners perpendicular to each other, Said mirrors (15) are always fixed in parallel so that they move in conjunction with the atomic microscope head. 2. The atomic microscope head of claim 1, wherein the laser adjustment bar is adjustable in three directions perpendicular to each other. 3. 2. Atomic microscope head according to claim 1, characterized in that the mirror (15) is two. 4. Atomic microscope head according to claim 3, characterized in that the separated scanner is coupled and driven together with the cantilever (14) and the detector (16). 5. Atomic microscope head according to claim 4, characterized in that the two mirrors (15) are of different sizes. The atomic force microscope head according to any one of claims 1 to 5, wherein the cantilever (14) is detachable. delete delete