JPH08285870A - Atmosphere controllable probe scanning type microscope - Google Patents

Abstract

PURPOSE: To observe even a biological sample as it is by providing an airtight sample observation chamber with a gas discharge means and an inert gas introduction means thereby controlling the atmosphere freely at the time of observation. CONSTITUTION: After entirely discharging the gas (normally, the atmosphere) in an airtight sample observation chamber (main chamber) 14 temporarily through a gas exhaust means, an inert gas is introduced through a gas introduction means into the chamber 14, while detecting the pressure by means of a pressure sensor, until an arbitrary pressure is reached thus controlling the atmosphere in the chamber 14 arbitrarily. Subsequently, a probe is scanned along the surface of a sample to obtain the three-dimensional image of the surface of sample. A rotary pump 41 and a turbo molecular pump 40 are used as the means for discharging the gas in the chamber 14. A gas cylinder 49, a terminal 48 for coupling the gas cylinder 49, etc., are used as the means for introducing an inert gas (e.g. argon gas) into the chamber 14.

Description

Detailed Description of the Invention

[0001]

TECHNICAL FIELD The present invention relates to a probe scanning microscope (SPM = Scanning Probe Microscope or SX) such as an atomic force microscope (Atomic Force Microscope) and a scanning tunneling microscope (Scanning Tunneling Microscope).
M).

[0002]

2. Description of the Related Art In an atomic force microscope (AFM), a probe having a sharp tip is attached to the tip of a cantilever so that the tip of the probe is very close to the sample surface (between the tip of the probe and the sample surface). Distance of 1 nm = on the order of 10 ⁻⁹ m). When the probe is scanned along the surface of the sample in this state, the probe moves up and down due to van der Waals force and repulsive force acting between atoms at the tip of the probe and atoms on the sample surface.
The cantilever flexes accordingly. deflection of this cantilever during scanning of the probe in the xy plane (z-coordinate)
Is detected by laser light or the like, a three-dimensional image (concavo-convex image) of the surface shape of the sample can be obtained. Usually, the height of the cantilever is feedback-controlled so that the deflection of the cantilever becomes constant, and an uneven image of the sample surface is obtained by the height of the cantilever at each point on the sample surface.

Further, in a scanning tunneling microscope (STM), a probe is similarly arranged very close to the surface of a sample,
A voltage is applied between the sample and the probe. By appropriately adjusting this voltage, a tunnel current flows between the sample and the probe. In the STM, the shape of the sample surface is obtained by scanning the sample surface with a probe while controlling the interval between the two so that the tunnel current is constant.

As described above, a microscope for measuring the shape of the sample surface by scanning the surface of the sample with a probe is, besides these, a laser force microscope (LFM).
oscope), magnetic force microscope (MFM = Magnetic Force Mic)
roscope), scanning ion conduction microscope (SICM = Scanni)
ng Ion-Conductance Microscope) and a scanning capacitance microscope (SCM = Scanning Capacitance Microscope). All of these have a feature that a very high resolution (magnification) can be obtained because the probe is brought close to the surface of the sample in atomic order.

At present, since AFM and STM are mainly intended for observation of non-biological samples such as metals and semiconductors, the samples are placed in an ultra-high vacuum sample chamber, and a clean surface is obtained by heating or cleavage. ing.

[0006]

When observing biological samples such as proteins and DNA, setting them in a vacuum may cause the morphology to be significantly different from that under normal pressure. Therefore, the biological sample has been conventionally observed in the atmosphere.

However, in this case, since the sample and the probe are observed without any protective equipment, there is a possibility that pollutants in the air adhere to the sample and the probe. However, since the resolution (magnification) of AFM and STM is very high as described above, when observing with such a contaminant adhering to the surface of the sample, it is impossible to know what is being observed. In addition, since a biological sample is aggregated in a vacuum, there is a problem that an image of an individual sample cannot be obtained.

[0008] These problems are not limited to AFM and STM.
This always occurs when a biological sample is to be observed with various probe scanning microscopes (SPM). The present invention has been made to solve such a problem, and an object of the present invention is to arbitrarily control the atmosphere when a sample is observed with a probe scanning microscope (SPM), Is to enable observation as it is.

[0009]

SUMMARY OF THE INVENTION An atmosphere-controlled probe scanning microscope according to the present invention, which has been made to solve the above-mentioned problems, comprises a) an airtight sample observation chamber, and b) a sample observation chamber. A probe provided so that its tip is near the surface of the sample; and c) a probe moving means for driving the probe or the sample three-dimensionally so that the tip of the probe moves along the surface of the sample. D) A gas discharge means for discharging gas in the sample observation chamber, and e) Gas introduction means for introducing an inert gas into the sample observation chamber, and are characterized by observing the sample in the presence of an inert gas. .

According to the present invention, by adopting the above-mentioned structure, the gas discharging means d once discharges all the gas (usually the atmosphere) in the sample observing chamber a, and then the gas introducing means e causes the sample observing chamber a. Another inert gas is introduced into the inside until an arbitrary pressure is reached. As a result, the atmosphere in the sample observation chamber can be controlled as desired. Thereafter, by scanning the probe b along the surface of the sample by the probe moving means c, a three-dimensional image of the surface shape of the sample can be obtained.

[0011]

BEST MODE FOR CARRYING OUT THE INVENTION An atomic force microscope (AF
An example applied to M) will be described with reference to FIGS. As shown in FIG. 1, the AFM of this embodiment is roughly classified into an observation unit 10,
It is composed of a control unit 11 and a console unit 12. In the observation section 10, a main chamber 14 is provided on a table 15 supported by an air suspension 16. The main chamber 14 is airtightly assembled,
A plurality of transparent windows (in addition to the obliquely upper transparent window 17 and the front transparent window 18 shown in FIG. 1, two transparent windows (not shown) are also provided on the upper surface) and two operation openings 20. , 21 are provided.

As shown in FIG. 2A, a sample station 23 is provided in the main chamber 14.
In the sample station 23, the sample 24 is placed on the upper surface of the piezo driver 25. When observing the sample, use sample 2
The coarse movement motor of the cantilever holding mechanism provided on the upper part of 4 sets the probe attached to the tip of the cantilever 26 so as to come close to the sample 24. After that, the sample 24 is gradually lifted (moved in the z direction) by the piezo driver 25 to further reduce the distance between the sample surface and the tip of the probe. When the cantilever 26 bends by a predetermined amount due to the atomic force between the two, the movement of the piezo driver 25 in the z direction is stopped, and the sample 24 is then scanned by the piezo driver 25 in the xy plane. While scanning is performed in this way, the cantilever holding mechanism detects the amount of deflection of the cantilever 26 by the deflection angle of the laser beam emitted from the laser 27 to the cantilever, and transmits it to the control unit 11. The control unit 11 drives the piezo driver 25 in the z direction so that the deflection amount of the cantilever 26 is always constant, and moves the sample 24 up and down. When the scanning of the predetermined area is completed, a three-dimensional image of the surface shape of the sample 24 is obtained.

As shown in FIG. 3, a sample introducing pipe 30 is connected to the side wall of the main chamber 14, and a sample chamber 31 sandwiched by valves 32 and 33 at the front and back is provided in the middle of the sample introducing pipe 30. It is provided. Further, rubber gloves 35 and 36 are airtightly attached to the operation openings 20 and 21 provided on the side wall of the main chamber 14 in the other direction, respectively, and after the rubber gloves 35 and 36 are pulled out, There are also provided shutters 37 and 38 that can hermetically shield the operation openings 20 and 21.

In the AFM of this embodiment, the main chamber 1
4 can control the gas atmosphere. A gas system for that purpose is provided below the table 15, and its piping and the like are as shown in FIG. AFM of the present embodiment
Uses a rotary pump (RP) 41 and a turbo-molecular pump (TMP) 40 to exhaust gas (initially air) in the main chamber 14. Further, a terminal 48 for connecting a gas cylinder 49 is provided in the case of filling the inside of the main chamber with another gas (for example, argon gas). The gas system further includes these pumps 40 and 41, cylinder 49 and main chamber 1
4. Pipe 42 and various valves 43, 44, 4 for connecting the space between the sample chamber 31 and the shutters 37, 38 of the operation openings 20, 21 and the rubber gloves 35, 36.
5, 46, 47 are included.

A procedure for observing a biological sample with the AFM according to the present embodiment will be described with reference to the flowchart of FIG. First, after the rubber gloves 35, 36 are pulled out, the operation openings 20, 21 are closed by the shutters 37, 38, and the valve 33 is closed (step S1). Then, the valves 43 and 47 are opened, and the air in the main chamber 14 is discharged from the gas discharge port 39 by the vacuum pumps 40 and 41 (step S2). As a result, the air containing pollutants is discharged from the inside of the main chamber 14. After the air in the main chamber 14 is sufficiently exhausted, the valve 47
Is closed, the valve 46 to the gas cylinder 49 is opened, and a predetermined atmosphere gas is introduced into the main chamber 14 (step S3). When the gas pressure in the main chamber 14 reaches a predetermined value (the gas pressure in the main chamber 14 is detected by the pressure sensor 34), the valve 46 is closed.
In this way, the atmosphere in the main chamber 14 is completely replaced with the clean gas from the contaminated air. Here, when observing a biological sample, it is preferable to use a mixed gas of an inert gas (argon gas, helium gas, or the like; nitrogen gas may be used) and water vapor at 1 atm as a new gas atmosphere. desirable. Of course, when observing another type of sample, the gas can be replaced with an arbitrary gas simply by replacing the gas cylinder 49, and the pressure can be set to an arbitrary value.

The sample to be observed is first placed in the sample chamber 31 (step S4). This sample chamber 31
The air inside is the same as in the case of the main chamber 14 described above.
By operating the valves 45, 47, 46 and the like, the atmosphere gas is replaced with a new one (step S5). On the other hand, even in the space between the rubber gloves 35 and 36 and the shutters 37 and 38 at both the operation openings 20 and 21, a small amount of contaminated air remains.
4, 47 and 46 are operated to replace the atmosphere gas with a new one (step S6).

After the contaminated air in the main chamber 14 and its surrounding space has been replaced with a clean atmosphere gas in this way, the valve 33 is opened and the sample is removed from the main chamber 1.
4 (step S7). And both operation openings 2
The shutters 37 and 38 of 0 and 21 are opened, and the operator puts his hand on the rubber gloves 35 and 36 and sets the sample at a predetermined position on the sample table (step S8). At this time, since the inside of the main chamber 14 can be seen through the transparent windows 17 and 18 obliquely above and in the front, the operator can surely perform fine work. After the sample setting is completed in this way, AFM observation is performed under the control of the control unit 11 as described above (step S9).

In the above embodiment, an atomic force microscope (AFM)
However, the present invention can be similarly applied to a scanning tunneling microscope (STM). In that case, the sample station shown in FIG. 2A is simply changed to a station dedicated to the STM as shown in FIG. 2B, and the sample setting mechanism shown in FIG. The same gas system can be used. In the STM sample station 73 shown in FIG. 2B, 74 is a sample table, 75 is an anti-vibration table, 76 is a piezo driver for moving a probe (tip), 77 is a probe (tip), and 78 is a coarse driver. It is a micrometer for movement.
Similarly, the present invention can be applied to other probe scanning microscopes such as the laser force microscope (LFM) and the magnetic force microscope (MFM) described above.

FIG. 6 shows an AFM which is another embodiment of the present invention. In the AFM of this embodiment, the main chamber 114 is composed of a base 151 and a glass case 150 hermetically fixed on the base 151, and an opening for putting rubber gloves 135, 136 for manipulating the sample into the main chamber 114. Are provided on the base portion 151. In the gas system, an exhaust pipe 153 for discharging gas from the main chamber 114 and an introduction pipe 154 for introducing another gas are provided.
And are provided separately. The other components are the same as those given the same lower two digits shown in FIGS.

FIG. 7 shows an AFM according to still another embodiment of the present invention. If the sample is one that will not be deformed by being temporarily placed in a vacuum, first place the sample in the main chamber 2
It can be set in the sample station 223 inside the chamber 14 and then the main chamber 214 can be closed to replace the contaminated air inside with a clean atmospheric gas. In this case, since it is not necessary to put a hand in the main chamber 214 or look inside, the structure of the main chamber 214 can be simplified as shown in FIG. Figure 7
, The other components are the same as those given the same lower two digits shown in FIGS. 1 to 4.

[0021]

As described above, the sample can be observed under any kind of atmospheric gas of any pressure in any probe scanning microscope (SPM). In particular, when observing a biological sample, the atmosphere containing pollutants is first excluded from the sample observing chamber, and the sample observing chamber is adjusted to 1 atm with a clean inert gas (and water vapor) instead. It is possible to observe the correct (under atmospheric pressure) surface morphology of the sample without deformation or agglomeration.

[Brief description of drawings]

FIG. 1 is a front view of an atmosphere control atomic force microscope (AFM) according to an embodiment of the present invention.

FIG. 2 is a vertical cross-sectional view of the main chamber of the AFM according to the embodiment.

FIG. 3 is a cross-sectional view of the main chamber.

FIG. 4 is a gas system diagram of the AFM of the embodiment.

FIG. 5 is a flowchart illustrating a procedure for observing a biological sample with the AFM according to the embodiment.

FIG. 6 is a schematic configuration diagram of an AFM according to another embodiment of the present invention.

FIG. 7 is a schematic configuration diagram of an AFM according to still another embodiment of the present invention.

[Explanation of symbols]

 10 ... Observation part 11 ... Control part 12 ... Console part 14 ... Main chamber 17, 18 ... Perspective window 20, 21 ... Operation opening 23 ... Sample station 24 ... Sample 25 ... Piezo driver 26 ... Cantilever 27 ... Laser 30 ... Sample introduction pipe 31 ... Sample chamber 32, 33 ... Valve 34 ... Pressure sensor 35, 36 ... Rubber gloves 37, 38 ... Shutter 39 ... Gas outlet 40 ... Turbo molecular pump 41 ... Rotary pump 42 ... Pipe 43, 44, 45, 46, 47 … Valve 48… Cylinder mounting terminal 49… Atmosphere gas cylinder

Claims (1)

[Claims] 1. A sample observation chamber which is a) airtightly provided; b) a probe which is provided so that its tip is close to the surface of the sample in the sample observation chamber; and c) the tip of the probe is the sample surface. Probe moving means for three-dimensionally driving the probe or the sample so as to move along the path, d) gas discharging means for discharging the gas in the sample observation chamber, and e) introducing an inert gas into the sample observation chamber. And a gas introducing means for observing the sample in the presence of an inert gas.