DE102017007578A1 - Method and device for determining the electrical resistance of an object - Google Patents

Abstract

According to the invention, the method for measuring the electrical resistance of an object in which at least four measuring contacts are brought into electrically conductive contact with the surface of the object, at least four measuring contacts, measuring contacts for applying a current (2, 2a ) and at least two measuring contacts, measuring contacts for voltage measurement (3, 3a), wherein in the object with at least one measuring contacts for applying a current (2, 2a), a current is injected and at least one measuring contact for applying a current is derived, and on the object with the at least two measuring contacts for voltage measurement (3, 3a) is measured in each case a voltage, wherein at each measuring contact for voltage measurement, a measuring electronics is connected, the current through the contact between the measuring contact for measuring voltage ( 3, 3a) and the object flows, wherein the current between the measuring contact for voltage measurement (3, 3a) and the object, by applying a bias voltage is regulated so that it no longer flows and thus the bias voltage equal to the voltage of the object at the location of the measuring contact for measuring voltage. The resistance of the object is calculated from the measured values for current and voltage according to Ohm's law.

Description

The invention relates to a method and a device for determining the electrical resistance of an object.

In many technical fields, there is a need to measure the electrical resistance of objects.
According to the prior art, a resistance measurement is carried out by the object to be measured is contacted via two probe tips with electrical lead wires. In the following, a distinction is made between the object to be measured, the electrical leads which connect the object to the measuring devices for electric current or voltage and the measuring contacts, which establish the electrical contact to the object. In general, an object can be contacted at various locations, resulting in different electrical resistances. Thus, the way and the exact positions of the contact determine the measured resistance. Thus, strictly speaking, one can not speak of the resistance of the object, but only of the resistance of an object with a certain contact.
In some cases, the object to be measured already has electrical connections, as is the case with a resistor known as an electronic component with two supply wires, or with an electronic circuit board.
In a two-point measurement, two electrical lead wires are subjected to a voltage difference, V, and the current flowing through the lead wires, I, is measured. The electrical resistance, R, of the object with the specific contacting results from the ohmic formula to R = U / I.

A known problem in the two-point measurement described above is that contact resistances and resistances in the lead wires falsify the resistance measurement because it is not the resistance of the object but the resistance of the object plus contact resistance plus resistances in the lead wires that is measured. To overcome this problem, the prior art uses e.g. used the four-point measurement or four-wire measurement. This method is shown for example on the Wikipedia page https://de.wikipedia.org/wiki/Vierleitermessung. In the case of the four-wire measuring arrangement, an electrical current flows through two measuring contacts for current injection through the object to be measured, which is measured using an ammeter. The voltage dropped across the object is tapped via two additional voltage measuring contacts and measured with a voltage measuring device with high internal resistance. The resistance to be measured is calculated according to Ohm's law from the measured quantities and is known to be largely independent of the contact resistances of the contacts used for voltage measurement in the case of four-point measurement.

The four-wire measurement is also used in semiconductor technology and for determining the surface resistance of thin layers. This method is described in Wikipedia on the page https://de.wikipedia.org/wiki/Vier-Punkt-Methode.
For performing the four-wire measurement with micron-to-nanometer contact distances, multi-point scanning tunneling microscopy can be used to determine resistances of surfaces, films, and nanostructures with the four-point method.

These measurements are performed, in particular, in various contact configurations by exchanging current-injecting measuring contacts, which are designed as tips, and with chip-measuring tips and various geometric arrangements of the contacts, for example by changing the spacing between the tips or rotating squared tips.
At the nanoscale, the contacting of objects, the placement of tips on surfaces or nanostructures means a modification or damage on the nano- or atomic level, equivalent to an invasive contact.
In scanning tunneling microscopy, the tips are usually positioned about 0.5 nm above the surface, which is equivalent to a non-invasive tunneling contact, wherein current measurements are performed.

The method of four-point measurement in multi-peak scanning tunneling microscopy is described, for example, in the paper by R. Hobara, N. Nagamura, S. Hasegawa, I. Matsuda, Y. Yamamoto, Y. Miyatake and T. Nagamura in REWIEW OF SCIENTIFIC INSTRUMENTS 78, 053705 (2007). In this publication, an invasive voltage measurement with a high-impedance operational amplifier, which is connected as a voltage follower, realized.
This is in this publication and in the text on page 3 in the chapter: "Extend the Z piezoactuators by a preset amount, and make direct contacts between tips and sample." Described.

In a publication of T. Druga et. al. (T. Druga, M. Wenderoth, J. Homoth, MA Schneider, and G. Ulbrich) Review of Scientific Instruments 81, 083704 (2010) ) describes a method of voltage measurement in which the voltage applied to a tip of the scanning tunneling microscope is varied or regulated until the current between the tip and the sample disappears. This voltage is then equal to the voltage of the sample at the point of the tip.

There are some disadvantages associated with the prior art processes. Despite the four-point measurement, the measurement of the voltage difference is carried out with a voltmeter with finite internal resistance. For example, Hobara et. al. the voltage measurement by a high-impedance operational amplifier, which is connected as a voltage follower realized, which corresponds to a voltmeter with finite internal resistance, which distorts the voltage measurement. Performing the measurements is expensive because both a current source including a current measurement, as well as a voltage measurement is needed. Occasionally, contacts used in a current injection measurement are used in a further measurement as contacts for voltage measurement. This swapping of the contacts is detrimental to fast measurements with different contact configurations.

Measurements with non-invasive contact are very difficult because it is always necessary to switch between voltage measurement and scanning tunneling microscope operation. The voltage measurement may only be performed for a few msec, otherwise the distance between the tip and the sample will vary during the measurement due to the thermal drift at room temperature in the order of magnitude of the tunneling distance of approximately 0.5 nm. Thereafter, it must be switched back to current measurement with grid tunnel operation to correct the tunnel distance.

Therefore, it is the object of the invention to overcome the disadvantages mentioned. In particular, systematic errors in the resistance measurement should be minimized or prevented. The voltage measurement should be independent of the contact resistance and the resistances in the supply wires. The design of the electronics and the exchange of contacts should be simplified and the non-invasive measurement should be simplified. The distance between the sample and the measuring tip should preferably be kept constant. The noise of the measuring signals should be reduced.

Starting from the preamble of claim 1 and the independent claim, the object is achieved by the features specified in the characterizing part of the claims.

With the method and the device according to the invention, it is now possible to minimize or prevent systematic measurement errors in the four-point measurement. The voltage measurement is independent of the contact resistance and of the resistances in the supply wires. The structure of the electronics and the swapping of contacts as well as the non-invasive measurement are simplified. The distance between the sample and the measuring contact can be kept constant. Smoother measurements can be performed.

Advantageous developments of the invention are specified in the subclaims.

In the following, the invention is described in its general form without this having to be construed restrictively.

First, some terms are defined.

Measuring contact for applying a current:

Electrically conductive object which injects or dissipates electricity at the contact point to the object to be examined.

Measuring contact for voltage measurement:

Electrically conductive object, via which the voltage of the object to be examined is measured at the contact point.

Measuring contact:

Generic term for the measuring contact for the voltage measurement and the measuring contact for the application of a current.

Measuring electronics:

The measuring electronics is a means for injecting a current and measuring an electric current when it is connected to the measuring contact for applying a current, and a means for measuring the electrical voltage when it is connected to the measuring contact for the voltage measurement.

Loop:

Control that regulates the voltage of a measuring contact for voltage measurement so that no current flows through the measuring contact.

According to the invention, the resistance of a sample is determined with a multi-point measurement, in which at least four measuring contacts are used, of which at least two serve to load a current and at least two for voltage measurement.

The object to be examined, or sample, hereinafter referred to as an object, may be any material designed to conduct a current. These may be any conductive materials such as metals, alloys, semiconductors, organic compounds or be earthy materials. Furthermore, the object to be measured can consist of a composition of different materials, in particular of the type mentioned above.

The object to be examined may be macroscopic, for example, the bottom of a terrain or even a smaller piece of material, at which the resistance for the smallest distances from measuring contacts to be measured.

The measuring contacts can be any material which is preferably rod-shaped depending on the application and / or the shape has a tip or a spherical apex, so that they have the ability to allow a flow of current. For example, the measuring contact may be made of metal, for example steel, copper or tungsten or of a semiconductor, for example silicon, or doped diamond, or other types of carbon, e.g. Carbon nanotubes.

Depending on the sample to be examined, a measuring contact can be dimensioned differently. Measurements in a terrain or a large-scale object can be massive rods, in the microscopic area around needles or tips of a scanning probe microscope, ie a scanning tunneling microscope, an atomic force microscope or other types of scanning probe microscopes.

According to the invention, at least four measuring contacts are used. However, the maximum number of measuring contacts is freely selectable and is limited only by practical conditions to upper values. For example, 5, 6, 7, 8, ... 10, ... 20, 30 or more measuring contacts can be used.

According to the invention, at least two measuring contacts for applying current are provided by these measuring contacts, and at least two measuring contacts are provided for measuring the voltage.

Of these at least two measuring contacts for the application of electricity, at least one measuring contact for the application of current injects a current and at least one measuring contact for the application of current conducts the current. With more than two measuring contacts for the application of electricity, the numerical distribution of the measuring contacts for the application of electricity, which inject a current and measuring contacts for the application of electricity, which derive the current freely selectable. Thus, the division may be half or have a different number ratio.

With more than four measuring contacts, the numerical distribution of the other measuring contacts for applying current and measuring contacts for voltage measurement is freely selectable. Thus, the division may be half or have a different number ratio.

The choice of the spatial distribution of measuring contacts for the application of current and measuring contacts for voltage measurement on the object to be examined is also freely selectable.

The measuring contacts for the application of current need not differ structurally and materially from the measuring contacts for voltage measurement, but they can. If the measuring contacts are structurally and / or materially designed to be charged with current and the voltage measurement, this has the consequence that their function can be easily reversed.
Which of the measuring contacts is used for the application of current or for voltage measurement can be controlled by a software without the need for a change of the apparatus construction. As a result, changes in the experimental setup and the implementation of the measurement method can be simplified. Relay switching is eliminated. Likewise, the replacement of the function of measuring contacts can be brought about manually.

According to the invention, the current is measured at each measurement contact for the voltage measurement.
For this purpose, each measuring contact for the voltage measurement is connected to a measuring electronics. This measuring electronics is an electronic system which applies a voltage to the measuring contact and measures the current flowing through the contact. These electronic elements are known in the art. By way of example, but not by way of limitation, a transimpedance converter which is subjected to a bias voltage can be mentioned here as an example of a measuring electronics. As other equivalent means may be mentioned ammeters, which are biased.

At the measuring contacts for the application of a current, a current is injected into or derived from the object to be measured.

At the measuring contacts for the application of current, a current is injected or discharged into the object to be measured. The types of measuring electronics used for this purpose are known to the person skilled in the art. By way of example but not limitation, a constant current source can be mentioned here as an example of a measuring electronics. As other equivalent means may be mentioned a transimpedance converter or ammeter, to each of which a bias voltage is applied. With these Electronics can also measure the injected current. As a simple power dissipation can also serve a direct wire connection to the ground, without current measurement.

According to the invention, each measuring contact for measuring voltage is connected to a measuring electronics, which applies a voltage to each measuring contact for the voltage measurement and measures the current flowing through the contact.

The measurement electronics of the measurement contacts provided for current must not differ from the measuring electronics of the measuring contacts for voltage measurement, but it can. If the measurement electronics of the measuring contacts for structuring current and the voltage measurement structurally the same, this has the consequence that their function can be easily reversed. In this case, it is possible to control by a software which of the measuring contacts is used for the application of current or for voltage measurement, without the need for a change in the construction of the apparatus. As a result, changes in the experimental setup and the implementation of the measurement method can be simplified. Relay switching is eliminated. Likewise, the replacement of the function of measuring contacts can be brought about manually.

According to the invention, the current flowing through each of the measuring contacts for the voltage measurement to the sample is controlled by the application of a bias voltage so that the current through these measuring contacts for the voltage measurement is equal to zero, or no more current flows. Then, the voltage of the object at the location of the contact for voltage measurement is equal to the applied bias voltage.
This can be done manually or by means of an automatic control.
In this case, in the case of a measuring contact for the voltage measurement via a control loop which is controlled by a software, the applied voltage will be adjusted so that no more current flows through this voltage measuring contact. The voltage then applied is the voltage of the object at the point of contact.
These embodiments of a control loop are known to the person skilled in the art.
By way of example but not limitation, proportional-integral control circuits can be mentioned here. As other equivalent means voltage sources can be mentioned.

Alternatively, a current of 0 amperes can be induced between the measuring contacts for the voltage measurement and the object to be examined by manually regulating the current.

In a preferred embodiment in multi-peak scanning probe microscopy, the determination of the resistance is non-invasive.

For this purpose, the distance of the measuring contact to the surface of the object to be examined is kept constant. This is particularly relevant in the scanning probe microscopic measurement.

In the case of multi-point scanning probe microscopy, a non-invasive current injection can be realized in which the measuring contacts for directing current and / or measuring contacts for voltage measurement have no direct contact with the sample, but are at a distance which, for example, corresponds to a tunnel contact of approx , 5 nm corresponds. For this purpose, various methods are known in the art.

In this case, for non-invasive measurements on the measuring contacts, the voltage measurement can be carried out in a time-varying manner with the voltage regulation, regulating the distance between tip and sample, in particular in scanning probe microscope operation. This can be used for any non-invasive voltage measuring contact.

For non-invasive measurements on the measuring contacts for the application of current, a regulation for the distance between the tip and the sample, in particular in Scanning Probe Microscope operation, can be carried out alternating with the current measurement of the measuring electronics at the measuring contacts for the application of current. This can be used for any non-invasive current injection contact.

An embodiment is preferred in which both the measuring contact for the application of current and the measuring contact for the voltage measurement are operated non-invasively.

In one embodiment, the measurement signal used in Scanning Probe Microscopy for peak-to-sample pitch control is alternately time-timed with voltage regulation that regulates the current to 0 amps to determine the voltage at the contact. The distance measurement signal may be any signal that allows determination of the distance of the tip of the measurement contact from the sample. For example, when using an atomic force microscope, the measured force between tip and sample, or in dynamic atomic force microscopy, the frequency shift or the amplitude of the oscillating scanning force microscope sensor. For a scanning tunneling microscope, it may be the measured tunneling current.

If the peak-to-sample separation does not remain constant over the measurement period due to drift, peak-to-sample separation can be alternated with current injection for each noninvasive current contact probe.

The determination of the resistance takes place from the measured quantities according to Ohm's law.

For measurements with more than two measuring contacts for the application of current and / or two measuring contacts for voltage measurement, the resistance of the sample results using mathematical models, which sets the measured values in relation to Ohm's law.

In an alternative embodiment, the distance between the measuring tip and the sample and the current flowing through the tip are measured at the same time instead of alternately. For this purpose, two different measuring signals are needed, one for determining the distance of the measuring tip to the sample and one for measuring the current through the tip.

For example, the force interactions between the measuring tip and the sample can be measured by means of an atomic force microscope in order to determine and regulate the distance of the measuring contact and to measure the current at the same time.

With the method according to the invention, the measured voltages are independent of contact resistances and resistances in supply lines. For contact resistances less than -10 MOhm, the noise of the voltage measurement is given only by the Johnson resistance noise of the contact resistance between the probe tip and the object to be measured.

Compared to the use of a voltage follower according to the prior art, this does not give a lower limit of the noise due to the inherent noise of the voltage follower used.

For the voltage measurement and the application of current are constructed identically with measuring electronics for measuring the current under application of a bias voltage. If measuring contacts and / or measuring electronics are constructed identically, it is possible to interchange the tasks of the measuring tips with the function of current injection or voltage measurement by means of a software without switching relays. Compared to the prior art, the electronics required for such measurements, by eliminating the circuits which had the measurement of voltage in previous implementations, are less expensive and thus less susceptible to disturbances such as noise. Non-invasive measurements are simplified.

The performance of the method according to the invention is provided by a device according to the invention, which is described below and is not intended to be restrictive.

According to the invention, the device has at least four measuring contacts. However, the maximum number of measuring contacts is freely selectable and is limited only by practical conditions to upper values. For example, 5, 6, 7, 8, ... 10, ... 20, 30 or more measuring contacts may be present.

According to the invention, at least two measuring contacts for applying current and at least two measuring contacts for voltage measurement are provided by these measuring contacts.

If there are more than two measuring contacts, the numerical distribution of the measuring contacts for the application of current in contacts, which inject electricity or discharge current, is freely selectable. Thus, the division may be half or have a different number ratio. Thus, the division may be half or have a different number ratio.

With more than four measuring contacts, the numerical distribution of the other measuring contacts for applying current and measuring contacts for voltage measurement is freely selectable. Thus, the division may be half or have a different number ratio.

The measuring contacts can be any material which, depending on the application, is preferably rod-shaped and / or has the shape of a point or a spherical apex, so that a flow of current is made possible. For example, the measuring contact can be made of metal, for example steel, copper or tungsten or of a semiconductor, for example silicon, or doped diamond, or other types of carbon, e.g. Carbon nanotubes.

Depending on the object to be examined, a measuring contact can be dimensioned differently. Measurements in a terrain or a large-scale object can be massive rods, in the microscopic area around needles or tips of a scanning probe microscope, ie a scanning tunneling microscope, an atomic force microscope, or other types of scanning probe microscopes.

According to the invention, means for measuring a current, to which a bias voltage is applied, are in the form of measuring electronics at all measuring contacts, for voltage measuring contacts. These agents are known to the person skilled in the art. By way of example but not limitation, transimpedance transducers biased may be cited. As an alternative means amperemeter with bias voltage can be attached to the measuring contacts. For this purpose, the measuring electronics have means for applying a bias voltage. For this purpose, all known means for applying a bias into consideration. These may be a simple wire or, by way of example but not limitation, a circuit that will shift the potentials.

The outputs of the measuring electronics lead to a computer, which processes the signals, or to an analog or digital measuring and control device.

In the case of the measuring contacts for the voltage measurement, the output of the measuring electronics is connected to a control circuit which is preferably located in the computer and which regulates the current so that it is zero at the tip-probe contact.

The technical versions of a control loop are known to the person skilled in the art. By way of example but not limitation, proportional-integral control circuits can be mentioned here. Voltage sources may be mentioned as other equivalent means. Furthermore, the measuring contacts may be tips of a scanning probe microscope, which may be part of a multi-tip scanning probe microscope.

In a preferred embodiment, the device then has means for keeping constant the distance of the tips to the surface of the object to be examined.

In the following figures are described, in which an embodiment of the invention is shown.

• 1: Einen schematischen Aufbau der erfindungsgemäßen Vorrichtung
• 2 Einen Transimpedanzwandler mit Mitteln zum Anlegen einer Vorspannung
• 3 Einen Transimpedanzwandler mit Mitteln zum Anlegen einer Vorspannung und Regelkreis für einen Messkontakt zur Spannungsmessung
• 4: Einen detaillierten schematischen Aufbau der erfindungsgemäßen Vorrichtung

It shows:

• 1 : A schematic structure of the device according to the invention
• 2 A transimpedance converter with means for applying a bias voltage
• 3 A transimpedance converter with means for applying a bias voltage and control circuit for a measuring contact for voltage measurement
• 4 : A detailed schematic structure of the device according to the invention

In 1 is a sample 1 represented, on which two measuring contacts for the application of electricity 2 . 2a and two measuring contacts for voltage measurement 3 . 3a are positioned. To the measuring contacts for the application of current 2 . 2a and the measuring contacts for voltage measurement 3 . 3a is each a measuring electronics 4 . 5 . 6 and 7 connected. These measuring electronics that measure the current 4 . 5 . 6 and 7 are with a computer 8th connected, which evaluates the signals. In the case of the measuring contacts for the voltage measurement are in the computer for each measuring contact for voltage measurement 6 . 7 control loops 9 . 9a , which measures the current between the object to be examined 1 and the measuring contact for voltage measurement 3 . 3a to zero amps.

2 shows a transimpedance transducer with bias. A line 10 is with the op amp 11 connected to its inverting input "-". The exit 12 of the operational amplifier 11 flows into a line 13 that have a resistance 14 in the stream entrance 10 returns. From the exit 12 of the operational amplifier 11 joins another line 15 out. To the non-inverting input "+" of the operational amplifier 11 is a lead 16 connected. The entrance 10 is connected to the measuring contact. The voltage applied to the measuring contact bias is due to the line 16 applied voltage. The resulting current through the measuring contact is using the operational amplifier 11 converted into a current proportional to the output voltage, which on the line 15 is tapped. This is read into the software with an analog-to-digital converter.

In 3 the same device features have the same reference numerals. In addition, the output is 12 and the line 15 to a control loop 9 connected, which regulates the current at the measuring contacts for voltage measurement to zero amps. The bias, which is on the line 16 is applied, is varied by the control loop so that the voltage which line 15 is tapped and thus the current through the line 10 and thus the measuring contact, disappears. In this case, the line is on 16 applied voltage identical to the voltage of the object to be measured 1 at the position of the measuring contact for the voltage measurement 3 . 3a which is at the entrance 10 connected.

In 4 the same device features have the same reference numerals as in the previous figures.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited non-patent literature

• T. Druga et. al. (T. Druga, M. Wenderoth, J. Homoth, M. A. Schneider, and G. Ulbrich) Review of Scientific Instruments 81, 083704 (2010) [0007]

Claims (22)

Method for determining the electrical resistance of an object, in which at least four measuring contacts are brought into electrically conductive contact with the surface of the object, of which at least four electrically conductive measuring contacts at least two measuring contacts, measuring contacts for acting on a current (2, 2a) and at least two measuring contacts, measuring contact for voltage measurement (3, 3a), wherein in the object with at least one measuring contact for applying a current (2, 2a), a current is injected and at least one measuring contact for applying a current is derived , characterized in that on the object with the at least two measuring contacts for voltage measurement (3, 3a) each a voltage is measured, wherein at each measuring contact for measuring voltage measuring electronics is connected, the current through the contact between the measuring contact for voltage measurement (3, 3a) and the object flows , wherein the current between the measuring contact for voltage measurement (3, 3a) and the object by applying a bias voltage to the measuring contact (3, 3a) is regulated so that it no longer flows and thus the bias voltage equal to the voltage of the object at the location of the measuring contact for measuring voltage is .. Method according to Claim 1 , characterized in that the measuring contacts are used, which are rod-shaped and / or have the shape of a tip or a spherical apex. Method according to one of Claims 1 or 2 , characterized in that measuring contacts made of a metal, steel, copper or tungsten or a semiconductor, silicon, doped diamond or carbon nanotubes are used. Method according to one of Claims 1 to 3 , characterized in that 4 to 30 measuring contacts are used. Method according to one of Claims 1 to 4 , characterized in that the number of measuring contacts for applying current (2, 2a) and the number of measuring contacts for voltage measurement (3, 3a) is the same. Method according to one of Claims 1 to 5 , characterized in that tips of a scanning probe microscope are used as measuring contacts. Method according to Claim 6 , characterized in that the measurement is carried out non-invasively. Method according to Claim 7 , characterized in that for the non-invasive measurement of the voltage at the measuring contacts for voltage measurement (3, 3a), a control for the distance between the tip of the scanning probe microscope and the object is performed alternately in time with the voltage control. Method according to one of Claims 7 or 8th , characterized in that for the non-invasive loading of a current at the measuring contacts for applying current (2, 2a), a regulation for the distance between the tip of the scanning probe microscope and the object is carried out alternately in time with the application of current for the purpose of current injection , Method according to one of Claims 7 to 9 , characterized in that the distance between the measuring contacts for applying current (2, 2a), a control for the distance between the tip of the scanning tunneling microscope and the object is carried out simultaneously with the current injection. Method according to one of Claims 7 to 9 , characterized in that the distance between the measuring contacts for voltage measurement (3, 3a) a control for the distance between the tip of the scanning tunneling microscope and the object is performed simultaneously with the voltage measurement. Method according to one of Claims 7 to 11 , characterized in that the distance between the measuring contacts for applying current (2, 2a) and the voltage measurement (3, 3a) to the object simultaneously by two different measuring signals for determining the distance of the measuring contacts and for measuring the current or the measurement the voltage is measured. Method according to one of Claims 7 to 12 , characterized in that the distance between the measuring contacts and the object is set in the order of a tunnel contact. Apparatus for carrying out the method according to one of Claims 1 to 12 with at least four measuring contacts, characterized in that it has at least two measuring contacts for a current injection (2, 2a) and two measuring contacts for a voltage measurement (3, 3a) which are each connected to a measuring electronics and that the measuring contacts for voltage measurement (3, 3a) are connected to a control which regulates the current to zero amps. Device after Claim 13 , characterized in that the measuring electronics is a transimpedance converter with means for applying a bias voltage or an ammeter with means for applying a bias voltage. Device according to one of Claims 13 or 14 , characterized in that the measuring contacts consist of electrically conductive material. Device after Claim 15 characterized in that the electrical material is a component selected from the group consisting of metal, copper, steel, tungsten, semiconductor silicon, doped diamond and carbon nanotubes. Device according to one of Claims 13 to 16 , characterized in that it has between 4 and 30 measuring contacts. Device after Claim 17 , characterized in that the number of measuring contacts for current injection (2, 2a) and the number of measuring contacts for voltage measurement (3, 3a) is the same. Device according to one of Claims 13 to 18 , characterized in that the measuring contacts are rod-shaped and / or have the shape of a tip or a spherical apex. Device according to one of Claims 13 to 19 , characterized in that the measuring contacts are tips of a scanning probe microscope. Device after Claim 20 , characterized in that it has means for keeping constant the distance of the tips of the scanning probe microscope from the object to be examined.

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