Abstract: To measure the resistance area product of a high resistivity layer using a microscopic multi point probe, the high resistivity layer is sandwiched between two conducting layers. A plurality of electrode configurations/positions is used to perform three voltage or resistance measurements. An equivalent electric circuit model/three layer model is used to determine the resistance area product as a function of the three measurements.

Abstract: A probe for direct nano- and micro-scale electrical characterization of materials and semi conductor wafers. The probe comprises a probe body, a first cantilever extending from the probe body, and a first thermal detector extending from the probe body. The thermal detector is used to position the cantilever with respect to a test sample.

Abstract: To measure the resistance area product of a high resistivity layer using a microscopic multi point probe, the high resistivity layer is sandwiched between two conducting layers. A plurality of electrode configurations/positions is used to perform three voltage or resistance measurements. An equivalent electric circuit model/three layer model is used to determine the resistance area product as a function of the three measurements.

Abstract: The method may be used for measuring an electric property of a magnetic tunnel junction used in an embedded MRAM memory for example. The method uses a multi point probe with a plurality of probe tips for contacting a designated area of the test sample, which is electrically insulated from the part of the test sample which is to be tested. Electrically connections are placed underneath the magnetic tunnel junction and goes to the designated area.

Abstract: The present invention relates to a method of establishing specific electrode positions by providing a multi-point probe and a test sample. The method comprises the measuring or determining of a distance between two of the electrodes of the multi-point probe and establishing a resistance model representative of the test sample. The method further comprises the performing of at least three different sheet resistance measurements and establishing for each of the different sheet resistance measurement a corresponding predicted sheet resistance based on the resistance model. Thereafter the method comprises the establishment of a set of differences constituting the difference between each of the predicted sheet resistance and its corresponding measured sheet resistance, and deriving the specific electrode positions of the multi-point probe on the surface of the test sample by using the distance and performing a data fit by minimizing an error function constituting the sum of the set of differences.

Abstract: The method may be used for measuring an electric property of a magnetic tunnel junction used in an embedded MRAM memory for example. The method uses a multi point probe with a plurality of probe tips for contacting a designated area of the test sample, which is electrically insulated from the part of the test sample which is to be tested. Electrically connections are placed underneath the magnetic tunnel junction and goes to the designated area.

Abstract: A probe for direct nano- and micro-scale electrical characterization of materials and semi conductor wafers. The probe comprises a probe body, a first cantilever extending from the probe body, and a first thermal detector extending from the probe body. The thermal detector is used to position the cantilever with respect to a test sample.

Abstract: The present invention relates to a method of establishing specific electrode positions by providing a multi-point probe and a test sample. The method comprises the measuring or determining of a distance between two of the electrodes of the multi-point probe and establishing a resistance model representative of the test sample. The method further comprises the performing of at least three different sheet resistance measurements and establishing for each of the different sheet resistance measurement a corresponding predicted sheet resistance based on the resistance model. Thereafter the method comprises the establishment of a set of differences constituting the difference between each of the predicted sheet resistance and its corresponding measured sheet resistance, and deriving the specific electrode positions of the multi-point probe on the surface of the test sample by using the distance and performing a data fit by minimizing an error function constituting the sum of the set of differences.