Abstract: A method for determining a three-dimensional atomic distribution of a sample having a tip, during an atom probe tomography process. The method accounts for the tip not being axial symmetric and not having a hemispherical shaped apex throughout the evaporation process.

Abstract: Example embodiments relate to methods and apparatuses for aligning a probe for scanning probe microscopy (SPM) to the tip of a pointed sample. One embodiments includes a method for aligning an SPM probe to an apex area of a free-standing tip of a pointed sample. The method includes providing an SPM apparatus that includes the SPM probe; a sample holder; a drive mechanism; and detection, control, and representation tools for acquiring and representing an image of a surface scanned by the SPM probe. The method also includes mounting the sample on the sample holder. Further, the method includes positioning the probe tip of the SPM, determining a 2-dimensional area that includes the pointed sample, performing an SPM acquisition scan, evaluating and acquired image, and placing the SPM probe in a position where it is aligned with an apex area of the free-standing tip of the pointed sample.

Abstract: Example embodiments relate to methods and apparatuses for aligning a probe for scanning probe microscopy (SPM) to the tip of a pointed sample. One embodiments includes a method for aligning an SPM probe to an apex area of a free-standing tip of a pointed sample. The method includes providing an SPM apparatus that includes the SPM probe; a sample holder; a drive mechanism; and detection, control, and representation tools for acquiring and representing an image of a surface scanned by the SPM probe. The method also includes mounting the sample on the sample holder. Further, the method includes positioning the probe tip of the SPM, determining a 2-dimensional area that includes the pointed sample, performing an SPM acquisition scan, evaluating and acquired image, and placing the SPM probe in a position where it is aligned with an apex area of the free-standing tip of the pointed sample.

Abstract: A device is provided for electrically measuring surface characteristics of a sample. The device comprises at least one group of three electrodes: a first and second electrode spaced apart from each other and configured to be placed onto the surface of the sample, and a third electrode between the first two but isolated from these two electrodes by a one or more first insulators, wherein a second insulator further isolates the central electrode from the sample when the device is placed thereon. The three electrodes and the insulators are attached to a single or to multiple holders with conductors incorporated therein for allowing the coupling of the electrodes to power sources or measurement tools. The placement of the device onto a semiconductor sample creates a transistor with the sample surface acting as the channel. The device thereby allows the determination of the transistor characteristics of the sample in a straightforward way.

Abstract: The disclosed technology relates to a method and apparatus for correctly positioning a probe suitable for scanning probe microscopy (SPM). The probe is positioned relative to the apex region of a needle-shaped sample, such as a sample for atom probe tomography, in order to perform a SPM acquisition of the apex region to obtain an image of the region. In one aspect, the positioning takes place by an iterative process, starting from a position wherein one side plane of the pyramid-shaped SPM probe interacts with the sample tip. By controlled consecutive scans in two orthogonal directions, the SPM probe tip approaches and finally reaches a position wherein a tip area of the probe interacts with the sample tip's apex region.

Abstract: A device is provided for electrically measuring surface characteristics of a sample. The device comprises at least one group of three electrodes: a first and second electrode spaced apart from each other and configured to be placed onto the surface of the sample, and a third electrode between the first two but isolated from these two electrodes by a one or more first insulators, wherein a second insulator further isolates the central electrode from the sample when the device is placed thereon. The three electrodes and the insulators are attached to a single or to multiple holders with conductors incorporated therein for allowing the coupling of the electrodes to power sources or measurement tools. The placement of the device onto a semiconductor sample creates a transistor with the sample surface acting as the channel. The device thereby allows the determination of the transistor characteristics of the sample in a straightforward way.

Abstract: The disclosure is related to a method and apparatus for transmission electron microscopy wherein a TEM specimen is subjected to at least one thinning step by scratching at least an area of the specimen with an SPM probe, and wherein the thinned area is subjected to an SPM acquisition step, using the same SPM probe or another probe.

Abstract: A method of characterizing a region in a sample under study, and related systems, is disclosed. In once aspect, the sample under study comprises a first region having first crystalline properties and a second region having second crystalline properties. The method comprises irradiating the sample under study with an electron beam, the average relative angle between the electron beam and the sample under study being selected so that a contribution in the backscattered or forward scattered signal of the first region is distinguishable from that of the second region. The method further comprises detecting the backscattered or forward scattered electrons, and deriving a characteristic of the first and/or the second region from the detected backscattered or forward scattered electrons. The instantaneous relative angle between the electron beam and the sample under study is modulated with a predetermined modulation frequency during the irradiating the sample under study with an electron beam.

Abstract: A method of measuring an electrical characteristic of a current path is disclosed. In one aspect, the method includes a probe for scanning spreading resistance microscopy (SSRM), a test sample contacted by the probe, a back contact on the test sample, a bias voltage source and a logarithmic SSRM amplifier, when a modulation at a predefined frequency is applied to either the contact force of the probe or to the bias voltage, the device comprising electronic circuitry for producing in real time a signal representative of the electrical characteristic, according to the formula lognA=±VSSRM±logn(dV)+Vmultiplier.

Abstract: The disclosed technology relates to a method and apparatus for correctly positioning a probe suitable for scanning probe microscopy (SPM). The probe is positioned relative to the apex region of a needle-shaped sample, such as a sample for atom probe tomography, in order to perform a SPM acquisition of the apex region to obtain an image of the region. In one aspect, the positioning takes place by an iterative process, starting from a position wherein one side plane of the pyramid-shaped SPM probe interacts with the sample tip. By controlled consecutive scans in two orthogonal directions, the SPM probe tip approaches and finally reaches a position wherein a tip area of the probe interacts with the sample tip's apex region.

Abstract: A method of measuring an electrical characteristic of a current path is disclosed. In one aspect, the method includes a probe for scanning spreading resistance microscopy (SSRM), a test sample contacted by the probe, a back contact on the test sample, a bias voltage source and a logarithmic SSRM amplifier, when a modulation at a predefined frequency is applied to either the contact force of the probe or to the bias voltage, the device comprising electronic circuitry for producing in real time a signal representative of the electrical characteristic, according to the formula lognA=±VSSRM±logn(dV)+Vmultiplier.

Abstract: The disclosure is related to a method and apparatus for transmission electron microscopy wherein a TEM specimen is subjected to at least one thinning step by scratching at least an area of the specimen with an SPM probe, and wherein the thinned area is subjected to an SPM acquisition step, using the same SPM probe or another probe.

Abstract: The present disclosure is related to a method of fabricating a semiconductor device involving the production of at least two non-parallel nano-scaled structures on a substrate. These structures are heated to different temperatures by exposing them simultaneously to polarized light having a wavelength and polarization such that a difference in absorption of light occurs in the first and second nanostructure. In some cases the light is polarized in a plane that is parallel to one of the structures. The present disclosure may provide differential heating of semiconductor structures of different materials, such as Ge and Si fins.

Abstract: The present disclosure is related to a method of fabricating a semiconductor device involving the production of at least two non-parallel nano-scaled structures on a substrate. These structures are heated to different temperatures by exposing them simultaneously to polarized light having a wavelength and polarization such that a difference in absorption of light occurs in the first and second nanostructure. In some cases the light is polarized in a plane that is parallel to one of the structures. The present disclosure may provide differential heating of semiconductor structures of different materials, such as Ge and Si fins.

Abstract: The disclosed technology relates generally to probe configurations, and more particularly to probe configurations and methods of making probe configurations that have a diamond body and a diamond layer covering at least an apex region of the diamond body. In one aspect, a method of fabricating a probe configuration includes forming a probe tip. Forming the probe tip includes providing a substrate and forming a recessed mold into the substrate on a first side of the substrate, wherein the recessed mold is shaped to form a probe body having an apex region. Forming the probe tip additionally includes forming a first diamond layer on the substrate on the first side, wherein forming the first diamond layer includes at least partially filling the recessed mold with the first diamond layer such that a probe body having an apex region is formed in the recessed mold.

Abstract: The disclosure is related to an SSRM method for measuring the local resistivity and carrier concentration of a conductive sample. The method includes contacting the conductive sample at one side with an AFM probe and at another side with a contact electrode, modulating, at a modulation frequency, the force applied to maintain physical contact between the AFM probe and the sample while preserving the physical contact between the AFM probe and the sample, thereby modulating at the modulation frequency the spreading resistance of the sample; measuring the current flowing through the sample between the AFM probe and the contact electrode; and deriving from the measured current the modulated spreading resistance. Deriving the modulated spreading resistance includes measuring the spreading current using a current-to-voltage amplifier, converting the voltage signal into a resistance signal, and filtering out from the resistance signal, the resistance amplitude at the modulation frequency.

Abstract: An apparatus (100) for performing atomic force microscopy is disclosed. The apparatus comprises an AFM measurement unit (102) configured to operate in a first controlled atmosphere (300) and a pretreatment unit (101) configured to operate in a second controlled atmosphere (400), the second controlled atmosphere being different from the first controlled atmosphere. The pretreatment unit is connected to the AFM measurement unit. In one embodiment, the second controlled atmosphere is a vacuum atmosphere, whereas the first controlled atmosphere includes at least an inert gas.

Abstract: The disclosed technology relates generally to probe configurations, and more particularly to probe configurations and methods of making probe configurations that have a diamond body and a diamond layer covering at least an apex region of the diamond body. In one aspect, a method of fabricating a probe configuration includes forming a probe tip. Forming the probe tip includes providing a substrate and forming a recessed mold into the substrate on a first side of the substrate, wherein the recessed mold is shaped to form a probe body having an apex region. Forming the probe tip additionally includes forming a first diamond layer on the substrate on the first side, wherein forming the first diamond layer includes at least partially filling the recessed mold with the first diamond layer such that a probe body having an apex region is formed in the recessed mold.

Abstract: A tunnel Field Effect Transistor is provided comprising an interface between a source and a channel, the source side of this interface being a layer of a first crystalline semiconductor material being substantially uniformly doped with a metal to the solubility level of the metal in the first crystalline material and the channel side of this interface being a layer of this first crystalline semiconductor material doped with this metal, the concentration decreasing towards the channel.

Abstract: A method and system for optically determining a substantially fully activated doping profile are disclosed. The substantially fully activated doping profile is characterized by a set of physical parameters. In one aspect, the method includes obtaining a sample comprising a fully activated doping profile and a reference, and obtaining photomodulated reflectance (PMOR) offset curve measurement data and DC reflectance measurement data for the sample including the fully activated doping profile and for the reference. The method also includes determining values for the set of physical parameters of the doping profile based on both the photomodulated reflectance offset curve measurements and the DC reflectance measurements.