Thermal probe (10) for a scanning thermal microscope (100), use, and process of manufacturing. The thermal probe (10) comprises a single-material (M1) thermal conducting body (12) consisting of a probe frame (14) ending in a probe tip (11). A bi-material (M1,M2) cantilever strip (13) is connected to the probe frame (14) in thermal communication with the probe tip (11). The cantilever strip (13) in unbended state lies in-plane (X,Z) with the probe tip (11). The cantilever strip (13) comprises layers of material (M1,M2) having different coefficients of thermal expansion configured to bend the cantilever strip (13) with respect to the single-material thermal conducting body (12) as a function of the heat exchange (H) between the probe tip (11) and the microscopic structure (2) for measuring heat exchange (H) with a sample interface (1) by means of measuring the bending of the cantilever strip (13).

Thermal probe (10) for a scanning thermal microscope (100), use, and process of manufacturing. The thermal probe (10) comprises a single-material (M1) thermal conducting body (12) consisting of a probe frame (14) ending in a probe tip (11). A bi-material (M1,M2) cantilever strip (13) is connected to the probe frame (14) in thermal communication with the probe tip (11). The cantilever strip (13) in unbended state lies in-plane (X,Z) with the probe tip (11). The cantilever strip (13) comprises layers of material (M1,M2) having different coefficients of thermal expansion configured to bend the cantilever strip (13) with respect to the single-material thermal conducting body (12) as a function of the heat exchange (H) between the probe tip (11) and the microscopic structure (2) for measuring heat exchange (H) with a sample interface (1) by means of measuring the bending of the cantilever strip (13).

Various examples are provided related to scanning tunneling thermometers and scanning tunneling microscopy (STM) techniques. In one example, a method includes simultaneously measuring conductance and thermopower of a nanostructure by toggling between: applying a time modulated voltage to a nanostructure disposed on an interconnect structure, the time modulated voltage applied at a probe tip positioned over the nanostructure, while measuring a resulting current at a contact of the interconnect structure; and applying a time modulated temperature signal to the nanostructure at the probe tip, while measuring current through a calibrated thermoresistor in series with the probe tip. In another example, a device includes an interconnect structure with connections to a first reservoir and a second reservoir; and a scanning tunneling probe in contact with a probe reservoir. Electrical measurements are simultaneously obtained for temperature and voltage applied to a nanostructure between the reservoirs.

A thermal probe and method for generating a thermal map (M) of a sample interface (1). A scanning thermal microscope (100) is provided having at least one or more probe tips (11,12). The probe tips (11,12) are scanned at a near-field distance (D1) over the sample interface (1). Heat flux data (H) is recorded as a function of a relative position (X,Y) of the probe tip (11) over the sample interface (1). The thermal map (M) is calculated from the recorded heat flux data (H) based on a spatially resolved heat flux profile (P) of the probe tip (11) at the sample interface (1). The heat flux profile (P) has a local maximum at a lateral distance (R) across the sample interface (1) with respect to an apex (11a) of the probe tip (11).

A thermal probe and method for generating a thermal map (M) of a sample interface (1). A scanning thermal microscope (100) is provided having at least one or more probe tips (11,12). The probe tips (11,12) are scanned at a near-field distance (D1) over the sample interface (1). Heat flux data (H) is recorded as a function of a relative position (X,Y) of the probe tip (11) over the sample interface (1). The thermal map (M) is calculated from the recorded heat flux data (H) based on a spatially resolved heat flux profile (P) of the probe tip (11) at the sample interface (1). The heat flux profile (P) has a local maximum at a lateral distance (R) across the sample interface (1) with respect to an apex (11a) of the probe tip (11).

The present disclosure provides a measuring method for measuring heat distribution of a specific space using an SThM probe, and a method and device for detecting a beam spot of a light source. The method according to an embodiment of the present disclosure is the measuring method for measuring heat distribution of a specific space, the measuring method includes: linearly moving a SThM probe that may measure a temperature change in the specific space; and calculating heat distribution of the specific space using continuous temperature change values obtained from the SThM probe during the moving step. According to the measuring method, and the method and device for detecting a beam spot of a light source, it is possible to map temperature distribution in a small space using a SThM probe and it is possible to accurately detect a beam spot using the temperature distribution.

The present disclosure provides a measuring method for measuring heat distribution of a specific space using an SThM probe, and a method and device for detecting a beam spot of a light source. The method according to an embodiment of the present disclosure is the measuring method for measuring heat distribution of a specific space, the measuring method includes: linearly moving a SThM probe that may measure a temperature change in the specific space; and calculating heat distribution of the specific space using continuous temperature change values obtained from the SThM probe during the moving step. According to the measuring method, and the method and device for detecting a beam spot of a light source, it is possible to map temperature distribution in a small space using a SThM probe and it is possible to accurately detect a beam spot using the temperature distribution.

Systems and Methods may be provided for performing chemical spectroscopy on samples from the scale of nanometers with surface sensitivity even on very thick samples.

Between a nitrogen-vacancy center and a support portion, a cut-off portion is provided that cuts off the nitrogen-vacancy center from the support portion.

A thermal probe and method for generating a thermal map (M) of a sample interface (1). A scanning thermal microscope (100) is provided having at least one or more probe tips (11,12). The probe tips (11,12) are scanned at a near-field distance (D1) over the sample interface (1). Heat flux data (H) is recorded as a function of a relative position (X,Y) of the probe tip (11) over the sample interface (1). The thermal map (M) is calculated from the recorded heat flux data (H) based on a spatially resolved heat flux profile (P) of the probe tip (11) at the sample interface (1). The heat flux profile (P) has a local maximum at a lateral distance (R) across the sample interface (1) with respect to an apex (11a) of the probe tip (11).