A quantum-dot-based measuring system is disclosed. The quantum-dot-based measuring system includes a laser to emit excitation light, an optical fiber probe including a tail end and a tapered tip, and the tapered tip of the optical fiber probe is attached with one or more quantum dots, and the excitation light is injected from the tail end of the optical fiber probe and emitted from the tapered tip to a sample to be detected, an objective lens to collect optical signal reflected by the sample and a spectrometer to receive the optical signal.

A quantum-dot-based measuring system is disclosed. The quantum-dot-based measuring system includes a laser to emit excitation light, an optical fiber probe including a tail end and a tapered tip, and the tapered tip of the optical fiber probe is attached with one or more quantum dots, and the excitation light is injected from the tail end of the optical fiber probe and emitted from the tapered tip to a sample to be detected, an objective lens to collect optical signal reflected by the sample and a spectrometer to receive the optical signal.

Provided is a probe configured to detect a near field, the probe including a probe substrate having a tip region at an end portion of the probe substrate, a width of the tip region being less than a width of a remaining region of the probe substrate, a first electrode and a second electrode disposed on a surface of the probe substrate, the first electrode and the second electrode being spaced apart from each other and extending from the tip region along the probe substrate, an emitter and a detector disposed between the first electrode and the second electrode, the emitter and the detector being spaced apart from each other in a direction in which the probe substrate extends, and being configured to be photo switched, and a reflector disposed above the emitter and the detector in the direction in which the probe substrate extends opposite to the tip region, and configured to reflect an electromagnetic wave emitted from the emitter.

Provided is a probe configured to detect a near field, the probe including a probe substrate having a tip region at an end portion of the probe substrate, a width of the tip region being less than a width of a remaining region of the probe substrate, a first electrode and a second electrode disposed on a surface of the probe substrate, the first electrode and the second electrode being spaced apart from each other and extending from the tip region along the probe substrate, an emitter and a detector disposed between the first electrode and the second electrode, the emitter and the detector being spaced apart from each other in a direction in which the probe substrate extends, and being configured to be photo switched, and a reflector disposed above the emitter and the detector in the direction in which the probe substrate extends opposite to the tip region, and configured to reflect an electromagnetic wave emitted from the emitter.

To enhance the measurement sensitivity of a scanning probe microscope. In a cross sectional view, a cantilever includes a vertex portion that is a portion close to a sample and is covered by a metallic film, a ridge that is connected to the vertex portion and is covered by the metallic film, and an upper corner portion that is connected to the ridge. Here, the upper corner portion and a part of the ridge are portions to be irradiated with excitation light emitted from a light source of the scanning probe microscope.

To enhance the measurement sensitivity of a scanning probe microscope. In a cross sectional view, a cantilever includes a vertex portion that is a portion close to a sample and is covered by a metallic film, a ridge that is connected to the vertex portion and is covered by the metallic film, and an upper corner portion that is connected to the ridge. Here, the upper corner portion and a part of the ridge are portions to be irradiated with excitation light emitted from a light source of the scanning probe microscope.

An article of manufacture includes a support structure including a cladding material and defining therein a plurality of substantially parallel cores. The article also includes a plurality of conically-shaped spikes protruding from a first side of the support structure. Each respective conically-shaped spike of the plurality of conically-shaped spikes includes a core material (i) extending through a corresponding core of the plurality of substantially parallel cores and (ii) comprising an axial protrusion that protrudes axially from the cladding material at the first side of the support structure. The axial protrusion of the core material is tapered to form the respective conically-shaped spike. The article also includes a refractory metal layer coating at least a portion of each respective conically-shaped spike and one or more electrodes connected to the refractory metal layer and configured to apply a voltage to the refractory metal layer.

An article of manufacture includes a support structure including a cladding material and defining therein a plurality of substantially parallel cores. The article also includes a plurality of conically-shaped spikes protruding from a first side of the support structure. Each respective conically-shaped spike of the plurality of conically-shaped spikes includes a core material (i) extending through a corresponding core of the plurality of substantially parallel cores and (ii) comprising an axial protrusion that protrudes axially from the cladding material at the first side of the support structure. The axial protrusion of the core material is tapered to form the respective conically-shaped spike. The article also includes a refractory metal layer coating at least a portion of each respective conically-shaped spike and one or more electrodes connected to the refractory metal layer and configured to apply a voltage to the refractory metal layer.

A quantum dot microscope apparatus is provided. A further aspect employs a tilted or tapered end or tip on a microscopic probe. Another aspect of the present apparatus employs a probe including a quantum dot with only one tunneling lead connected to a power source. A manufacturing aspect includes creating a tapered or asymmetrically shaped specimen-facing end of a probe where a quantum dot is located on the end. A further manufacturing aspect includes using focused ion-beam milling to create a tip or end of a quantum dot microscope probe.

A quantum dot microscope apparatus is provided. A further aspect employs a tilted or tapered end or tip on a microscopic probe. Another aspect of the present apparatus employs a probe including a quantum dot with only one tunneling lead connected to a power source. A manufacturing aspect includes creating a tapered or asymmetrically shaped specimen-facing end of a probe where a quantum dot is located on the end. A further manufacturing aspect includes using focused ion-beam milling to create a tip or end of a quantum dot microscope probe.