Disclosed herein is a super resolution imaging method and system for obtaining an image in a crystal material and/or device.

In a sensor unit, a sensor element having an optical behavior that depends on at least one analyte is in diffusive contact with an auxiliary medium, which is present in a reservoir in the sensor unit, via a membrane. The reservoir and the membrane, on the one hand, and sensor element, on the other hand, can be removed from one another in order to place the sensor unit in a measurement state. The auxiliary medium can serve to wet the sensor element during storage of the sensor unit or also for calibrating the sensor element.

In a sensor unit, a sensor element having an optical behavior that depends on at least one analyte is in diffusive contact with an auxiliary medium, which is present in a reservoir in the sensor unit, via a membrane. The reservoir and the membrane, on the one hand, and sensor element, on the other hand, can be removed from one another in order to place the sensor unit in a measurement state. The auxiliary medium can serve to wet the sensor element during storage of the sensor unit or also for calibrating the sensor element.

Systems and methods are provided for analyzing a biomechanical property of a medium using stimulated Brillouin scattering microscopy. The method can include a first step of applying a probe beam and pulsed pump beam to a target section of the medium, wherein the pump beam interacts with the probe beam to generate at least one acoustic wave in the medium and at least one Brillouin signal is produced as a result of the generated acoustic wave. The method can also include a second step of receiving the produced Brillouin signal and a third step of determining, using a processor and the

Various embodiments may provide an optical system. The optical system may include a laser source configured to emit a pump beam. The optical system may also include a non-linear medium configured to generate, based on the pump beam, an idler beam configured to incident on the sample and configured to be reflected, and a signal beam. The optical system may further include a mirror configured to reflect the signal beam so that the reflected signal beam interacts with the reflected idler beam in the non-linear medium to generate a resultant signal beam that carries an interference pattern. The optical system may additionally include a detector configured to receive the resultant signal beam for imaging the sample. The optical system may also include one or more optical elements configured to direct the idler beam from the non-linear medium to the sample, and the signal beam from the non-linear medium to the mirror.

Disclosed is a composite particle for use in a marking that is suitable for identification/authentication purposes. The particle comprises at least one superparamagnetic portion and at least one thermoluminescent portion coated with an thermoisolating portion. Optionally also a thermoconductive portion between the superparamagnetic and thermoluminscent portions.

Disclosed is a composite particle for use in a marking that is suitable for identification/authentication purposes. The particle comprises at least one superparamagnetic portion and at least one thermoluminescent portion coated with an thermoisolating portion. Optionally also a thermoconductive portion between the superparamagnetic and thermoluminscent portions.

A biosensor is provided. The biosensor includes a substrate, photodiodes, pixelated filters, an excitation light rejection layer and an immobilization layer. The substrate has pixels. The photodiodes are disposed in the substrate and correspond to one of the pixels, respectively. The pixelated filters are disposed on the substrate. The excitation light rejection layer is disposed on the pixelated filter. The immobilization layer is disposed on the excitation light rejection layer.

A biosensor is provided. The biosensor includes a substrate, photodiodes, pixelated filters, an excitation light rejection layer and an immobilization layer. The substrate has pixels. The photodiodes are disposed in the substrate and correspond to one of the pixels, respectively. The pixelated filters are disposed on the substrate. The excitation light rejection layer is disposed on the pixelated filter. The immobilization layer is disposed on the excitation light rejection layer.

A flow cell applicator system can include a flow cell applicator including multiple flow cells to deposit multiple substance spots on a deposition surface, and a positioning assembly to position, to dock, and to unlock the multiple flow cells relative to the deposition surface. The substance spots can be depositable when the multiple flow cells are docked on the deposition surface. The flow cell applicator system can also include a spot deposition identifier operably associated with a processor to: record data related to substance spots as applied on the deposition surface, identify data related to substance spots previously deposited on the deposition surface, or both.