A microscope including an illumination objective with a first optical axis, embodied to produce a light sheet, and a detection objective with a second optical axis, embodied to detect light coming from the specimen plane. The illumination objective and the detection objective are aligned relative to one another and the specimen plane so that the first and second optical axes intersect in the specimen plane and include a substantially right angle therebetween. The optical axes each include an angle which differs from zero with a reference axis directed orthogonal to the specimen plane. An overview illumination apparatus for wide-field illumination of the specimen plane, includes an illumination optical unit with a third optical axis. The characterizing feature is that the detection objective is provided to detect both light from the light sheet and light from the illumination optical unit. A method is also provided for operating a light sheet microscope.

An aperture stop that includes a non-circular region that comprises at least one opaque region and at least one opening region; wherein each point in the at least one opening region is (a) mapped to an angle of illumination and (b) is associated with a corresponding point in the at least one opaque region that. mapped to an angle of specular reflectance from the angle of illumination mapped to the opening point.

The present disclosure relates a low magnification dark-field microscope system and method for producing a dark-field image. The method includes transferring a biological specimen to a surface of a sample plate, and pre-treating the biological specimen using one or more pre-treatment steps selected from (1) heating the biological specimen using a heating device; (2) applying ultrasound energy using an ultrasound transducer and ultrasound generator; and (3) doping the biological specimen with a metallic nanoparticle. Following pre-treatment, the method includes imaging a region of interest the biological specimen on the sample plate using a dark-field microscope to generate a dark-field image of the biological specimen.

A system and method for using a microscope to at least haptically observe a specimen in a fluid is provided. In one embodiment of the present invention, an audio frequency modulation sensing (AFMS) device is used to convert an optical signal from the specimen into an electrical signal. A haptic feedback device is then used to convert the electrical signal in at least vibrations, thereby providing a user with haptic feedback associated with the optical signal from the specimen. In another embodiment, a second electrical signal can be provided to a second haptic feedback (e.g., shaker, piezo electric, electric current inducing, etc.) device in the fluid, thereby allowing for bidirectional haptic feedback between the user and the specimen. In other embodiments, aural data can be extracted from the electrical signal and presented to the user either alone in in synchronization with video data (e.g., from a video camera).

A dark field metrology device includes an objective lens arrangement and a zeroth order block to block zeroth order radiation. The objective lens arrangement directs illumination onto a specimen to be measured and collects scattered radiation from the specimen, the scattered radiation including zeroth order radiation and higher order diffracted radiation. The dark field metrology device is operable to perform an illumination scan to scan illumination over at least two different subsets of the maximum range of illumination angles; and simultaneously perform a detection scan which scans the zeroth order block and/or the scattered radiation with respect to each other over a corresponding subset of the maximum range of detection angles during at least part of the illumination scan.

A dark field metrology device includes an objective lens arrangement and a zeroth order block to block zeroth order radiation. The objective lens arrangement directs illumination onto a specimen to be measured and collects scattered radiation from the specimen, the scattered radiation including zeroth order radiation and higher order diffracted radiation. The dark field metrology device is operable to perform an illumination scan to scan illumination over at least two different subsets of the maximum range of illumination angles; and simultaneously perform a detection scan which scans the zeroth order block and/or the scattered radiation with respect to each other over a corresponding subset of the maximum range of detection angles during at least part of the illumination scan.

The invention relates to a liquid cell (1) for the microscopic image capture and Raman spectroscopic material analysis of a particle suspension in a reflected light microscope, having at least the following components: a measuring chamber (2) which has a base (3), a measuring window (5) opposite the base (3), and a seal (6), wherein the base (3) has a planar design at least in one region of the support of the seal (6), and the base (3) has a reflective surface (4) which is provided such that Raman excitation light incident through the measuring window (5) is reflected on the reflective surface (4) in a directed manner such that the background signal in a Raman measurement is reduced and the Raman signal of a particle in a suspension is increased. The invention further relates to a microscope which has such a liquid cell.

The invention relates to a liquid cell (1) for the microscopic image capture and Raman spectroscopic material analysis of a particle suspension in a reflected light microscope, having at least the following components: a measuring chamber (2) which has a base (3), a measuring window (5) opposite the base (3), and a seal (6), wherein the base (3) has a planar design at least in one region of the support of the seal (6), and the base (3) has a reflective surface (4) which is provided such that Raman excitation light incident through the measuring window (5) is reflected on the reflective surface (4) in a directed manner such that the background signal in a Raman measurement is reduced and the Raman signal of a particle in a suspension is increased. The invention further relates to a microscope which has such a liquid cell.

A light sheet microscope includes a sample chamber in which a cover slip or slide is arrangeable, which has a surface that defines a partially reflective interface and which has a further surface that defines a further partially reflective interface. The two interfaces are arranged at different distances from an objective. The light sheet microscope further includes an optical system having the objective facing toward the cover slip or slide, an illumination apparatus, which is designed to generate a light sheet, a sensor, and a processor. The two interfaces are formed in that two optical media are applicable in the sample chamber. The light sheet microscope forms a measuring device for acquiring a measured variable. The sensor is designed to acquire the intensities and/or the incidence locations of the two reflection light beams.

A cultivation container includes a waveguide substrate that totally reflects and guides measurement light incident from a side end surface of the waveguide substrate, and a surrounding wall that stands upright on a top surface of the waveguide substrate and forms a cell cultivation space. The surrounding wall includes a shielding part that shields the measurement light.