Abstract: Disclosed herein is a system for detecting cancer cells. The system includes a biosensor comprising a graphene-Si Schottky junction, a light source placed above the biosensor, an electrical stimulator-analyzer connected to the biosensor, and a processing unit connected to the electrical stimulator-analyzer and the light source. The processing unit is configured to perform a method. The method includes generating a set of photocurrents in a reverse bias regime passed through the graphene-Si Schottky junction with a sample placed thereon utilizing the light source and the electrical stimulator-analyzer, measuring the set of the generated photocurrents through the graphene-semiconductor Schottky junction in reverse bias regime in the presence of the sample utilizing the electrical stimulator-analyzer device, and detecting a presence of cancer cells in the sample responsive to detecting a change in the measured set of the generated photocurrents within the reverse bias regime.

Abstract: A permanent magnet actuation mechanism may include a first permanent magnet magnetized along a first axis and rotatable about a first rotational axis perpendicular to the first axis, a second permanent magnet magnetized along a second axis and rotatable about a second rotational axis perpendicular to the second axis. The first rotational axis is parallel with the second rotational axis. The mechanism further comprises a mounting structure configured to position the first permanent magnet at a first distance from the second permanent magnet along a main axis perpendicular to the first rotational axis and the second rotational axis.

Abstract: A system for detecting a target material in a sample. The system includes a sensor, a light source, an image-capturing device, two linear-crossed polarizers including a first polarizer and a second polarizer, and a processing unit. The sensor is configured to place the sample thereon and includes a fabric impregnated with liquid crystals (LCs). The light source is configured to transmit a beam of light through a path passing from the first polarizer, the sensor, and the second polarizer. The image-capturing device is configured to capture an image of a surface of the second polarizer. The image contains a pattern formed by orientations of LCs corresponding to the sample. The processing unit is configured to detect a presence of the target material in the sample by analyzing the captured image.

Abstract: A metamaterial switch. The metamaterial switch includes a first conductive plate, a first loaded conductive plate, and a magneto-dielectric material. The first loaded conductive plate includes a second conductive plate and a first tunable impedance surface set. Each tunable impedance surface in the first tunable impedance surface set includes a respective tunable conductivity. An effective permittivity of the metamaterial switch is configured to be adjusted to a first predetermined value. The effective permittivity of the metamaterial switch is adjusted responsive to tuning a respective tunable conductivity of each respective tunable impedance surface in the first tunable impedance surface set.

Abstract: A method for detecting a species of bacteria in a sample solution. The method includes putting the sample solution in contact with an array of zinc oxide nanorods on a gate region of a field effect transistor (FET) biosensor, applying an alternating current (AC) voltage between source and drain electrodes of the FET biosensor, applying a first direct current (DC) voltage of V1 to the sample solution, measuring a first set of electrical impedance values (Z1) between the source region and the drain region, calculating a first impedance difference set (?Z1) between the Z1 and a respective first initial set of electrical impedance values (Z10) associated with a bacteria-free reference solution, determining bacteria indicative factors including a first impedance difference peak value (?Z1m) and a respective peak frequency (fm), and detecting a presence of a first species of bacteria in the sample solution based on the bacteria indicative factors.

Abstract: A system for detecting a target material in a sample. The system includes a sensor, a light source, an image-capturing device, two linear-crossed polarizers including a first polarizer and a second polarizer, and a processing unit. The sensor is configured to place the sample thereon and includes a fabric impregnated with liquid crystals (LCs). The light source is configured to transmit a beam of light through a path passing from the first polarizer, the sensor, and the second polarizer. The image-capturing device is configured to capture an image of a surface of the second polarizer. The image contains a pattern formed by orientations of LCs corresponding to the sample. The processing unit is configured to detect a presence of the target material in the sample by analyzing the captured image.

Abstract: A morphing panel mechanism may include a central panel and a side panel, where a first edge of the side panel may be pivotally coupled to a first edge of the central panel. A morphing panel mechanism may further include a guide panel that may be coupled with a first corner of the central panel via a ball joint, where the guide panel may include a first slit. A morphing panel mechanism may further include a flexible panel, where a first edge of the flexible panel may be pivotally coupled with a second edge of the side panel, and a second edge of the flexible panel may be slidably disposed within the slit of the guide panel.

Abstract: A method for fabricating porous wire-in-tube (WiT) nanostructures including forming a first porous core-shell nanostructure, forming a second porous core-shell nanostructure by increasing thickness and porosity of the porous core-shell nanostructure, and forming a porous WiT nanostructure by etching the second porous core-shell nanostructure. Forming the first porous core-shell nanostructure may include forming a porous layer on a semi-conductive core by depositing a first plurality of particles on the semi-conductive core and generating an initial porous semi-conductive core by etching the semi-conductive core simultaneously with forming the porous layer.

Abstract: A morphing panel mechanism may include a central panel and a side panel, where a first edge of the side panel may be pivotally coupled to a first edge of the central panel. A morphing panel mechanism may further include a guide panel that may be coupled with a first corner of the central panel via a ball joint, where the guide panel may include a first slit. A morphing panel mechanism may further include a flexible panel, where a first edge of the flexible panel may be pivotally coupled with a second edge of the side panel, and a second edge of the flexible panel may be slidably disposed within the slit of the guide panel.

Abstract: A method for nitrate removal from drinking water. The method includes adapting a sludge including hydrogenotrophic denitrifiers (HTDs) by dominating the HTDs in the sludge, cultivating a microalgae biomass, forming a microalgae-HTD biomass by cultivating a mixture of the adapted sludge and the cultivated microalgae biomass, nucleating a plurality of microalgae-HTD granules by cultivating the formed microalgae-HTD biomass in a sequencing batch (SB) mood with a constant HRT, growing the plurality of microalgae-HTD granules by cultivating the nucleated plurality of microalgae-HTD granules in an up flow (UF) mood with a reducing HRT, and continuous nitrate removal from nitrate-contaminated water with a minimum HRT over the grown plurality of microalgae-HTD granules.

Abstract: A damping system for damping rotary movements of a tailing arm. The system includes a chassis, a main shaft, and a rotary damping mechanism. The rotary damping mechanism includes a first externally-threaded gear attached fixedly to the main shaft, a guide rail attached fixedly to the chassis, a linear shock absorber, an internally-threaded gear associated with the first externally-threaded gear, and a first actuator configured to decouple the first externally-threaded gear from the linear shock absorber and couple the first externally-threaded gear with the linear shock absorber.

Abstract: A liposomal composition includes at least two anti-tumor herbal drugs that are simultaneously co-encapsulated. Optionally, the liposomal composition is targeted by adding a monoclonal antibody is added to the liposomes.