Abstract: A spectroscopy system that includes a light source that generates light having a plurality of wavelengths, a light transmitter that transmits the light to a target analyte, a light receiver that receives Raman-scattered light scattered from the target analyte, and a multi-wavelength spectroscopy assembly that acquires a spectrum by splitting the Raman-scattered light transmitted from the light receiver. The multi-wavelength spectroscopy assembly includes a single diffraction grating configured to diffract the Raman-scattered light and a single concave mirror configured to focus the Raman-scattered light.

Abstract: An impedance measurement device of the present disclosure includes: an electrochemical energy device; an amplifier connected to each connection terminal of the electrochemical energy device and configured to amplify a signal introduced into a wiring; and a main board configured to receive the signal from the amplifier and measure an impedance. Accordingly, the present invention has advantages in that high resistance to electromagnetic interference may be achieved by disposing a preamplifier close to a terminal of an electrochemical energy device to amplify only the signal without amplifying a noise introduced into a wiring.

Abstract: A spectroscopy system that includes a light source portion configured to generate light having a plurality of wavelengths, a light transmitter configured to transmit the light to a target analyte, a light receiving portion configured to receive Raman-scattered light scattered from the target analyte, and a multi-wavelength spectroscopy portion that may acquire a spectrum by splitting the Raman-scattered light transmitted from the light receiving portion. The multi-wavelength spectroscopy portion includes a single diffraction grating configured to diffract the Raman-scattered light and a single concave mirror configured to focus the Raman-scattered light.

Abstract: An impedance measurement device of the present disclosure includes: an electrochemical energy device; an amplifier connected to each connection terminal of the electrochemical energy device and configured to amplify a signal introduced into a wiring; and a main board configured to receive the signal from the amplifier and measure an impedance. Accordingly, the present invention has advantages in that high resistance to electromagnetic interference may be achieved by disposing a preamplifier close to a terminal of an electrochemical energy device to amplify only the signal without amplifying a noise introduced into a wiring.

Abstract: Solar cells and methods of manufacturing the solar cells are provided. The solar cell may be formed on a substrate having a plurality of concave portions. A plurality of nanostructures may be formed on a surface of the substrate, in which the plurality of concave portions are formed. A photoactive layer may be formed to cover the plurality of nanostructures. The nanostructures may include an inorganic material, and the photoactive layer may include an organic material.

Abstract: An electric energy generating device. The electric energy generating device includes a piezoelectric structure including a material having piezoelectric characteristics, and an insulating film including a material having electret characteristics. When external energy is supplied to the insulating film, the insulating film contacts the piezoelectric structure and the piezoelectric structure is then deformed to generate electric energy. Also, electric energy is generated when an electrostatic capacitance between the insulating film and a substrate adjacent to the insulating film changes.

Abstract: A terahertz radiation source includes: a cathode configured to emit an electron beam, an anode configured to focus the electron beam emitted from the cathode; a collector facing the cathode and configured to collect the emitted electron beam focused by the anode; an oscillating circuit positioned between the anode and the collector and configured to convert energy of a passing electron beam into electromagnetic wave energy; and an output unit connected to the oscillating circuit and configured to externally emit the electromagnetic wave energy.

Abstract: Provided are 3-dimensional standing type metamaterial structures and methods of fabricating the same. The 3-dimensional metamaterial structure includes a substrate; and a resonator, which includes a fixing unit fixed to the substrate; and a plurality of arms, which extend from the fixing unit and are curved upward on the substrate, wherein permittivity, permeability, and refractive index of the metamaterial structure in a predetermined frequency band differ from permittivity, permeability, and refractive index of the substrate. The resonator may be easily fabricated in MEMS/NEMS (micro-electro-mechanical system/nano-electro-mechanical system) processes.

Abstract: An electroconductive fiber, a method of manufacturing an electroconductive fiber, and a fiber complex including an electroconductive fiber are provided, the electroconductive fiber includes an electroconductive polymer, an elastic polymer that forms a structure with the electroconductive polymer, and a carboneous material on at least one of the electroconductive polymer and the elastic polymer.

Abstract: An electric energy generating device. The electric energy generating device includes a piezoelectric structure including a material having piezoelectric characteristics, and an insulating film including a material having electret characteristics. When external energy is supplied to the insulating film, the insulating film contacts the piezoelectric structure and the piezoelectric structure is then deformed to generate electric energy. Also, electric energy is generated when an electrostatic capacitance between the insulating film and a substrate adjacent to the insulating film changes.

Abstract: Solar cells and methods of manufacturing the solar cells are provided. The solar cell may be formed on a substrate having a plurality of concave portions. A plurality of nanostructures may be formed on a surface of the substrate, in which the plurality of concave portions are formed. A photoactive layer may be formed to cover the plurality of nanostructures. The nanostructures may include an inorganic material, and the photoactive layer may include an organic material.

Abstract: An electroconductive fiber, a method of manufacturing an electroconductive fiber, and a fiber complex including an electroconductive fiber are provided, the electroconductive fiber includes an electroconductive polymer, an elastic polymer that forms a structure with the electroconductive polymer, and a carboneous material on at least one of the electroconductive polymer and the elastic polymer.

Abstract: Provided is a fiber for detecting a target, a method of preparing the fiber for detecting the target, a method of detecting the target in a sample, a fiber complex including the fiber for detecting the target, and a kit including the fiber for detecting the target. The fiber may include a polymer, a target detecting material, and a metal nanoparticle, wherein the target material and the metal nanoparticle are fixed to the polymer. The method of preparing a fiber may include preparing a composition that includes a polymer, a target detecting material, and a metal nanoparticle and spinning the composition to prepare the fiber.

Abstract: A terahertz radiation source includes: a cathode configured to emit an electron beam, an anode configured to focus the electron beam emitted from the cathode; a collector facing the cathode and configured to collect the emitted electron beam focused by the anode; an oscillating circuit positioned between the anode and the collector and configured to convert energy of a passing electron beam into electromagnetic wave energy; and an output unit connected to the oscillating circuit and configured to externally emit the electromagnetic wave energy.

Abstract: Solar light utilizing systems and solar devices are provided, the solar light utilizing system includes a main body portion, a solar light collecting unit associated with the main body portion and a tracking unit configured to change an orientation of the solar light collecting unit by moving a center of mass of the solar light utilizing system.

Abstract: A solar cell module includes an upper substrate including a cylindrical lens is disposed on a lower substrate to cover a solar cell. The cylindrical lens focuses incident light onto the solar cell. In a method of manufacturing the solar cell module, a solar cell is formed on a lower substrate by sequentially depositing a first material layer, a second material layer, and a second electrode onto the first electrode. An upper substrate including a cylindrical lens is adhered to or formed on the lower substrate.

Abstract: A solar energy utilizing apparatus includes: a fluid pipe forming a flow path of a heat medium and including a convex surface; and a solar cell formed on the convex surface of the fluid pipe. In a method of manufacturing a solar energy utilizing apparatus, a first substrate including a first surface and a second surface is formed. The first surface has a plurality of convex surfaces and the second surface has a plurality of concave surfaces. A plurality of solar cells are formed on the convex surfaces, respectively. A second substrate is formed, and the second substrate is bonded to the first substrate.