Abstract: A protected anode including: an anode including lithium or capable of reversibly incorporating lithium ions; and a lithium ion-conductive protective layer on the anode and including a ceramic composite represented by Formula 1: Li1+aAlbGe2?cMdP3+eO12+f??Formula 1 wherein M is at least one element selected from titanium (Ti), zirconium (Zr), and germanium (Ge), 0?a?1, 0?b?1, 0?c?1, 0?d?0.5, 0?e?0.1, and 0?f?1.

Abstract: Provided is an antibody production method whereby it is possible to repeatedly acquire antibodies produced by fish without killing the fish. Specifically provided is an antibody production method whereby it is possible to repeatedly acquire the antibodies produced by a fish, without killing the fish, by administering antigens to fish that have blisters.

Abstract: A lithium battery including a negative electrode including a lithium metal or a lithium alloy; a positive electrode; and a polymer gel electrolyte contacting the negative electrode, wherein the polymer gel electrolyte has an ionic conductivity of about 10?3 S/cm or greater, a lithium ion transference number of about 0.15 or greater, and a lithium ion mobility of about 10?6 cm2/V×sec or greater, wherein the polymer gel electrolyte includes a lithium salt, a polymer capable of forming a complex with the lithium salt, an insulating inorganic filler, and an organic solvent, wherein the organic solvent is inert with respect to the lithium metal, wherein an anionic radius of the lithium salt is about 2.5 Angstroms or greater, and wherein a molecular weight of the lithium salt is about 145 or greater.

Abstract: An electrolyte including a lithium ion conductive polymer, a lithium salt, and an ionic liquid including an anion represented by Formula 1 below: wherein, in Formula 1 above, R1 and R2 are defined herein.

Abstract: A protected anode including an anode including a lithium titanium oxide; and a protective layer including a compound represented by Formula 1 below, a lithium air battery including the same, and an all-solid battery including the protected anode: Li1+XMXA2?XSiYP3?YO12??<Formula 1> wherein M may be at least one of aluminum (Al), iron (Fe), indium (In), scandium (Sc), or chromium (Cr), A may be at least one of germanium (Ge), tin (Sn), hafnium (Hf), and zirconium (Zr), 0?X?1, and 0?Y?1.

Abstract: A lithium air battery including an electrolyte including lithium ion conductive polymers and lithium salts between a positive electrode and a lithium ion conductive solid electrolyte membrane. The lithium ion conductive polymers are hydrophilic matrix polymers.

Abstract: The present invention aims at providing a novel indocyanine compound solving problems of conventionally used indocyanine green, such as solubility in water or physiological saline, a synthesis method and a purification method thereof, and a diagnostic composition including the novel indocyanine compound. Further, provided are a method for evaluating biokinetics of the novel indocyanine compound and a device for measuring biokinetics, and a method and a device for visualizing circulation of fluid such as blood in a living body, which utilize the diagnostic composition. Also, found are a novel indocyanine compound in which a hydrophobic moiety in a near-infrared fluorescent indocyanine molecule is included in a cavity of a cyclic sugar chain cyclodextrin to cover the hydrophobic moiety in the indocyanine molecule with the glucose, and a synthesis method and a purification method thereof.

Abstract: A negative electrode for a lithium secondary battery that includes an organic-inorganic hybrid protective layer where the lithium ion conductivity of a polymer included in the organic-inorganic hybrid protective layer is about 10?4 S/cm or less, a method of manufacturing the same, and a lithium secondary battery employing the same.

Abstract: A lithium air battery including: a negative electrode including lithium; a positive electrode using oxygen as a positive active material; and an organic electrolyte, wherein the organic electrolyte includes a metal-ligand complex.

Abstract: A lithium ion conductor, a method of preparing the same, and a lithium air battery including the lithium ion conductor. The lithium ion conductor includes a phosphorus-based compound having a characteristic peak at a Raman shift of about 720˜770 cm?1 on a Raman spectrum of the phosphorus-based compound.

Abstract: A lithium air battery including an aqueous electrolyte. In the lithium air battery, a lithium halide is included in the aqueous electrolyte in order to prevent lithium hydroxide and a solid electrolyte from reacting with each other so as to protect the negative electrode, thereby improving electrical characteristics of the lithium air battery.

Abstract: A group 3-5 nitride semiconductor multilayer substrate (1) and a method for manufacturing such substrate are provided. A semiconductor layer (12) is formed on a base substrate (11), and a mask (13) is formed on the semiconductor layer (12). Then, after forming a group 3-5 nitride semiconductor crystalline layer (14) by selective growing, the group 3-5 nitride semiconductor crystalline layer (14) and the base substrate (11) are separated. The crystallinity of the semiconductor layer (12) is lower than that of the group 3-5 nitride semiconductor crystalline layer (14).

Abstract: A group 3-5 nitride semiconductor multilayer substrate (1) and a method for manufacturing such substrate are provided. A semiconductor layer (12) is formed on a base substrate (11), and a mask (13) is formed on the semiconductor layer (12). Then, after forming a group 3-5 nitride semiconductor crystalline layer (14) by selective growing, the group 3-5 nitride semiconductor crystalline layer (14) and the base substrate (11) are separated. The crystallinity of the semiconductor layer (12) is lower than that of the group 3-5 nitride semiconductor crystalline layer (14).