Disclosed is a gas sensing material for methylbenzene detection. Specifically, the gas sensing material includes a nanocomposite of Cr.sub.2O.sub.3 and ZnCr.sub.2O.sub.4. The content of Cr in the nanocomposite is from 67.0 at. % to 90.0 at. %, based on the sum of the contents of Cr and Zn atoms. The gas sensing material is highly selective to methylbenzenes over other gases and is highly sensitive to methylbenzenes. Also disclosed are methods for preparing the gas sensing material. The methods facilitate control over the composition of the gas sensing material and enable rapid synthesis of the gas sensing material at low temperature. Also disclosed is a gas sensor including the gas sensing material.

A particle mixture having: ZrO.sub.2+HfO.sub.2+Y.sub.2O.sub.3+CeO.sub.2; 0%≤Al.sub.2O.sub.3≤1.5%; other oxides than ZrO.sub.2, HfO.sub.2, Y.sub.2O.sub.3, CeO.sub.2 and Al.sub.2O.sub.3: between 0.5% and 12%. The contents of Y.sub.2O.sub.3 and CeO.sub.2, on the basis of the sum of ZrO.sub.2, HfO.sub.2, Y.sub.2O.sub.3 and CeO.sub.2, being such that 1.8%≤Y.sub.2O.sub.3≤3% and 0.1%≤CeO.sub.2≤0.9%. The mixture includes between 0.5% and 10% of particles of an oxide pigment. The content of other oxides and which are not included in the oxide pigment being less than 2%. The particles of the oxide pigment including, for more than 95%, of a material chosen from: oxide(s) of perovskite structure or equivalent of precursor(s) of these oxides, oxides of spinal structure or an equivalent amount of precursor(s) of these oxides, and oxides of hematite structure E.sub.2O.sub.3, oxides of rutile structure FO.sub.2, with “E” and “F” being chosen.

[Object] Provided are a Zn—Sn—O-based oxide sintered body which is used as a sputtering target or a tablet for vapor deposition and which is resistant to crack formation and the like during film formation, and a method for producing the same. [Solving means] The oxide sintered body is characterized in that tin is contained with an atomic ratio of Sn/(Zn+Sn) being 0.01 to 0.6, an average crystal particle diameter of the sintered body is 4.5 μm or less, and a degree of orientation represented by I.sub.(222)/[I.sub.(222)+I.sub.(400)] is 0.52 or more, where I.sub.(222) and I.sub.(400) represent integrated intensities of the (222) plane and the (400) plane of a Zn.sub.2SnO.sub.4 phase measured by X-ray diffraction using the CuKα radiation. The oxide sintered body has an improved mechanical strength, so that the oxide sintered body is resistant to breakage during processing of the sintered body and also is resistant to breakage and crack formation during film formation of transparent conductive films when used as a sputtering target or a tablet for vapor deposition.

A cylindrical sputtering target includes a plurality of cylindrical sintered compacts adjacent to each other while having a space therebetween. The plurality of cylindrical sintered compacts have a relative density of 99.7% or higher and 99.9% or lower. The plurality of cylindrical sintered compacts adjacent to each other have a difference therebetween in the relative density of 0.1% or smaller.

Methods of forming a carbon fiber reinforced carbon foam are provided. Such a method may comprise heating a porous body composed of a solid material comprising covalently bound carbon atoms and heteroatoms and having a surface defining pores distributed throughout the solid material, in the presence of an added source of gaseous hydrocarbons. The heating generates free radicals in the porous body from the heteroatoms and induces reactions between the free radicals and the gaseous hydrocarbons to form covalently bound carbon nanofibers extending from the surface of the solid material and a network of entangled carbon microfibers within the pores the porous body, thereby forming a carbon fiber reinforced carbon foam. Carbon fiber reinforced carbon foams and ballistic barriers incorporating the foams are also provided.

An image acquisition semiconductor film for a high-resolution mass spectrometric imaging system, and a preparation method and an application. The image acquisition semiconductor film for the high-resolution mass spectrometric imaging system is prepared by using the following method: weighing semiconductor nanometer particles, putting the semiconductor nanometer particles into a muffle furnace for burning first, further grinding by using an agate mortar, and uniformly dispersing the semiconductor nanometer particles so as to obtain semiconductor nanometer powder; and finally, pressing the semiconductor nanometer powder in a compressor so as to obtain the semiconductor film. Based on laser activated electron tunnelling as well as photoelectron capture ionization and dissociation, sample molecules are ionized without background interference; the limitation of a conventional MALDI substrate is overcome; the semiconductor film is simple and easy to obtain, is stable in mass spectrometric signal, has a uniform and smooth surface, generates no background interference, and can be used for fingerprint analyzing and animal and plant tissue slice analysis; and the semiconductor film is particularly suitable for accurate mass spectrometric imaging of small molecular substances, so that quality control and industrialization can be performed conveniently.

An oxide electrolyte sintered body with high lithium ion conductivity and a method for producing the same, which can obtain the oxide electrolyte sintered body with high lithium ion conductivity by sintering at lower temperature than ever before. The method for producing an oxide electrolyte sintered body may comprise the steps of: preparing crystal particles of a garnet-type ion-conducting oxide which comprises Li, H, at least one kind of element L selected from the group consisting of an alkaline-earth metal and a lanthanoid element, and at least one kind of element M selected from the group consisting of a transition element that can be 6-coordinated with oxygen and typical elements belonging to the Groups 12 to 15, and which is represented by a general formula (Li.sub.x−3y−z,E.sub.y,H.sub.z)L.sub.αM.sub.βO.sub.γ (where E is at least one kind of element selected from the group consisting of Al, Ga, Fe and Si, 3≦x−3y−z≦7, 0≦y<0.22, 0<z≦2.8, 2.5≦α≦3.5, 1.5≦β≦2.5, and 11≦γ≦13); preparing a lithium-containing flux; and sintering a mixture of the crystal particles of the garnet-type ion-conducting oxide and the flux by heating at 400° C. or more and 650° C. or less.

Disclosed herein are doped perovskite oxides. The doped perovskite oxides may be used as a cathode material in an electrochemical cell to electrochemically generate ammonia from N.sub.2. The doped perovskite oxides may be combined with nitride compounds, for instance iron nitride, to further increase the efficiency of the ammonia production.

A lead-free piezoelectric ceramic composition mainly includes a first crystal phase (KNN phase) and a second crystal phase (NTK phase). In the first crystal phase (KNN phase), a plurality of crystal grains formed of an alkali niobate/tantalate perovskite oxide having piezoelectric characteristics is bound to each other in a deposited state. The second crystal phase (NTK phase) is formed of a compound containing titanium (Ti) and fills spaces between the crystal grains in the first crystal phase.

A porous sintered clay mineral matrix that contains aluminum and is doped with 0.1-20 mol %, based on the amount of the aluminum, one or more transition metals, one or more post-transition metals, one or more rare earth metals, or a combination thereof. An example is a kaolinite matrix. The matrix can be made from a calcined clay mineral powder that contains aluminum and is doped with at least one of these metals. Also disclosed are methods of preparing the above-described matrix and powder.