Abstract: A high-frequency acceleration cavity core is a toroidal core obtained by winding an Fe-based magnetic ribbon having crystals with an average crystal grain size of 1 ?m or less, in which a space factor of the Fe-based magnetic ribbon is 40% or more and 59% or less, and a ?Qf value at 1 MHz is 3×109 Hz or more. The average crystal grain size is preferably 0.1 ?m or less. The toroidal core preferably has a portion having a gap portion from an inner diameter to an outer diameter.

Abstract: A magnetic ribbon according to an embodiment has a crystallinity degree of 0.05 or higher and 0.4 or lower when the magnetic ribbon is subjected to XRD analysis, the magnetic ribbon being Fe—Nb—Cu—Si—B-base, and the crystallinity degree being expressed by “a peak total area of a crystalline phase”/(“a peak area of an amorphous phase”+“the peak total area of the crystalline phase”). Also, the magnetic ribbon is preferred to have a region in which a KIKUCHI pattern is detected when the crystalline phase is subjected to EBSD analysis. Also, the thickness of the magnetic ribbon is preferred to be 25 ?m or less.

Abstract: A Co-based amorphous magnetic thin strip for a magnetic sensor is disclosed. The Co-based amorphous magnetic thin strip has a width W equal to or smaller than 1 mm, a length L between 6 mm and 100 mm inclusive, a ratio L/W between 20 and 1000 inclusive, a strip thickness t between 10 ?m and 28 ?m inclusive, and a cross section of a rectangle or a trapezoid.

Abstract: A permanent magnet of the embodiment includes: a composition represented by a composition formula: R(FepMqCurCtCo1-p-q-r-t)z (R is at least one element selected from rare-earth elements, M is at least one element selected from Ti, Zr and Hf, 0.27?p?0.45, 0.01?q?0.05, 0.01?r?0.1, 0.002?t?0.03, and 6?z?9); and a metallic structure including a main phase containing a Th2Zn17 crystal phase, and a sub phase of the element M having an element M concentration of 30 atomic % or more. The sub phase of the element M precipitates in the metallic structure. A ratio of a circumferential length to a precipitated area of the sub phase of the element M is 1 or more and 10 or less.

Abstract: A permanent magnet of the embodiment includes: a composition represented by a composition formula: R(FepMqCurCtCo1-p-q-r-t)z (R is at least one element selected from rare-earth elements, M is at least one element selected from Ti, Zr and Hf, 0.27?p?0.45, 0.01?q?0.05, 0.01?r?0.1, 0.002?t?0.03, and 6?z?9); and a metallic structure including a main phase containing a Th2Zn17 crystal phase, and a sub phase of the element M having an element M concentration of 30 atomic % or more. The sub phase of the element M precipitates in the metallic structure. A ratio of a circumferential length to a precipitated area of the sub phase of the element M is 1 or more and 10 or less.

Abstract: A high thermal expansion member consisting substantially of Fe—Ni—Cr based alloy, a low thermal expansion member consisting substantially of an Fe—Ni based alloy, and an intermediary member, which comprises one kind of metal selected from Fe, Al and Cu or an alloy comprising these metals, possesses a thermal expansion coefficient &agr;3 which has a value between those of the high thermal expansion member (thermal expansion coefficient &agr;1) and the low thermal expansion member (thermal expansion coefficient &agr;2) (&agr;1>&agr;3>&agr;2), and is interposed therebetween, are laminated to form a thermal deformation member for an electron tube or a thermal deformation member for electric control. The intermediary member, without adversely affecting strength or long term reliability of the thermal deformation member, contributes to manufacturing cost reductions and improvement of workability.

Abstract: A high thermal expansion member consisting of such as an Fe--Ni--Cr based alloy, a low thermal expansion member consisting of such as an Fe--Ni based alloy, and an intermediary member, which comprises one kind of metal selected from Fe, Al and Cu or an alloy comprising these metals, possesses a thermal expansion coefficient .alpha..sub.3 which is located between those of the high thermal expansion member (thermal expansion coefficient .alpha..sub.1) and the low thermal expansion member (thermal expansion coefficient .alpha..sub.2) (.alpha..sub.1 >.alpha..sub.3 >.alpha..sub.2), and is interposed therebetween, are laminated to form a thermal deformation member for an electron tube or a thermal deformation member for electric control. The intermediary member, without adversely affecting strength or long term reliability of the thermal deformation member, contributes to manufacturing cost reduction and improvement of workability.