Abstract: An antenna device is provided as a near-field communication antenna device that is configured by arranging a plurality of loop antennas. Each loop antenna includes a plurality of parallel circuits each having a capacitor and a resistance element; and a plurality of looped conductors in a shape of a loop that is divided. The divided looped conductors are connected to each other via the parallel circuits, and the plurality of looped conductors and the plurality of parallel circuits form a loop.

Abstract: A magnetoresistive element of the present disclosure includes a multilayer structure made up of at least a fixed magnetization layer, an intermediate layer and a storage layer. A first side wall is formed on a side wall of the multilayer structure. A second side wall is formed on the first side wall. The first side wall is made of an insulating material, for instance SiN or AlOx, that prevents intrusion of hydrogen. The second side wall is made of a hydrogen storage material, for instance titanium.

Abstract: A magnetoresistive element of the present disclosure has at least a layered structure composed of a magnetization fixed layer, an intermediate layer and a storage layer, wherein a metal layer is formed on or above the layered structure; an orthogonal projection image of the layered structure with respect to the metal layer is contained in the metal layer; and assuming that an oxide formation Gibbs energy of a metal atom constituting the metal layer at a temperature T (° C.) of 0° C. or higher and 400° C. or lower is EGib-0(T), a minimum Gibbs energy among oxide formation Gibbs energies of metal atoms constituting the magnetization fixed layer and the storage layer at the temperature T is EGib-1(T), and a maximum Gibbs energy among oxide formation Gibbs energies of metal atoms constituting the intermediate layer at the temperature T is EGib-2(T), EGib-0(T)<EGib-1(T) and/or EGib-2(T)?EGib-0(T) is satisfied.

Abstract: A resistance change element includes first and second electrodes spaced apart from each other, a metal material layer adjacent to the first electrode, an oxide layer adjacent to each of the metal material layer and the first electrode, and a resistance change layer disposed continuously between the second and first electrodes and between the second electrode and the oxide layer. The resistance change layer is made of a metal oxide. The metal material layer is made of a metal or a metal compound. The oxide layer is made of an oxide of the material forming the metal material layer. The first electrode is made of ruthenium, ruthenium oxide, iridium, iridium oxide, platinum, gold, or copper. A free energy of oxide formation of the oxide forming the oxide layer is higher than a free energy of oxide formation of the oxide forming the resistance change layer.

Abstract: A semiconductor device has a resistance change element that is high in the holding resistance of a low resistance (On) state while securing a memory window. In a resistance random access memory including selection transistors and resistance change elements coupled in series to the selection transistors, the resistance change element uses a lower electrode that applies a positive voltage when being transited to a high resistance (Off) state, an upper electrode that faces the lower electrode, and a resistance change layer that is sandwiched between the lower electrode and the upper electrode and that uses an oxide of transition metal. The resistance change layer contains nitrogen. The concentration of nitrogen on the lower electrode side is higher than that on the upper electrode side. The nitrogen in the resistance change layer exhibits a concentration gradient continuously declined from the lower electrode side to the upper electrode side.

Abstract: A resistance change element includes first and second electrodes spaced apart from each other, a metal material layer adjacent to the first electrode, an oxide layer adjacent to each of the metal material layer and the first electrode, and a resistance change layer disposed continuously between the second and first electrodes and between the second electrode and the oxide layer. The resistance change layer is made of a metal oxide. The metal material layer is made of a metal or a metal compound. The oxide layer is made of an oxide of the material forming the metal material layer. The first electrode is made of ruthenium, ruthenium oxide, iridium, iridium oxide, platinum, gold, or copper. A free energy of oxide formation of the oxide forming the oxide layer is higher than a free energy of oxide formation of the oxide forming the resistance change layer.

Abstract: Included are memory cells each including a resistance change element and a control circuit. The circuit performs an On writing process for applying, to the memory cell, an On writing pulse for the cell to be in a resistance state where a resistance value of the resistance change element is lower than a first reference value and an Off writing process for applying an Off writing pulse with an opposite polarity to the On writing pulse for a high resistance state with a second reference value or greater. The circuit applies, in the On writing process, a trial pulse having the same polarity as that of the On writing pulse and having the pulse width shorter than that of the On writing pulse and a reset pulse having the same polarity as that of the On writing pulse, in this order before applying the On writing pulse to the cell.

Abstract: A semiconductor device has a resistance change element that is high in the holding resistance of a low resistance (On) state while securing a memory window. In a resistance random access memory including selection transistors and resistance change elements coupled in series to the selection transistors, the resistance change element uses a lower electrode that applies a positive voltage when being transited to a high resistance (Off) state, an upper electrode that faces the lower electrode, and a resistance change layer that is sandwiched between the lower electrode and the upper electrode and that uses an oxide of transition metal. The resistance change layer contains nitrogen. The concentration of nitrogen on the lower electrode side is higher than that on the upper electrode side. The nitrogen in the resistance change layer exhibits a concentration gradient continuously declined from the lower electrode side to the upper electrode side.

Abstract: To improve information retention resistance of a resistance change memory which requires high information retention resistance. On the assumption that a special data storage memory and a general-purpose data storage memory are distinguished from each other, a forming operation small in resistance rise rate is used for an information writing operation of the special data storage memory. A switching operation is used for information writing of the general-purpose data storage memory. That is, the special data storage memory is configured so as to store information while adapting an initial resistance state to “0” whereas adapting a low resistance state to “1”. On the other hand, the general-purpose data storage memory is configured so as to store information while adapting a high resistance state to “0” whereas adapting a low resistance state to “1”.

Abstract: Included are memory cells each including a resistance change element and a control circuit. The circuit performs an On writing process for applying, to the memory cell, an On writing pulse for the cell to be in a resistance state where a resistance value of the resistance change element is lower than a first reference value and an Off writing process for applying an Off writing pulse with an opposite polarity to the On writing pulse for a high resistance state with a second reference value or greater. The circuit applies, in the On writing process, a trial pulse having the same polarity as that of the On writing pulse and having the pulse width shorter than that of the On writing pulse and a reset pulse having the same polarity as that of the On writing pulse, in this order before applying the On writing pulse to the cell.

Abstract: To improve information retention resistance of a resistance change memory which requires high information retention resistance. On the assumption that a special data storage memory and a general-purpose data storage memory are distinguished from each other, a forming operation small in resistance rise rate is used for an information writing operation of the special data storage memory. A switching operation is used for information writing of the general-purpose data storage memory. That is, the special data storage memory is configured so as to store information while adapting an initial resistance state to “0” whereas adapting a low resistance state to “1”. On the other hand, the general-purpose data storage memory is configured so as to store information while adapting a high resistance state to “0” whereas adapting a low resistance state to “1”.

Abstract: The semiconductor device includes an insulating film that is formed using a cyclic siloxane having a six-membered ring structure as a raw material; a trench that is formed in the insulating film; and a interconnect that is configured by a metal film embedded in the trench. In the semiconductor device, a modified layer is formed on a bottom surface of the trench, in which the number of carbon atoms and/or the number of nitrogen atoms per unit volume is larger than that inside the insulating film.

Abstract: Provided is a semiconductor memory device (resistance random access memory element) improved in properties. A Ru film is formed as a film of a lower electrode by sputtering, and a Ta film is formed thereonto by sputtering. Next, the Ta film is oxidized with plasma to oxidize the Ta film. In this way, a compound Ta2O5 is produced and further Ru is diffused into the compound to form a layer (variable resistance layer) in which Ru is diffused into the compound Ta2O5. Such an incorporation of a metal (such as Ru) into a transition metal oxide TMO (such as Ta2O5) makes it possible to form electron conductive paths additional to filaments to lower the filaments in density and thickness. Thus, the memory element can be restrained from undergoing OFF-fixation, by which the element is not easily lowered in resistance, to be improved in ON-properties.

Abstract: To provide a semiconductor device having less variation in characteristics. The semiconductor device is equipped with a plug formed in an interlayer insulating film, a lower electrode provided on the plug and to be coupled to the plug, a middle layer provided on the lower electrode and made of a metal oxide, and an upper electrode provided on the middle layer. The middle layer has a layered region contiguous to the lower electrode and the upper electrode. At least a portion of the layered region does not overlap with the plug. At least a portion of the plug does not overlap with the layered region.

Abstract: A semiconductor integrated circuit includes a logic circuit having a plurality of operation modes, a power source circuit that generates a power source voltage to be supplied to the logic circuit, a power source wiring that couples the power source circuit and the logic circuit, and a charge control block that holds charges for controlling the voltage of the power source wiring. The power source circuit generates a first power source voltage for causing the logic circuit to operate in a computing mode and a second power source voltage for causing the logic circuit to operate in a sleep mode. The charge control block includes a capacitor, a first switch, and a voltage supply unit that supplies the second power source voltage or a third power source voltage lower than the second power source voltage, to the capacitor.

Abstract: A semiconductor device in which MRAM is formed in a wiring layer A contained in a multilayered wiring layer, the MRAM having at least two first magnetization pinning layers in contact with a first wiring formed in a wiring layer and insulated from each other, a free magnetization layer overlapping the two first magnetization pinning layers in a plan view, and connected with the first magnetization pinning layers, a non-magnetic layer situated over the free magnetization layer, and a second magnetization pinning layer situated over the non-magnetic layer.

Abstract: A semiconductor device in which MRAM is formed in a wiring layer A contained in a multilayered wiring layer, the MRAM having at least two first magnetization pinning layers in contact with a first wiring formed in a wiring layer and insulated from each other, a free magnetization layer overlapping the two first magnetization pinning layers in a plan view, and connected with the first magnetization pinning layers, a non-magnetic layer situated over the free magnetization layer, and a second magnetization pinning layer situated over the non-magnetic layer.

Abstract: A semiconductor device in which MRAM is formed in a wiring layer A contained in a multilayered wiring layer, the MRAM having at least two first magnetization pinning layers in contact with a first wiring formed in a wiring layer and insulated from each other, a free magnetization layer overlapping the two first magnetization pinning layers in a plan view, and connected with the first magnetization pinning layers, a non-magnetic layer situated over the free magnetization layer, and a second magnetization pinning layer situated over the non-magnetic layer.

Abstract: Provided is a semiconductor device, which includes an interlayer insulating film formed on a semiconductor substrate, a wiring layer filled in a recess formed in the interlayer insulating film, and a cap insulating film. The interlayer insulating film includes a first SiOCH film and a surface modification layer including an SiOCH film formed by modifying a surface layer of the first SiOCH film, the SiOCH film having a lower carbon concentration and a higher oxygen concentration than the first SiOCH film has. The cap insulating film contacts with surfaces of the metal wiring and the surface modification layer.

Abstract: A quick connection unit 324 of a mobile phone 3 (a mobile phone-STA) searches PCs 2 (PC-AP) being access points, extracts PCs 2 in a predetermined waiting state from PCs 2 that responded to the search, and executes connection establishment based on connection information corresponding to the predetermined waiting state and data transmission for each of a plurality of PCs 2 selected from the extracted PCs 2.