Provided is a simplified driving method of a synapse circuit. In a case where a first pre-spike pulse precedes a first post-spike pulse, a second pre-spike pulse from an input circuit 20a is used as a time window that allows writing of a coupling weight, and the first post-spike pulse from a neuron circuit 17 is used as a write pulse for controlling a write timing of the coupling weight. In a case where the first post-spike pulse precedes the first pre-spike pulse, a second post-spike pulse from the neuron circuit 17 is used as the time window, and the first pre-spike pulse from the input circuit 20a is used as the write pulse. The second pre-spike pulse and the second post-spike pulse are output in synchronization with the first pre-spike pulse and the first post-spike pulse, respectively.

A three-dimensional array device with multiple layers in height direction includes a first two-dimensional array circuit located in a first layer; and a second two-dimensional array circuit located in a second layer adjacent to the first layer and overlapped in a plan view with the first two-dimensional array circuit. Each of the first two-dimensional array circuit and the second two-dimensional array circuit has a first wiring group, an input part that inputs signals to the first wiring group, a second wiring group that intersects the first wiring group and an output part that outputs signals from the second wiring group. The output part in the first two-dimensional array circuit is overlapped in a plan view on the input part in the second two-dimensional array circuit and is connected in a signal transferable manner.

A 3D semiconductor device including: a first single crystal layer with first transistors; overlaid by a first metal layer; a second metal layer overlaying the first metal layer and being overlaid by a third metal layer; a logic gates including at least the first metal layer interconnecting the first transistors; second transistors disposed atop the third metal layer; third transistors disposed atop the second transistors; a top metal layer disposed atop the third transistors; and a memory array including word-lines, and at least four memory mini arrays, where each of the memory mini arrays includes at least four rows by four columns of memory cells, where each of the memory cells includes at least one of the second transistors or third transistors, sense amplifier circuit(s) for each of the memory mini arrays, the second metal layer provides a greater current carrying capacity than the third metal layer.

A 3D semiconductor device including: a first single crystal layer with first transistors; overlaid by a first metal layer; a second metal layer overlaying the first metal layer and being overlaid by a third metal layer; a logic gates including at least the first metal layer interconnecting the first transistors; second transistors disposed atop the third metal layer; third transistors disposed atop the second transistors; a top metal layer disposed atop the third transistors; and a memory array including word-lines, and at least four memory mini arrays, where each of the memory mini arrays includes at least four rows by four columns of memory cells, where each of the memory cells includes at least one of the second transistors or third transistors, sense amplifier circuit(s) for each of the memory mini arrays, the second metal layer provides a greater current carrying capacity than the third metal layer.

Embodiments provide a memory structure, including: a capacitive structure, provided with an upper electrode layer; a conductive column, arranged on the upper electrode layer, and in contact with and electrically connected to the upper electrode layer; a metal layer, arranged on a side of the conductive column away from the upper electrode layer, the conductive column being in contact with a surface of the metal layer facing the upper electrode layer; and at least one buffer column, spaced apart from the conductive column, in contact with the surface of the metal layer facing the upper electrode layer, and extending in a direction from the metal layer to the upper electrode layer.

A magnetoresistance effect element has a first ferromagnetic metal layer, a second ferromagnetic metal layer, and a tunnel barrier layer that is sandwiched between the first and second ferromagnetic metal layers, and the tunnel barrier layer has a spinel structure represented by a composition formula of AIn.sub.2O.sub.x (0<x≤4), and an A-site is a non-magnetic divalent cation which is one or more selected from a group consisting of magnesium, zinc and cadmium.

A magnetoresistance effect element has a first ferromagnetic metal layer, a second ferromagnetic metal layer, and a tunnel barrier layer that is sandwiched between the first and second ferromagnetic metal layers, and the tunnel barrier layer has a spinel structure represented by a composition formula of AIn.sub.2O.sub.x (0<x≤4), and an A-site is a non-magnetic divalent cation which is one or more selected from a group consisting of magnesium, zinc and cadmium.

A semiconductor storage according to an embodiment of the present disclosure includes two power source paths, and a connection path that connects the power source paths. Each of the power source paths includes a power gate transistor and a current source transistor which are coupled in series. The connection path connects ends of the respective power source paths on a side of the current source transistor. The semiconductor storage further includes a storage element, and a switch element inserted between the connection path and the storage element. A back gate is coupled to an internal node in the current source transistor provided in a low-side path of the two power source paths.

A transistor includes a first gate electrode, a composite channel layer, a first gate dielectric layer, and source/drain contacts. The composite channel layer is over the first gate electrode and includes a first capping layer, a crystalline semiconductor oxide layer, and a second capping layer stacked in sequential order. The first gate dielectric layer is located between the first gate electrode and the composite channel layer. The source/drain contacts are disposed on the composite channel layer.

A magnetoresistance effect element includes a wiring that extends in a first direction, a laminate that includes a first ferromagnetic layer connected to the wiring, a first conductive part and a second conductive part that sandwich the first ferromagnetic layer therebetween in a plan view in a lamination direction, and a resistor that has a geometrical center overlapping a geometrical center of the first conductive part or farther away from the laminate than the geometrical center of the first conductive part in the first direction when viewed in a plan view in the lamination direction.