A method includes forming a metal-insulator-semiconductor (MIS) structure, in which the MIS structure includes a semiconductor layer, an insulating layer over the semiconductor layer, and a metal electrode layer over the insulating layer; performing a soft breakdown process to the MIS structure to form a local breakdown portion in the insulating layer; performing a first write operation by supplying a first voltage pulse; performing a first read operation by supplying a second voltage pulse and detecting a first read current flowing through the MIS structure; performing a second write operation by supplying a third voltage pulse, in which the first voltage pulse has a higher voltage level than the third voltage pulse; and performing a second read operation by supplying a fourth voltage pulse and detecting a second read current flowing through the MIS structure, in which the first read current is different from the second read current.

A configurable impeder is provided. The configurable impeder comprises of multiple CESs. Each of the CESs is capable of being configured into one of a plurality of impedance states. Further, a programing circuit is provided. The programing circuit provides a plurality of programing signals in dependence of an input signal. Each programing signal configures an impedance state of a respective CES from the plurality of CESs.

A configurable impeder is provided. The configurable impeder comprises of multiple CESs. Each of the CESs is capable of being configured into one of a plurality of impedance states. Further, a programing circuit is provided. The programing circuit provides a plurality of programing signals in dependence of an input signal. Each programing signal configures an impedance state of a respective CES from the plurality of CESs.

A configurable impeder is provided. The configurable impeder comprises of multiple CESs. Each of the CESs is capable of being configured into one of a plurality of impedance states. Further, a programing circuit is provided. The programing circuit provides a plurality of programing signals in dependence of an input signal. Each programing signal configures an impedance state of a respective CES from the plurality of CESs.

A configurable impeder is provided. The configurable impeder comprises of multiple CESs. Each of the CESs is capable of being configured into one of a plurality of impedance states. Further, a programing circuit is provided. The programing circuit provides a plurality of programing signals in dependence of an input signal. Each programing signal configures an impedance state of a respective CES from the plurality of CESs.

A configurable impeder is provided. The configurable impeder comprises of multiple CESs. Each of the CESs is capable of being configured into one of a plurality of impedance states. Further, a programing circuit is provided. The programing circuit provides a plurality of programing signals in dependence of an input signal. Each programing signal configures an impedance state of a respective CES from the plurality of CESs.

Described is a memory bit-cell comprising: a storage node; an access transistor coupled to the storage node; a capacitor having a first terminal coupled to the storage node; and one or more negative differential resistance devices coupled to the storage node such that the memory bit-cell is without one of a ground line or a supply line or both.

Described is a memory bit-cell comprising: a storage node; an access transistor coupled to the storage node; a capacitor having a first terminal coupled to the storage node; and one or more negative differential resistance devices coupled to the storage node such that the memory bit-cell is without one of a ground line or a supply line or both.

A semiconductor device that has reduced power consumption and is capable of non-destructive reading is provided. The semiconductor device includes a first circuit including a first transistor and a first FTJ element, and a second circuit including a second transistor and a second FTJ element. A first terminal of the first transistor is electrically connected to an output terminal of the first FTJ element, and a first terminal of the second transistor is electrically connected to an input terminal of the second FTJ element. A second terminal of the first transistor and a second terminal of the second transistor are electrically connected to a read circuit. In a data writing method, a voltage is applied between the input terminal and the output terminal of each of the first FTJ element and the second FTJ element to polarize the first FTJ element and the second FTJ element. In a data reading method, a differential current flowing through the first FTJ element and the second FTJ element is input to the read circuit.