The invention relates to a method for regulating, by means of a computer, a resistive element arranged to deice and/or demist a support, the method comprising:

a) a loop for monitoring the temperature T and the moisture level H at the support;

b) a deicing and/or demisting sequence which, as long as the temperature T and the moisture level H monitored by the monitoring loop a) are indicative of an absence of frost or mist on the support, keeps the resistive element inactive and, in the contrary case, demands, in a step b2), the circulation of a current I in the resistive element so that the latter dissipates a thermal power P.sub.th, adjusted according to the temperature T and the moisture level H, and providing deicing or demisting of the support over a predetermined period D.sub.p.

A memtransistor includes a top gate electrode and a bottom gate electrode; a polycrystalline monolayer film formed of an atomically thin material disposed between the top gate electrode and the bottom gate electrode; and source and drain electrodes spatial-apart formed on the polycrystalline monolayer film to define a channel in the polycrystalline monolayer film between the source and drain electrodes. The top gate electrode and the bottom gate electrode are capacitively coupled with the channel.

A method for manufacturing a semiconductor device, a first structure is formed on a first substrate. A first bonded body is formed by bonding a supporting substrate lower in rigidity than the first substrate to a first principal surface, on which the first structure is formed, of the first substrate. The first substrate is removed from the first bonded body. A second structure is formed on a second substrate. A third structure is formed on a third substrate. A second bonded body is formed by bonding a second principal surface, on which the second structure is formed, of the second substrate to a third principal surface, on which the third structure is formed, of the third substrate. The second substrate is removed from the second bonded body. A third bonded body is formed by bonding a fourth principal surface, which is exposed after the first substrate is removed, of the first bonded body to a fifth principal surface, which is exposed after the second substrate is removed, of the second bonded body. The supporting substrate is removed from the third bonded body.

Provided is a memory device including a gate electrode, a first insulation layer on the gate electrode, a first conductive pattern and a second conductive pattern, which are spaced apart from each other on the first insulation layer, a channel pattern disposed on the first insulation layer to connect the first conductive pattern and the second conductive pattern, and an interface layer disposed between the channel pattern and the first insulation layer and having a hydrogen atom content ratio (atomic %) greater than that of the first insulation layer.

A method and resulting structures for a semiconductor device includes forming a source terminal of a semiconductor fin on a substrate. An energy barrier is formed on a surface of the source terminal. A channel is formed on a surface of the energy barrier, and a drain terminal is formed on a surface of the channel. The drain terminal and the channel are recessed on either sides of the channel, and the energy barrier is etched in recesses formed by the recessing. The source terminal is recessed using timed etching to remove a portion of the source terminal in the recesses formed by etching the energy barrier. A first bottom spacer is formed on a surface of the source terminal and a sidewall of the semiconductor fin, and a gate stack is formed on the surface of the first bottom spacer.

A transistor comprises a channel region between a source region and a drain region, a dielectric material adjacent to the channel region, an electrode adjacent to the dielectric material, and an electrolyte between the dielectric material and the electrode. Related semiconductor devices comprising at least one transistors, related electronic systems, and related methods are also disclosed.

A voltage-variable type memory element having an electrode; a charge storage layer that is arranged on the electrode via a first interlayer insulating layer and stores charges; and a semiconductor wiring which has electric conductivity, that is arranged on the charge storage layer via a second interlayer insulating layer, and comprises a region facing the charge storage layer, a resistance value of the region being variable according to magnitude of potential corresponding to an amount of charges stored in the charge storage layer, and a voltage value of a reading signal supplied and passing through the semiconductor wiring being varied according to the resistance value. A semiconductor memory device configure to a memory cell array in which voltage-variable type memory elements are arranged as memory cells.

Methods of forming a compact FDSOI OTP/MTP cell and a compact FinFET OTP/MTP cell and the resulting devices are provided. Embodiments include forming a SOI region or a fin over a BOX layer over a substrate; forming a first and a second gate stack, laterally separated, over respective portions of the SOI region or the fin; forming a first and a second liner along each first and second sidewall and of the first and the second gate stack, respectively, the second sidewall over respective portions of the SOI region or the fin; forming a spacer on each first and second liner; forming a S/D region in the SOI region or the fin between the first and the second gate stack; forming a CA over the S/D region; utilizing each gate of the first gate stack and the second gate stack as a WL; and connecting a BL to the CA.

A first memory unit includes a first bipolar-variable-resistance and a first control transistor. This first memory unit is configured to provide a function of a flash memory with first bipolar-variable-resistance transistor serving as a storage. In addition, a second bipolar-variable-resistance transistor and a second control transistor with the same structure as first memory unit can be used to serve as a second memory unit. An isolation transistor is connected between the first memory unit and the second memory unit. The isolation transistor can electrically isolate the first memory unit and the second memory unit from each other, thereby preventing sneak current from flowing between arrays among memory circuits.

Methods of forming a compact FDSOI OTP/MTP cell and a compact FinFET OTP/MTP cell and the resulting devices are provided. Embodiments include forming a SOI region or a fin over a BOX layer over a substrate; forming a first and a second gate stack, laterally separated, over respective portions of the SOI region or the fin; forming a first and a second liner along each first and second sidewall and of the first and the second gate stack, respectively, the second sidewall over respective portions of the SOI region or the fin; forming a spacer on each first and second liner; forming a S/D region in the SOI region or the fin between the first and the second gate stack; forming a CA over the S/D region; utilizing each gate of the first gate stack and the second gate stack as a WL; and connecting a BL to the CA.