An object is to shorten the time for rewriting data in memory cells. A memory module includes a first memory cell, a second memory cell, a selection transistor, and a wiring WBL1. The first memory cell includes a first memory node. The second memory cell includes a second memory node. One end of the first memory cell is electrically connected to the wiring WBL1 through the selection transistor. The other end of the first memory cell is electrically connected to one end of the second memory cell. The other end of the second memory cell is electrically connected to the wiring WBL1. When the selection transistor is on, data in the first memory node is rewritten by a signal supplied through the selection transistor to the wiring WBL1. When the selection transistor is off, data in the first memory node is rewritten by a signal supplied through the second memory node to the wiring WBL1.

To further reduce contact resistance when a current or a voltage is taken out from a metal layer. A conductive structure including: an insulating layer; a metal layer provided on one surface of the insulating layer to protrude in a thickness direction of the insulating layer; and a two-dimensional material layer provided along outer shapes of the metal layer and the insulating layer from a side surface of the metal layer to the one surface of the insulating layer.

It is a two-dimensional semiconductor-metal ohmic-contact structure, a preparation method therefor and use thereof, wherein the ohmic-contact structure comprises two-dimensional semiconductor having semimetal antimony or an alloy containing semimetal antimony deposited thereon to form an ideal van der Waals interface with strong orbital hybridization, and semimetal antimony is deposited on the two-dimensional semiconductor by high-vacuum evaporation; which is applied to semiconductor devices and realizes ultralow contact resistance between the metal and the two-dimensional semiconductor and significantly improve the performance of two-dimensional semiconductor devices.

It is a two-dimensional semiconductor-metal ohmic-contact structure, a preparation method therefor and use thereof, wherein the ohmic-contact structure comprises two-dimensional semiconductor having semimetal antimony or an alloy containing semimetal antimony deposited thereon to form an ideal van der Waals interface with strong orbital hybridization, and semimetal antimony is deposited on the two-dimensional semiconductor by high-vacuum evaporation; which is applied to semiconductor devices and realizes ultralow contact resistance between the metal and the two-dimensional semiconductor and significantly improve the performance of two-dimensional semiconductor devices.

A method includes placing a semiconductor substrate in a deposition chamber, wherein the semiconductor substrate includes a trench, and performing an atomic layer deposition (ALD) process to deposit a dielectric material within the trench, including flowing a first precursor of the dielectric material into the deposition chamber as a gas phase; flowing a second precursor of the dielectric material into the deposition chamber as a gas phase; and controlling the pressure and temperature within the deposition chamber such that the second precursor condenses on surfaces within the trench as a liquid phase of the second precursor, wherein the liquid phase of the second precursor has capillarity.

A method includes placing a semiconductor substrate in a deposition chamber, wherein the semiconductor substrate includes a trench, and performing an atomic layer deposition (ALD) process to deposit a dielectric material within the trench, including flowing a first precursor of the dielectric material into the deposition chamber as a gas phase; flowing a second precursor of the dielectric material into the deposition chamber as a gas phase; and controlling the pressure and temperature within the deposition chamber such that the second precursor condenses on surfaces within the trench as a liquid phase of the second precursor, wherein the liquid phase of the second precursor has capillarity.

A method includes placing a semiconductor substrate in a deposition chamber, wherein the semiconductor substrate includes a trench, and performing an atomic layer deposition (ALD) process to deposit a dielectric material within the trench, including flowing a first precursor of the dielectric material into the deposition chamber as a gas phase; flowing a second precursor of the dielectric material into the deposition chamber as a gas phase; and controlling the pressure and temperature within the deposition chamber such that the second precursor condenses on surfaces within the trench as a liquid phase of the second precursor, wherein the liquid phase of the second precursor has capillarity.

A transistor may be provided by forming, in a forward order or in a reverse order, a gate electrode, a semiconducting metal oxide liner, a gate dielectric, and an active layer over a substrate, and by forming a source electrode and a drain electrode on end portions of the active layer. The semiconducting metal oxide liner comprises a thin semiconducting metal oxide material that functions as a hydrogen barrier material.

A transistor may be provided by forming, in a forward order or in a reverse order, a gate electrode, a semiconducting metal oxide liner, a gate dielectric, and an active layer over a substrate, and by forming a source electrode and a drain electrode on end portions of the active layer. The semiconducting metal oxide liner comprises a thin semiconducting metal oxide material that functions as a hydrogen barrier material.

A semiconductor apparatus capable of reducing the leakage current in the reverse direction, and keeping characteristics thereof, even when using n type semiconductor (gallium oxide, for example) or the like having a low-loss at a high voltage and having much higher dielectric breakdown electric field strength than SiC is provided. A semiconductor apparatus includes a crystalline oxide semiconductor having a corundum structure as a main component, and an electric field shield layer and a gate electrode that are respectively laminated directly or through other layers on the n type semiconductor layer, wherein the electric field shield layer includes a p type oxide semiconductor, and is embedded in the n type semiconductor layer deeper than the gate electrode.