Abstract: A semiconductor device includes a substrate, a first dielectric layer, a channel layer and source/drain electrodes. The first dielectric layer is over the substrate. The channel layer is over the first dielectric layer. Source/drain electrodes are over the channel layer. The source/drain electrodes comprise a 2D semimetal material. The channel layer comprises a 2D semiconductor material interfacing the 2D semimetal material of the source/drain electrodes.

Abstract: A plasma enhanced chemical vapor deposition (PECVD) method includes loading a wafer having a magnetic layer thereon into a processing chamber equipped with a radio frequency (RF) system, introducing an aromatic hydrocarbon precursor into the processing chamber, and turning on an RF source of the RF system to decompose the aromatic hydrocarbon precursor into active radicals at a frequency greater than about 1000 Hz to form a graphene layer over the magnetic layer.

Abstract: A method includes loading a wafer having a dielectric layer thereon into a processing chamber; introducing a hydrocarbon precursor into the processing chamber; pyrolyzing the hydrocarbon precursor; introducing the pyrolyzed hydrocarbon precursor to the dielectric layer to form a graphene layer on the dielectric layer at a temperature lower than about 400° C.

Abstract: A method includes forming a first electrode layer on a substrate; depositing a transition metal layer on the first electrode layer, introducing a chalcogen precursor around the transition metal layer; performing a plasma treatment to ionize the chalcogen precursor around the transition metal layer to convert the transition metal layer into a transition metal dichalcogenide (TMDC) layer at a temperature lower than about 400° C.; forming a second electrode layer on the TMDC layer.

Abstract: A method includes loading a wafer having a catalytic metal thereon into a processing chamber, introducing a hydrocarbon precursor into the processing chamber, pyrolyzing the hydrocarbon precursor; conducting the pyrolyzed hydrocarbon precursor to the catalytic metal to form a graphene layer on the catalytic metal at a temperature lower than about 400° C.

Abstract: An integrated circuit device includes a substrate, a first transition metal dichalcogenide layer over the substrate, a dielectric layer over the first transition metal dichalcogenide layer, a first gate electrode, and a first source contact and a first drain contact. The first transition metal dichalcogenide layer has a surface roughness greater than 0.5 nm and less than 1 nm. The first gate electrode is over the dielectric layer and a first portion of the first transition metal dichalcogenide layer. The first source contact and the first drain contact are respectively connected with a second portion and a third portion of the first transition metal dichalcogenide layer. The first portion of the first transition metal dichalcogenide layer is between the second and third portions of the first transition metal dichalcogenide layer.

Abstract: A method for forming an integrated circuit device is provided. The method includes forming a transistor over a frontside of a substrate; forming an interconnect structure over the transistor; depositing a first transition metal layer over the interconnect structure; performing a plasma treatment to turn the first transition metal layer into a first transition metal dichalcogenide layer; forming a dielectric layer over the first transition metal dichalcogenide layer; forming a first gate electrode over the dielectric layer and a first portion of the first transition metal dichalcogenide layer; and forming a first source contact and a first drain contact respectively connected with a second portion and a third portion of the first transition metal dichalcogenide layer, the first portion of the first transition metal dichalcogenide layer being between the second and third portions of the first transition metal dichalcogenide layers.

Abstract: A device includes a substrate, a chalcogenide channel layer, a chalcogenide barrier layer, source/drain contacts, and a gate electrode. The chalcogenide channel layer is over the substrate. The chalcogenide barrier layer is over the chalcogenide channel layer. A dopant concentration of the chalcogenide barrier layer is greater than a dopant concentration of the chalcogenide channel layer. The source/drain contacts are over the chalcogenide channel layer. The gate electrode is over the substrate.

Abstract: A semiconductor structure includes a semiconductor substrate, a gate structure, a source/drain structure, a contact, a dielectric layer, and a metal line. The gate structure is on the semiconductor substrate. The source/drain structure is adjacent to the gate structure. The contact lands on the source/drain structure. The dielectric layer spas the contact and the gate structure. The metal line extends through the dielectric layer to the contact. The metal line includes a liner over the contact, a magnetic layer over the liner, a graphene layer over the magnetic layer, and a filling metal over the graphene layer. The magnetic layer has a greater permeability coefficient than the filling metal.

Abstract: A device includes a substrate, a channel layer, a barrier layer, a gate electrode, and source/drain contacts. The channel layer is made of transition metal dichalcogenide. The barrier layer is over the channel layer. The gate electrode is over the barrier layer. The source/drain contacts are on opposite sides of the gate electrode and over the barrier layer.

Abstract: A method includes forming a 2-D semiconductor material layer over a substrate; forming source/drain contacts over source/drain regions of the 2-D semiconductor material layer; and forming a gate structure over a channel region of the 2-D semiconductor material layer. Forming the source/drain contacts includes performing a first deposition process to deposit a first metal layer over the 2-D semiconductor material layer; and after the first deposition process is completed, performing a second deposition process to deposit a second metal layer over the first metal layer, in which the second metal layer has a higher melting point than the first metal layer.

Abstract: A method includes forming a transistor over a substrate; and forming a resistive element over the transistor, in which forming the resistive element includes forming a bottom electrode electrically connected to a source/drain region of the transistor; forming a resistive switching layer over the bottom electrode, in which the resistive switching layer is made of metal halide; and forming a top electrode over the resistive switching layer.

Abstract: A method for forming an integrated circuit device is provided. The method includes forming a transistor over a frontside of a substrate; forming an interconnect structure over the transistor; depositing a first transition metal layer over the interconnect structure; performing a plasma treatment to turn the first transition metal layer into a first transition metal dichalcogenide layer; forming a dielectric layer over the first transition metal dichalcogenide layer; forming a first gate electrode over the dielectric layer and a first portion of the first transition metal dichalcogenide layer; and forming a first source contact and a first drain contact respectively connected with a second portion and a third portion of the first transition metal dichalcogenide layer, the first portion of the first transition metal dichalcogenide layer being between the second and third portions of the first transition metal dichalcogenide layers.

Abstract: A device includes a substrate, a channel layer, a barrier layer, a gate electrode, and source/drain contacts. The channel layer is made of transition metal dichalcogenide. The barrier layer is over the channel layer. The gate electrode is over the barrier layer. The source/drain contacts are on opposite sides of the gate electrode and over the barrier layer.

Abstract: A plasma enhanced chemical vapor deposition (PECVD) method includes loading a wafer having a magnetic layer thereon into a processing chamber equipped with a radio frequency (RF) system, introducing an aromatic hydrocarbon precursor into the processing chamber, and turning on an RF source of the RF system to decompose the aromatic hydrocarbon precursor into active radicals at a frequency greater than about 1000 Hz to form a graphene layer over the magnetic layer.

Abstract: A semiconductor device includes a substrate, a channel stack, source/drain contacts, and a gate electrode. The channel stack is over the substrate and includes a 2D channel layer and a barrier layer. An energy band gap of the barrier layer is greater than an energy band gap of the 2D channel layer. The source/drain contacts are in contact with the channel stack. The gate electrode is above the substrate.

Abstract: A method includes loading a wafer into a processing chamber, wherein the processing chamber is wound by a coil, and the coil is coupled to an RF system; supplying an aromatic hydrocarbon precursor into the processing chamber; after supplying the aromatic hydrocarbon precursor, turning on an RF power of the RF system to decompose the aromatic hydrocarbon precursor into active radicals and cyclize the active radicals into a graphene layer over a metal layer on the wafer; and after an entirety of the metal layer being covered by the graphene layer, turning off the RF power of the RF system to stop forming the graphene layer.

Abstract: A method includes loading a wafer into a processing chamber, wherein the processing chamber is wound by a coil, and the coil is coupled to an RF system; supplying an aromatic hydrocarbon precursor into the processing chamber; after supplying the aromatic hydrocarbon precursor, turning on an RF power of the RF system to decompose the aromatic hydrocarbon precursor into active radicals and cyclize the active radicals into a graphene layer over a metal layer on the wafer; and after an entirety of the metal layer being covered by the graphene layer, turning off the RF power of the RF system to stop forming the graphene layer.

Abstract: A semiconductor device includes a substrate, a channel stack, source/drain contacts, and a gate electrode. The channel stack is over the substrate and includes a 2D channel layer and a barrier layer. An energy band gap of the barrier layer is greater than an energy band gap of the 2D channel layer. The source/drain contacts are in contact with the channel stack. The gate electrode is above the substrate.