Abstract: An integrated circuit structure includes: a field-effect transistor including a semiconductor region including a semiconductor material having a bandgap less than or equal to that of silicon, a semiconductor source and a semiconductor drain, the semiconductor region being between the semiconductor source and the semiconductor drain, a gate electrode, a gate dielectric between the semiconductor region and the gate electrode, a source contact adjacent to the semiconductor source, and a drain contact adjacent to the semiconductor drain; and a resistive switch or a capacitor electrically connected to the drain contact. One of the source contact and the drain contact includes a threshold switching region, to be a selector for the resistive switch or the capacitor. In some embodiments, the threshold switching region includes a threshold switching oxide or a threshold switching chalcogenide, and the resistive switch or the capacitor is part of a resistive memory cell or capacitive memory cell.

Abstract: An embodiment includes a system comprising: a thin film transistor (TFT) comprising a source, a channel, a drain, and a gate; first, second, and third dielectric portions; wherein (a) a first vertical axis intersects the source, the channel, and the drain; (b) the first dielectric portion surrounds the source in a first plane; (c) the second dielectric portion surrounds the channel in a second plane; (d) the third dielectric surrounds the drain in a third plane; (e) a second vertical axis intersects the first, second, and third dielectric portions; (f) the source includes a first dopant, the first dielectric portion includes the first dopant, the second dielectric portion includes at least one of the first dopant and a second dopant, the drain includes the at least one of the first and second dopants, and the third dielectric portion includes the at least one of the first and second dopants.

Abstract: A perpendicular spin transfer torque memory (pSTTM) device incorporates a magnetic tunnel junction (MTJ) device having a free magnetic stack that includes a plurality of magnetic layers interleaved with a plurality of non-magnetic insert layers. The layers are arranged such that the topmost and bottommost layers are magnetic layers. The stacked design decreases the damping of the MTJ free magnetic stack, beneficially reducing the write current required to write to the pSTTM device. The stacked design further increases the interface anisotropy, thereby beneficially improving the stability of the pSTTM device. The non-magnetic interface layer may include tantalum, molybdenum, tungsten, hafnium, or iridium, or a binary alloy containing at least two of tantalum, molybdenum, tungsten hafnium, or iridium.

Abstract: Thin film transistors having relatively increased width and shared bitlines are described. In an example, an integrated circuit structure includes a plurality of transistors formed in an insulator structure above a substrate. The plurality of transistors arranged in a column such that the respective lateral arrangement of the source, the gate, and the drain of each of the transistors aligns with an adjacent thin film transistor, wherein the plurality transistors extend vertically through the insulator structure at least two interconnect levels to provide increased relative width. A first conductive contact is formed between one of sources and drains of at least two of the plurality of transistors in the column, and the conductive contact extends through the insulator structure at least two interconnect levels.

Abstract: A 2T-2S SRAM cell exhibiting a complementary scheme, that includes two selector devices that exhibit negative differential resistance. Advantages include lower area and better performance than traditional SRAM cells, according to some embodiments. The term 1T-1S refers to a transistor in series with a selector device. Accordingly, the term 2T-2S refers to two such 1T-1S structures.

Abstract: Systems, apparatus, and methods for magnetoresitive memory are described. An apparatus for magnetoresitive memory includes a fixed layer, a free layer, and a tunneling barrier between the fixed layer and the free layer. The free layer is a new alloy consisting of a composition of Cobalt (Co), Iron (Fe), and Boron (B) intermixed with a non-magnetic metal according to a ratio. A thin insert layer of CoFeB may optionally be added between the alloy and the tunneling barrier.

Abstract: Described herein are apparatuses, systems, and methods associated with a memory circuit that includes memory cells having respective threshold switches. The memory cells may include a selector transistor with a gate terminal coupled to a word line to receive a word line signal, a drain terminal coupled to a bit line to receive a bit line signal, and a source terminal coupled to a first terminal of the threshold switch. The threshold switch may switch from a high resistance state to a low resistance state when a voltage across the first terminal and a second terminal exceeds a threshold voltage and may remain in the low resistance state after switching when the voltage across the first and second terminals is equal to or greater than a holding voltage that is less than the threshold voltage. Other embodiments may be described and claimed.

Abstract: A method of fabricating a MOS transistor having a thinned channel region is described. The channel region is etched following removal of a dummy gate. The source and drain regions have relatively low resistance with the process.

Abstract: A perpendicular spin transfer torque memory (pSTTM) device incorporates a magnetic tunnel junction (MTJ) device having a free magnetic stack and a fixed magnetic stack separated by a dielectric tunneling layer. The free magnetic stack includes an uppermost magnetic layer that is at least partially covered by a cap layer. The cap layer is at least partially covered by a protective layer containing at least one of: ruthenium (Ru); cobalt/iron/boron (CoFeB); molybdenum (Mo); cobalt (Co); tungsten (W); or platinum (Pt). The protective layer is at least partially covered by a cap metal layer which may form a portion of MTJ electrode. The protective layer minimizes the occurrence of physical and/or chemical attack of the cap layer by the materials used in the cap metal layer, beneficially improving the interface anisotropy of the MTJ free magnetic layer.

Abstract: Techniques are disclosed for forming integrated circuit (IC) devices that include ferroelectric field-effect transistors (FE-FETs) having a top gate and a bottom gate (or, generally, a dual-gate configuration). The disclosed FE-FET devices may be formed in the back end of the IC structure and may be implemented with various materials that exhibit ferroelectric properties when processed at temperatures within the thermal budget of the back-end processing. The disclosed back-end FE-FET devices can achieve greater than two resistance states, depending on the direction of poling of the top and bottom gates, thereby enabling the formation of 3-state and 4-state memory devices, for example. Additionally, as will be appreciated in light of this disclosure, the disclosed back-end FE-FET devices can free up floor space in the front-end, thereby providing space for additional devices in the front-end.

Abstract: A method of fabricating a MOS transistor having a thinned channel region is described. The channel region is etched following removal of a dummy gate. The source and drain regions have relatively low resistance with the process.

Abstract: Resistive memory cells, precursors thereof, and methods of making resistive memory cells are described. In some embodiments, the resistive memory cells are formed from a resistive memory precursor that includes a switching layer precursor containing a plurality of oxygen vacancies that are present in a controlled distribution therein, optionally without the use of an oxygen exchange layer. In these or other embodiments, the resistive memory precursors described may include a second electrode formed on a switching layer precursor, wherein the second electrode is includes a second electrode material that is conductive but which does not substantially react with oxygen. Devices including resistive memory cells are also described.

Abstract: Spin transfer torque memory (STTM) devices incorporating an Insulator-Metal-Transition (IMT) device or at least one layer of Insulator-Metal-Transition (IMT) material are disclosed. The Insulator-Metal-Transition (IMT) device or at least one layer of Insulator-Metal-Transition (IMT) material are utilized for providing a spike current when the voltage across it exceeds the threshold voltage to reduce a critical current required for transfer torque induced magnetization switching.

Abstract: Strain engineering of perpendicular magnetic tunnel junctions (PMTJs) is described. In an example, a memory structure includes a perpendicular magnetic tunnel junction (pMTJ) element disposed above a substrate. A lateral strain-inducing material layer is disposed on the pMTJ element. An inter-layer dielectric (ILD) layer disposed laterally adjacent to both the pMTJ element and the lateral strain-inducing material layer.

Abstract: MTJ material stacks, pSTTM devices employing such stacks, and computing platforms employing such pSTTM devices. In some embodiments, perpendicular MTJ material stacks include a multi-layered filter stack disposed between a fixed magnetic layer and an antiferromagnetic layer or synthetic antiferromagnetic (SAF) stack. In some embodiments, non-magnetic layers of the filter stack include at least one of Ta, Mo, Nb, W, or Hf. These transition metals may be in pure form or alloyed with other constituents.

Abstract: Spin transfer torque memory (STTM) devices incorporating an Insulator-Metal-Transition (IMT) device or at least one layer of Insulator-Metal-Transition (IMT) material are disclosed. The Insulator-Metal-Transition (IMT) device or at least one layer of Insulator-Metal-Transition (IMT) material are utilized for providing a spike current when the voltage across it exceeds the threshold voltage to reduce a critical current required for transfer torque induced magnetization switching.

Abstract: An embedded cross-point memory array is described. In an example, an integrated circuit structure includes a first die including a cross-point memory array comprising separate memory blocks, the memory blocks including orthogonally arranged conductive lines, and memory elements at cross-sections of the conductive lines. A first plurality of sockets is on the first die adjacent to the memory blocks, the first plurality of sockets comprising a first plurality of pads that connect to at least a portion to the conductive lines of the corresponding memory block. A second die includes logic circuitry and a second plurality of sockets comprising a second plurality of pads at least partially aligned with positions of the first plurality of pads on the first die. A top of the first die and a top of the second die face one another, wherein the first plurality of pads are bonded with the second plurality pads to directly connect the cross-point memory array to the logic circuitry.

Abstract: An embodiment includes an apparatus including: a substrate; a perpendicular magnetic tunnel junction (pMTJ), on the substrate, including a first fixed layer, a second fixed layer, and a free layer between the first and second fixed layers; a first dielectric layer between the first fixed layer and the free layer; and a second layer between the second fixed layer and the free layer. Other embodiments are described herein.

Abstract: An embodiment includes an apparatus comprising: a substrate; a magnetic tunnel junction (MTJ), on the substrate, comprising a fixed layer, a free layer, and a dielectric layer between the fixed and free layers; and a first synthetic anti-ferromagnetic (SAF) layer, a second SAF layer, and an intermediate layer, which includes a non-magnetic metal, between the first and second SAF layers; wherein the first SAF layer includes a Heusler alloy. Other embodiments are described herein.

Abstract: Electronic devices, memory devices, and computing devices are disclosed. An electronic device includes electronic circuitry, a temperature sensor, a heat sink, at least one thermoelectric material, a thermally conductive material configured to thermally couple the electronic circuitry to the at least one thermoelectric material, and a transistor. The temperature sensor is configured to monitor a temperature of the electronic circuitry. The transistor is configured to selectively enable thermoelectric current to flow through the at least one thermoelectric material and dissipate heat from the thermally conductive material to the heat sink responsive to fluctuations in the temperature of the electronic circuitry detected by the temperature sensor.