Abstract: The three-state spintronic device includes: a bottom electrode, a magnetic tunnel junction and a top electrode from bottom to top. The magnetic tunnel junction includes: a spin-orbit coupling layer, a ferromagnetic free layer, a barrier tunneling layer, a ferromagnetic reference layer, three local magnetic domain wall pinning centers and domain wall nucleation centers. An antisymmetric exchange interaction is modulated, and the magnetic domain wall pinning centers are embedded in an interface between a heavy metal and the ferromagnetic free layer. The magnetic domain wall nucleation centers are at two ends of the ferromagnetic free layer. A current pulse flows through the spin-orbit coupling layer to generate a spin current and the spin current is injected into the ferromagnetic free layer. Under a control of all-electrical controlled, an effective field of a spin-orbit torque drives domain wall to move and displace.

Abstract: The present disclosure provides a method for fabricating an anti-reflective layer on a quartz surface by using a metal-induced self-masking etching technique, comprising: performing reactive ion etching to a metal material and a quartz substrate by using a mixed gas containing a fluorine-based gas, wherein metal atoms and/or ions of the metal material are sputtered to a surface of the quartz substrate, to form a non-volatile metal fluoride on the surface of the quartz substrate; forming a micromask by a product of etching generated by reactive ion etching gathering around the non-volatile metal fluoride; and etching the micromask and the quartz substrate simultaneously, to form an anti-reflective layer having a sub-wavelength structure.

Abstract: A multi-band and multi-functional antenna integrated module and a preparation method thereof are provided. The multi-band and multi-functional antenna integrated module has an electromagnetic wave capture layer, a frequency selection circuit layer, and a signal processing circuit layer stacked vertically in sequence. The frequency selection circuit layer and the frequency selection circuit layer are interconnected through a metallized through hole. The frequency selection circuit layer has a plurality of frequency selection circuit units with different processing bands. The signal processing circuit layer has a plurality of signal processing circuit units with different functions. The plurality of frequency selection circuit units are interconnected to the plurality of signal processing circuit units in a one-to-one correspondence manner through a plurality of metallized through holes.

Abstract: The present disclosure provides a semiconductor device and a method of manufacturing the same thereof, and an electronic apparatus including the semiconductor device. According to embodiments of the present disclosure, the semiconductor device includes a channel portion, source/drain portions connected to the channel portion on two opposite sides of the channel portion, and a gate stack intersecting with the channel portion. The channel portion includes a first portion extending in a vertical direction with respect to a substrate and a second portion extending from the first portion to two opposite sides in a lateral direction with respect to the substrate, respectively.

Abstract: The memory circuit structure includes: a storage array, wherein the storage array includes at least two storage units; a decoder connected with a bit line and a word line of the storage array respectively; a programming circuit configured to generate a voltage pulse or a constant current pulse; a polarity switching circuit connected with the programming circuit, and configured to implement a switching between a voltage programming and a current programming of the programming circuit under a set operation and a reset operation; a detection circuit connected with the storage array, and configured to detect a detection signal of a current or a voltage corresponding to the specific storage unit in the storage array and feed back the detection signal to a control unit, wherein the detection signal output by the detection circuit is configured to enable the polarity switching circuit to switch; and the control unit.

Abstract: A complementary storage unit and a method of preparing the same, and a complementary memory. The complementary storage unit includes: a control transistor, a pull-up diode and a pull-down diode. The control transistor is configured to control reading and writing of the storage unit. One end of the pull-up diode is connected to a positive selection line, and the other end thereof is connected to a source end of the control transistor, so as to control a high-level input. One end of the pull-down diode is connected to a negative selection line, and the other end thereof is connected to the source end of the control transistor, so as to control a low-level input. The pull-up diode and the pull-down diode are symmetrically arranged in a first direction.

Abstract: The memory cell includes: a piezoelectric substrate layer, wherein two ends of the piezoelectric substrate layer are respectively provided with a first electrode and a second electrode, and a current-free drive of skyrmion is implemented by applying a voltage to the first electrode and the second electrode; a magnetic layer on a surface of the piezoelectric substrate layer, wherein the magnetic layer is used to form a heterojunction with the piezoelectric substrate layer, and is used to generate, stabilize, and serve as a basic carrier for a movement of the skyrmion; wherein the magnetic layer includes a convex body, the convex body is configured to divide the magnetic layer into a bit region and a memory region, and the bit region is provided with a magnetic tunnel junction used to perform generation and detection functions of the skyrmion.

Abstract: There are provided a semiconductor device, a method of manufacturing the same, and an electronic device including the device. According to an embodiment, the semiconductor device may include a substrate, and a first device and a second device formed on the substrate. Each of the first device and the second device includes a first source/drain layer, a channel layer and a second source/drain layer stacked on the substrate in sequence, and also a gate stack surrounding a periphery of the channel layer. The channel layer of the first device and the channel layer of the second device are substantially co-planar.

Abstract: A method of manufacturing a semiconductor memory device is provided. The method include: providing a stack of a sacrificial layer, a first source/drain layer, a channel layer, and a second source/drain layer on a substrate; defining a plurality of pillar-shaped active regions arranged in rows and columns in the first source/drain layer, the channel layer, and the second source/drain layer; removing the sacrificial layer and forming a plurality of bit lines extending below the respective columns of active regions in a space left by the removal of the sacrificial layer; forming gate stacks around peripheries of the channel layer in the respective active regions; and forming a plurality of word lines between the respective rows of active regions, wherein each of the word lines is electrically connected to the gate stacks of the respective memory cells in a corresponding one of the rows.

Abstract: A semiconductor device including a substrate, a first source/drain layer, a channel layer and a second source/drain layer stacked on the substrate in sequence, and a gate stack surrounding a periphery of the channel layer. The channel layer includes a semiconductor material causing an increased ON current and/or a reduced OFF current as compared to Si.

Abstract: A method for manufacturing a semiconductor device. A photolithographic coating, including a first film, a photolithographic film, and a second film, is formed on the to-be-connected structure. Refractive indexes of the first film and the second film are smaller than 1. The photolithographic coating is exposed to a light having a first wavelength, to image the to-be-connected structure to a first region of the photolithographic film. The photolithographic coating is exposed to a light having a second wavelength through a mask, to image the mask to a second region of the photolithographic film. A region in which the first region and the second region overlap serves as a connection region corresponding to the to-be-connected structure, and thereby self-alignment between a layer of the to-be-connected structure and a layer where a contact hole is arranged is implemented.

Abstract: The present disclosure provides a memory with a three-dimensional vertical structure and a manufacturing method. The memory includes: a semiconductor substrate, a first isolation layer, a first transistor and a second transistor. The first transistor includes a first source layer, a second isolation layer, a first drain layer, a third isolation layer, and a first through hole penetrating to the first source layer. A first active layer, a first gate dielectric layer and a first gate layer are on an inner sidewall of the first through hole. The second transistor includes a fourth isolation layer, a second source layer, a fifth isolation layer, and a second through hole penetrating to the first gate layer. A second active layer, a second gate dielectric layer and a second gate layer are on an inner sidewall of the second through hole. The second through hole is surrounded by the first through hole.

Abstract: A three-dimensional integrated circuit and a manufacturing method therefor is used for improving the performance of the integrated circuit when the integrated circuit includes a power gating circuit. The three-dimensional integrated circuit includes a substrate, and a front-section circuit, a rear-section metal interconnection layer, and a rear-section power gating circuit that are formed on the substrate; the rear-section metal interconnection layer is formed on the front-section circuit; the rear-section power gating circuit is located in the rear-section metal interconnection layer; and the front-section circuit is electrically connected to a power supply or a ground wire by means of the rear-section metal interconnection layer and the rear-section power gating circuit.

Abstract: The present disclosure provides a method for optimizing mask parameters, and the method includes: acquiring a test pattern, light source parameters, and initial mask parameters, the initial mask parameters including a mask thickness and an initial mask sidewall angle; generating multiple sets of candidate mask parameters according to the initial mask sidewall angle in the initial mask parameters; the multiple sets of candidate mask parameters including different mask sidewall angles and the same mask thickness; obtaining an imaging contrast of each set of candidate mask parameters based on the test pattern and the light source parameters; and selecting an optimal mask sidewall angle from the multiple sets of candidate mask parameters according to the imaging contrasts.

Abstract: Provided is a cache memory, including: a first field-effect transistor, a field-like spin torque layer underneath a magnetic tunnel junction, an electrode, and a second field-effect transistor sequentially arranged and connected; wherein the first field-effect transistor is configured to provide a writing current and to control the on-off of the writing current through a gate electrode; the field-like spin torque layer is configured to generate field-like spin torques for switching a first ferromagnetic layer of the magnetic tunnel junction; the magnetic tunnel junction includes a first ferromagnetic layer, a tunneling layer, a second ferromagnetic layer and a pinning layer arranged sequentially; the electrode is configured to connect the cache memory with the second field-effect transistor; and the second field-effect transistor is configured to control the on-off of the second field-effect transistor through the gate electrode to read the resistive state of the magnetic tunnel junction.

Abstract: Provided are a symmetric memory cell and a BNN circuit. The symmetric memory cell includes a first complementary structure and a second complementary structure, the second complementary structure being symmetrically connected to the first complementary structure in a first direction, wherein the first complementary structure includes a first control transistor configured to be connected to the second complementary structure, the second complementary structure includes a second control transistor, a drain electrode of the second control transistor and a drain electrode of the first control transistor being symmetrically arranged in the first direction and connected to a bit line, and the symmetric memory cell is configured to store a weight value 1 or 0.

Abstract: A method for manufacturing a semiconductor device. A photolithographic coating, including a first film, a photolithographic film, and a second film, is formed on the to-be-connected structure. Refractive indexes of the first film and the second film are smaller than 1, so that the photolithographic coating forms an optical structure with a high reflection coefficient. The photolithographic coating is exposed to a light having a target wavelength through a mask. The to-be-connected structure is reflected in the photolithographic coating, and hence serves as another mask and is imaged to the photolithographic film. A pattern of the mask is simultaneously imaged to the photolithographic film. That is, both the to-be-connected structure and the pattern of the mask are imaged to a target region of the photolithographic film, and the target region corresponds to the to-be-connected structure.

Abstract: A data recovery method for a flash memory includes: reading data from the flash memory by using preset read voltage; calculating a check node error rate corresponding to the data; calculating a read voltage adjustment step size according to the check node error rate; adjusting the preset read voltage according to the read voltage adjustment step size and reading data from the flash memory by using the adjusted preset read voltage, and repeating the operation of calculating a check node error rate corresponding to the data to operation of adjusting the preset read voltage according to the read voltage adjustment step size and reading data from the flash memory by using the adjusted preset read voltage, until the check node error rate is minimum; and selecting a read voltage corresponding to the minimum check node error rate to read data from the flash memory, so as to perform data recovery.

Abstract: An interconnection structure for semiconductor devices formed on a substrate may be arranged under the semiconductor devices. The interconnection structure includes at least one via layer and at least one interconnection layer alternately arranged in a direction from the semiconductor device to the substrate, wherein each via layer includes via holes respectively arranged under at least a part of the semiconductor devices, and each interconnection layer includes conductive nodes respectively arranged under at least a part of the semiconductor devices, and in a same interconnection layer, a conductive channel is provided between at least one conductive node and at least another node; and the via holes in each via layer and the conductive nodes in each interconnection layer corresponding to the via holes at least partially overlap with each other in the direction from the semiconductor device to the substrate.

Abstract: An in-memory computing circuit having reconfigurable logic, including: an input stage and N output stages which are cascaded. The input stage includes 2N STT-MTJs. Each output stage includes STT-MTJs, of which a quantity is equal to a half of a quantity of STT-MTJs in a just previous stage. Two STT-MTJs in the previous stage and one STT-MTJ in the subsequent stage form a double-input single-output in-memory computing unit. Each double-input single-output in-memory computing unit can implement the four logical operations, i.e., NAND, NOR, AND, and OR, under different configurations. Data storage and logical operations can be realized under the same circuit architecture, and reconfigurations among different logic can be achieved.