A PERC solar cell capable of improving photoelectric conversion efficiency and a preparation method thereof are provided. The solar cell consecutively includes, from the bottom up, a rear silver electrode (1), a rear aluminum field (2), a rear silicon nitride film (3), a rear aluminum oxide film (4), P-type silicon (5), N-type silicon (6), a front silicon nitride film (7), and a front silver electrode (8). The rear aluminum field (2) is connected to the P-type silicon (5) via a rear aluminum strip (10). The P-type silicon (5) is a silicon wafer of the cell. The N-type silicon (6) is an N-type emitter formed by diffusion via the front surface of the silicon wafer. The front silicon nitride film (7) is deposited on the front surface of the silicon wafer. The rear aluminum oxide film (4) is deposited on the rear surface of the silicon wafer. The rear aluminum oxide film (3) is deposited after the front silicon nitride film (7) is deposited on the silicon wafer, and the rear surface of the silicon wafer is washed before depositing the rear aluminum oxide film (3). The cell can significantly improves passivation effect of the rear aluminum oxide film and improve the open-circuit voltage and short-circuit current of the cell, thereby increasing photoelectric conversion efficiency of the cell.

A method of manufacturing an integrated circuit (IC) includes forming a first active region in a first cell. The method includes forming a plurality of second active regions in a second cell, wherein the second cell abuts the first cell. The method includes forming a third active region in a third cell, wherein the second cell is between the first cell and the third cell, and a height of the second cell is different from a height of the first cell or the third cell. The method includes forming a plurality of gate structures extending across each of the first active region, the plurality of second active regions, and the third active region. The method includes removing a first portion of a first gate structure at an interface between the first cell and the second cell between the first active region and the plurality of second active regions.

The present disclosure relates to a semiconductor structure and a manufacturing method thereof. The method of manufacturing a semiconductor structure includes: providing a base; forming a plurality of first trenches arranged in parallel at intervals and extending along a first direction, and an initial active region between two adjacent ones of the first trenches, wherein the initial active region includes a first initial source-drain region close to a bottom of the first trench, a second initial source-drain region away from the bottom of the first trench, and an initial channel region located between the first initial source-drain region and the second initial source-drain region; forming a protective dielectric layer, wherein the protective dielectric layer covers a sidewall of the second initial source-drain region and a sidewall of the initial channel region; thinning the first initial source-drain region.

An enhanced symmetric multicycle rapid thermal annealing process for removing defects and activating implanted dopant impurities in a III-nitride semiconductor sample. A sample is placed in an enclosure and heated to a temperature T.sub.1 under an applied pressure P.sub.1 for a time t.sub.1. While the heating of the sample is maintained, the sample is subjected to a series of rapid laser irradiations under an applied pressure P.sub.2 and a baseline temperature T.sub.2. Each of the laser irradiations heats the sample to a temperature T.sub.max above its thermodynamic stability limit. After a predetermined number of temperature pulses or a predetermined period of time, the laser irradiations are stopped and the sample is brought to a temperature T.sub.3 and held at T.sub.3 for a time t.sub.3 to complete the annealing.

A laminated body of an embodiment includes: a silicon layer; a first beryllium oxide layer on the silicon layer; and a diamond semiconductor layer on the first beryllium oxide layer.

Disclosed is a high-quality and high-functional graphene-based TFT, including: a gate electrode, a gate insulating layer disposed on the gate electrode; an active layer including a nitrogen-doped graphene layer, on which disposed in a partial region of the gate insulating layer; a first electrode disposed on a region of one side of the active layer; and a second electrode disposed on a region of the other side of the active layer. The present invention allows obtaining the TFT having excellent characteristics by directly growing graphene on a Ti layer, implementing damages with remote plasma, and doping with nitrogen gas to fabricate a graphene active layer.

The present invention relates to a method for assembling molecules on the surface of a two-dimensional material formed on a substrate, the method comprises: forming a spacer layer comprising at least one of an electrically insulating compound or a semiconductor compound on the surface of the two-dimensional material, depositing molecules on the spacer layer, annealing the substrate with spacer layer and the molecules at an elevated temperature for an annealing time duration, wherein the temperature and annealing time are such that at least a portion of the molecules are allowed to diffuse through the spacer layer towards the surface of the two-dimensional material to assemble on the surface of the two-dimensional material. The invention also relates to an electronic device.

The present application discloses a semiconductor device and a method for forming a p-type conductive channel in a diamond using an abrupt heterojunction, which pertain to the technical field of fabrication of semiconductor devices. The method includes: forming a diamond layer on a substrate; forming one or multiple layers of a heterogeneous elementary substance or compound having an acceptor characteristic on an upper surface of the diamond layer; forming a heterojunction at an interface between the diamond layer and an acceptor layer; forming two-dimensional hole gas at one side of the diamond layer with a distance of 10 nm-20 nm away from the heterojunction; and using the two-dimensional hole gas as a p-type conductive channel. The method enables a concentration and a mobility of carriers to maintain stable at a temperature range of 0 C.-1000 C., thereby realizing normal operation of the diamond device at high temperature environment.

A method for manufacturing a functionalized graphene structure includes preparing a substrate having a graphene layer, forming an organic linker layer by providing an organic linker on the graphene layer, and forming a dopant layer by providing a dopant material including a metal on the organic linker layer. The organic linker layer and the dopant layer are formed in-situ.

Techniques for forming nanoribbon or bulk graphene-based SPR sensors are provided. In one aspect, a method of forming a graphene-based SPR sensor is provided which includes the steps of: depositing graphene onto a substrate, wherein the substrate comprises a dielectric layer on a conductive layer, and wherein the graphene is deposited onto the dielectric layer; and patterning the graphene into multiple, evenly spaced graphene strips, wherein each of the graphene strips has a width of from about 50 nanometers to about 5 micrometers, and ranges therebetween, and wherein the graphene strips are separated from one another by a distance of from about 5 nanometers to about 50 micrometers, and ranges therebetween. Alternatively, bulk graphene may be employed and the dielectric layer is used to form periodic regions of differing permittivity. A testing apparatus and method of analyzing a sample using the present SPR sensors are also provided.