Abstract: A method for silicon carbide ingot peeling includes the steps of: placing the silicon carbide ingot between first and second suckers; having a pressing head disposed on a top surface of the first sucker to apply mechanical oscillatory energy to both the silicon carbide ingot and the second sucker through the first sucker; and, having an elastic element disposed under the second sucker to absorb part of the mechanical oscillatory energy to transmit longitudinal waves thereof to a modified layer of the silicon carbide ingot for propagating individually intermittent invisible cracks at the modified layer to break silicon carbide chains at different levels. Till the cracks connect together for forming a continuous crack across the silicon carbide ingot, a top portion of the silicon carbide ingot is then separable therefrom to form a wafer. In addition, an apparatus for silicon carbide ingot peeling is also provided.

Abstract: The present disclosure is directed to a method of manufacturing one or more needles of a probe card by refining and processing a conductive body that extends from the probe card to form a respective tip at the end of the respective conductive body. Forming the respective tip of a respective needle includes removing respective portions from the end of the conductive body by flowing an electrolytic fluid between a conductive pattern structure and an end of the respective conductive body. Removing the respective portions with the flow of the electrons may be performed in multiple successive steps to form various needles with various sizes, shapes, and profiles (e.g., cylindrical, rectangular, triangular, trapezoidal, etc.).

Abstract: A decoding method, a memory storage device and a memory control circuit unit are disclosed. The method includes: activating a decoding circuit which supports a plurality of decoding modes each corresponding to a threshold value, wherein a distribution of the threshold value corresponds to error correction abilities of the decoding modes; reading first data from a rewritable non-volatile memory module; performing, by the decoding circuit, a first decoding operation on the first data; obtaining a decoding parameter according to an execution result of the first decoding operation; and performing, by the decoding circuit, a second decoding operation on the first data based on a first decoding mode among the decoding modes according to a relative numerical relationship between the decoding parameter and the threshold value.

Abstract: A decoding method, a memory storage device and a memory control circuit unit are disclosed. The method includes: activating a decoding circuit which supports a plurality of decoding modes each corresponding to a threshold value, wherein a distribution of the threshold value corresponds to error correction abilities of the decoding modes; reading first data from a rewritable non-volatile memory module; performing, by the decoding circuit, a first decoding operation on the first data; obtaining a decoding parameter according to an execution result of the first decoding operation; and performing, by the decoding circuit, a second decoding operation on the first data based on a first decoding mode among the decoding modes according to a relative numerical relationship between the decoding parameter and the threshold value.

Abstract: A system and method for testing semiconductor memory devices includes a variable voltage input to a memory cell control gate. The voltage to the control gate can be varied from a voltage level used for normal memory cell operation, such as a read operation, to a voltage level that can be used to detect a defect in the memory device. During testing, the voltage level applied to the control gate is lower than the voltage level applied to a second terminal, such as a drain terminal, of the memory cell. In some embodiments, testing for defects can include applying a negative voltage to the control gate, while a positive voltage is applied to the drain terminal, which can reveal the presence of a gate-to-drain leakage defect.

Abstract: A method of detecting manufacturing defects at a memory array may include utilizing test circuitry to provide a selected voltage as drain bias on a bit-line of the memory array where the memory array is configured to employ a first voltage as the drain bias for a read operation and the selected voltage is higher than the first voltage, and determining whether a leakage current indicative of a manufacturing defect between the bit-line and another component of the memory array is present responsive to providing the selected voltage as the drain bias. A corresponding test device is also provided.

Abstract: A method of detecting manufacturing defects at a memory array may include utilizing test circuitry to provide a selected voltage as drain bias on a bit-line of the memory array where the memory array is configured to employ a first voltage as the drain bias for a read operation and the selected voltage is higher than the first voltage, and determining whether a leakage current indicative of a manufacturing defect between the bit-line and another component of the memory array is present responsive to providing the selected voltage as the drain bias. A corresponding test device is also provided.

Abstract: A system and method for testing semiconductor memory devices includes a variable voltage input to a memory cell control gate. The voltage to the control gate can be varied from a voltage level used for normal memory cell operation, such as a read operation, to a voltage level that can be used to detect a defect in the memory device. During testing, the voltage level applied to the control gate is lower than the voltage level applied to a second terminal, such as a drain terminal, of the memory cell. In some embodiments, testing for defects can include applying a negative voltage to the control gate, while a positive voltage is applied to the drain terminal, which can reveal the presence of a gate-to-drain leakage defect.

Abstract: A disk-like microfluidic structure includes a disk, and a plurality of microfluidic systems formed on the disk and covered by a top sealing layer. Each microfluidic system includes a first and a second supply chamber located near a geometrical center of the disk, and at least one receiving chamber communicably connected to the first and the second supply chambers via a first and a second microchannel, respectively. When the first and the second microchannels have different geometrical sizes and the disk is driven to spin, two fluids separately held in the first and the second supply chambers are centrifugally moved into the receiving chamber via the differently sized first and second microchannels at different speeds and in different quantities to generate in the receiving chamber a fluid mixture having a specific concentration. By changing the geometrical sizes of the first and second microchannels, different concentration fluid mixtures may be generated.