Abstract: A semiconductor device includes: a substrate having a base and an array of semiconductor pillars extending from the base, the substrate being formed with a plurality of trenches, each of which extends into the base and has two opposing trench side walls; a first insulative liner layer formed on each of the trench side walls of each of the trenches and divided into upper and lower segments by a gap that leaves a bit-forming surface of each of the trench side walls uncovered by the first insulative liner layer; and a plurality of buried bit lines, each of which extends into the base from the bit-forming surface of a respective one of the trench side walls of each of the trenches.

Abstract: Double-exposure mask structure and photolithography. method for performing a photolithography process on a substrate are provided. The substrate has a central region and a margin region. A double-exposure mask structure includes a plurality of parallel and spaced first masks corresponding to the central region, a plurality of parallel and spaced second masks corresponding to the central region, and a plurality of auxiliary masks. The second masks intersect the first masks to form a plurality of overlapping regions. The auxiliary masks are not in contact with one another, and correspond to the Second masks to assist the overlapping regions neighboring to the auxiliary masks to have sufficient depth of focus for photolithography. With the auxiliary masks, the overlapping regions in the central region and neighboring to the margin region can have preferred photolithography and etching effect.

Abstract: A vertical semiconductor charge storage structure includes a substrate, at least one lower electrode, a dielectric layer and an upper electrode. The lower electrode includes a lower conductor, and a first side conductor and a second side conductor connected to the lower conductor. The first side conductor and the second side conductor are parallel to each other and form an included angle with the lower conductor. A height of the first side conductor from the substrate is greater than a height of the second side conductor from the substrate. The dielectric layer and the upper electrode are sequentially formed on surfaces of the substrate and the lower electrode. Accordingly, by forming the first side conductor and the second side conductor at different heights, an aperture ratio is increased to reduce difficulty in filling or deposition in subsequent processes to further enhance an overall yield rate.

Abstract: A vertical transistor structure includes a substrate, a plurality of pillars located on the substrate and spaced from each other at a selected distance, a gate line and a plurality of conductors. The pillars are aligned in a straight line in a first direction and have respectively a primary control wall along the first direction and two ancillary control walls perpendicular to the primary control wall. The gate line is connected to the primary control wall in the first direction through a first isolated layer. The conductors are interposed between the ancillary control walls through second isolated layers. By providing the gate line merely on the primary control wall and the conductors to aid the gate line to control ON/OFF of the pillars, problems of etching and separating gate material during gradually shrunken feature size process that are difficult to control etching positions and etching duration can be prevented.

Abstract: A dust collector for catching dust generated by temperature drop comprises a box, a plurality of separating boards, a plurality of catch boards, and a plurality of baffle boards. The separating boards partition the box to form an air flow channel. The catch boards and the baffle boards are staggered in the air flow channel; a portion of the catch boards are arranged in a central column to form a superimposition region along the vertical direction. The pores of the catch boards in the superimposition region are overlapped to make the air flow pour into the air flow channel easily. The baffle boards are staggered at the left or right of the catch boards, whereby the air flow takes more time to have a longer travel in the air flow channel, and dust is not accumulated in a single area but uniformly caught by the catch boards.

Abstract: A method of manufacturing a charging capacity structure includes steps of: forming a first oxide layer, a support layer and a second oxide layer on a substrate in sequence; forming a plurality of etching holes on the surface of the second oxide layer in a matrix to run through the substrate that are spaced from each other at a selected distance; forming a plurality of pillar layers in the etching holes; removing the second oxide layer by etching; forming an etching protection layer on the surfaces of the support layer and pillar tubes that is formed at a thickness one half of the spaced distance between the etching holes such that the pillar tubes at diagonal locations form a self-calibration hole; and finally removing the first oxide layer from the self-calibration hole by etching. Through the self-calibration hole, the invention needn't to provide extra photoresists to form holes.

Abstract: A semiconductor device includes: a substrate having a base and a pillar array including a plurality of pillars; a plurality of bit lines, each of which is disposed between two adjacent ones of the columns of the pillar array; a plurality of word lines, each of which is connected to a corresponding one of the rows of the pillar array; and a contact array including a plurality of bit line contacts arranged in rows and columns. The bit line contacts of each column of the contact array are embedded in the base and are electrically connected to a respective one of the bit lines. Each bit line contact intersects the respective one of the bit lines and extends between and is electrically connected to two adjacent ones of the pillars.

Abstract: A method of manufacturing vertical transistors includes steps of: forming a conductive layer on the surface of a substrate with a ditch and two support portions; removing the conductive layer on the bottom wall of the ditch and top walls of the support portions via anisotropic etching through a etch back process; forming an oxidized portion in the ditch; and etching the conductive layer to form two gates without contacting each other. By forming the conductive layer on the surface of the ditch and adopting selective etching of the etch back process, the problem of forming sub-trenches caused by lateral etching or uneven etching rate that might otherwise occur in the conventional etching process is prevented, and the risk of damaging metal wires caused by increasing etching duration also can be averted.

Abstract: A method for fabricating a vertical transistor comprises steps: forming a plurality of first trenches in a substrate; sequentially epitaxially growing a first polarity layer and a channel layer inside the first trenches, and forming a first retard layer on the channel layer; etching the first retard layer and the channel layer along the direction vertical to the first trenches to form a plurality of pillars; respectively forming a gate on a first sidewall and a second sidewall of each pillar; removing the first retard layer on the pillar; and epitaxially growing a second polarity layer on the pillar. The present invention is characterized by using an epitaxial method to form the first polarity layer, the channel layer and the second polarity layer and has the advantage of uniform ion concentration distribution. Therefore, the present invention can fabricate a high-quality vertical transistor.

Abstract: A robot arm for delivering a wafer is disclosed which comprises a carrier plate, an inner ring, a driving device and at least a contact pad. The inner ring is disposed on the carrier plate and defines at least a through-hole. The driving device is connected to the carrier plate to move the carrier plate. The contact pad is disposed at the through-hole of the inner ring and comprises a first protrusion portion and a second protrusion portion. The first protrusion portion protrudes from a first surface of the inner ring and is used for being in contact with the wafer to prevent it from being in contact with the first surface. The second protrusion portion is lodged in the through-hole to fix the contact pad at the inner ring.

Abstract: A method for fabricating buried bit lines comprises steps of: defining a plurality of parallel masked regions and a plurality of first etched regions each forming between any two neighboring masked regions on a surface of a substrate, and wherein the masked region is wider than the first etched region; etching the first etched regions to form a plurality of first trenches and a plurality of first pillars; forming two bit lines respectively on two sidewalls of each first trench; etching the first pillars to form a plurality of second pillars corresponding to the bit lines. The present invention uses a two-stage etching process to prevent pillars from bending or collapsing due to high aspect ratio. Moreover, the present invention has a simple process and is able to reduce cost and decrease cell size.

Abstract: An ion implantation method for semiconductor sidewalls includes steps of: forming a trench on a substrate, and the trench having a lower reflecting layer and two sidewalls adjacent to a bottom section; performing a plasma doping procedure to sputter conductive ions to the lower reflecting layer and the conductive ions being rebounded from the lower reflecting layer to adhere to the sidewalls to respectively form an adhesion layer thereon; and performing an annealing procedure to diffuse the conductive ions of the adhesion layer into the substrate to form a conductive segment. Thus, without damaging the substrate, the conductive segment having a high conductive ion doping concentration is formed at a predetermined region to satisfy semiconductor design requirements.

Abstract: A self-aligned wet etching process comprises the steps of: etching a substrate having an etch protection layer on a surface thereof to form a plurality of trenches spaced from each other; and sequentially forming an insulating layer, an etch stop layer and a primary insulator in each trench, wherein the primary insulator is filled inside an accommodation space surrounded by the etch stop layer. During the wet etching process, the etch stop layer protects the primary insulator from being etched, whereby is achieved anisotropic wet etching. Further, the present invention expands the contact areas for electrically connecting with external circuits and exempts the electric contactors formed on the contact areas from short circuit caused by excessively etching the primary insulators.

Abstract: A method of controlling a vertical dual-gate DRAM provides a short circuit state, a clearing state and a false broken circuit state. In the short circuit state, a first gate and a second gate at two sides of a first pillar are controlled to respectively have a turn-on voltage to form electric connection between a drain and a source at two ends of the first pillar. In the clearing state, the first gate and second gate are controlled to respectively have a clearing voltage to disconnect electric connection between the drain and source at two ends of the first pillar. The false broken circuit state is entered after the clearing state has been finished. The invention does not separate gates between neighboring pillars, but controls ON/OFF of transistors electrically so that no current leakage is generated in the clearing state and problem of inaccurate data reading can be prevented.

Abstract: A method for forming a buried split word line structure is provided. The method comprises the following steps. At first, a substrate having a trench therein is provided. Two liners are formed to a first thickness on sidewalls of the trench. Then, the trench is filled with a first insulating layer to a first height. The two liners are removed. Finally, a conductive material is deposited to a second height between and adjacent to the first insulating layer and the trench. Here, the first height is greater than the second height.

Abstract: A three-dimensional dynamic random access memory with an ancillary electrode structure includes a substrate, at least one bit line formed on the substrate, at least one pillar element formed on a growth zone of the bit line, an ancillary electrode, a character line parallel with the substrate and perpendicular to the bit line, and at least one capacitor connecting to the pillar element. The bit line is formed on the substrate by doping and diffusing a doping element. The ancillary electrode is located on a separation zone of the bit line and adjacent to the pillar element. The character line is insulated from the ancillary electrode and incorporates with the bit line to output or input electronic data to the capacitor. Through the ancillary electrode, impedance of the bit line can be controlled to enhance conductivity of the bit line.

Abstract: An integrated circuit with a memory cell is disclosed. The integrated circuit with a memory cell includes: a word line disposed in a word line trench of a substrate; a bit line disposed below the word line in a bit line trench and extending orthogonal to the word line; and, a separating layer disposed above the bit line in the bit line trench that separates the word line from the bit line; wherein an etching rate of the separating layer approaches that of the substrate.