Vertical gain cell and array for a dynamic random access memory and method for forming the same
First Claim
1. A method for fabricating a gain cell on a semiconductor substrate, the method comprising the steps of:
- forming a vertical write transistor having multiple sides, the vertical write transistor having a gate, a body region and first and second source/drain regions;
forming a vertical read transistor having multiple sides, the vertical read transistor having a body region and first and second source/drain regions, the vertical read transistor further having a gate region that couples to the second source/drain region of the vertical write transistor;
forming a charge storage node coupled to the second source/drain region of the vertical write transistor;
forming a write bit line that couples to the first source/drain region of the vertical write transistor;
forming a write wordline that couples to the gate region of the vertical write transistor;
forming a read bit line that couples to the first source/drain region of the vertical read transistor; and
forming a read wordline that couples to the second source/drain region of the vertical read transistor.
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Abstract
A vertical gain memory cell including an n-channel metal-oxide semiconductor field-effect transistor (MOSFET) and p-channel junction field-effect transistor (JFET) transistors formed in a vertical pillar of semiconductor material is provided. The body portion of the p-channel transistor is coupled to a second source/drain region of the MOSFET which serves as the gate for the JFET. The second source/drain region of the MOSFET is additionally coupled to a charge storage node. Together the second source/drain region and charge storage node provide a bias to the body of the JFET that varies as a function of the data stored by the memory cell. A non destructive read operation is achieved. The stored charge is sensed indirectly in that the stored charge modulates the conductivity of the JFET so that the JFET has a first turn-on threshold for a stored logic “1” condition and a second turn-on threshold for a stored logic “0” condition. The charge storage node is a plate capacitor which surrounds the second source/drain region of the MOSFET. The vertical gain cell is fabricated so that the write word line, read bit line, read word line and capacitor are buried beneath the silicon surface. As a result the cell can be fabricated in an area as small as four (4) lithographic feature squares.
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Citations
25 Claims
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1. A method for fabricating a gain cell on a semiconductor substrate, the method comprising the steps of:
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forming a vertical write transistor having multiple sides, the vertical write transistor having a gate, a body region and first and second source/drain regions; forming a vertical read transistor having multiple sides, the vertical read transistor having a body region and first and second source/drain regions, the vertical read transistor further having a gate region that couples to the second source/drain region of the vertical write transistor; forming a charge storage node coupled to the second source/drain region of the vertical write transistor; forming a write bit line that couples to the first source/drain region of the vertical write transistor; forming a write wordline that couples to the gate region of the vertical write transistor; forming a read bit line that couples to the first source/drain region of the vertical read transistor; and forming a read wordline that couples to the second source/drain region of the vertical read transistor. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8)
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9. A method for fabricating a gain memory cell array on a semiconductor substrate, the method comprising the steps of:
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forming multiple vertical pillars of single crystalline semiconductor material extending outwardly from the substrate, the pillars having multiple sides, each pillar including a pair of transistors in the same pillar, each of the transistors having a body region, a gate region and first and second source/drain regions, and wherein the second source/drain region of a first transistor comprises the gate for a second transistor, and wherein the first source/drain region of the second transistor comprises the body region of the first transistor, the pillars forming an array of rows and columns; forming a number of write wordlines, wherein each write wordline is coupled to the gates of the first transistors in a row of vertical pillars in the array; forming a number of write bit lines, wherein each write bit line is coupled to the first source/drain regions of the first transistors in a column of vertical pillars in the array; forming a charge storage node coupled to the second source/drain region of each first transistor in the array of vertical pillars; forming a number of read bit lines, wherein each read bit line is coupled to the first source/drain regions of the second transistors in a row of vertical pairs in the array; and forming a number of read wordlines, wherein each read wordline is coupled to the second source/drain regions of the second transistors in a column of vertical pillars in the array. - View Dependent Claims (10, 11, 12, 13)
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14. A method for fabricating a gain memory cell array having a number of gain memory cells, the method comprising:
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forming a number of vertical pillars having an array of rows and columns, each vertical pillar comprising a vertical write transistor and a vertical read transistor each having a body region, a gate region, and first and second source/drain regions; forming a number of write wordlines, wherein each write wordline is coupled to the gates of the write transistors in one row of vertical pillars in the array; forming a number of write bit lines, wherein each write bit line is coupled to the first source/drain regions of the write transistors in one column of vertical pillars in the array; forming a number of charge storage nodes, wherein each charge storage node is coupled to the second source/drain region of each write transistor in the array of vertical pillars, and wherein a charge stored on each of the charge storage nodes controls a conductivity of each of the read transistors in the array of vertical pillars; forming a number of indepedent read bit lines for nondestructive read operations, wherein each independent read bit line is coupled to the first source/drain regions of the read transistors in one row of vertical pillars in the array; and forming a number of read wordlines, wherein each read wordline is coupled to the second source/drain regions of the read transistors in one column of vertical pillars in the array, wherein each gain memory cell of the gain memory cell array has an area substantially equal to four lithographic features. - View Dependent Claims (15, 16, 17)
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18. A method for fabricating a data storage device, the method comprising:
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forming a memory array, wherein the forming of the memory array includes forming multiple vertical pillars of single crystalline semiconductor material extending outwardly from the substrate, the pillars having multiple sides, each pillar including a pair of transistors in the same pillar, each of the transistors having a body region, a gate region and first and second source/drain regions; forming a number of write wordlines, wherein each write wordline is coupled to the gates of the first transistors in a row of vertical pillars in the array; forming a number of write bit lines, wherein each write bit line is coupled to the first source/drain regions of the first transistors in a column of vertical pillars in the array; forming a number of charge storage nodes coupled to the second source/drain region of each first transistor in the array of vertical pillars; forming a number of read bit lines, wherein each read bit line is coupled to the first source/drain regions of the second transistors in a row of vertical pairs in the array; and forming a number of read wordlines, wherein each read wordline is coupled to the second source/drain regions of the second transistors in a column of vertical pillars in the array; forming a number of bit line drivers coupled to the respective read and write bit lines; and forming a number of wordline drivers coupled to the respective read and write wordlines. - View Dependent Claims (19, 20, 21, 22, 23)
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24. A method for fabricating a data storage device, the method comprising:
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forming a number of vertical pillars forming an array of rows and columns, each vertical pillar having a vertical write transistor and a vertical read transistor each having a body region, a gate region, and first and second source/drain regions; forming a number of plate capacitors that surrounds each vertical pillar adjacent to the second source/drain region of the write transistor, wherein each plate capacitor is coupled to the second source/drain region of each write transistor in the vertical pillars, and wherein a charge stored on each of the plate capacitors controls a conductivity of each of the read transistors in the vertical pillars; forming a number of independent read bit lines for nondestructive read operations, wherein each independent read bit line is coupled to the first source/drain regions of the read transistors in one row of the vertical pillars; forming a number of read wordlines, wherein each read wordline is coupled to the second source/drain regions of the read transistors in one column of the vertical pillars; forming a read bit line driver coupled to each of the read bit lines; forming a read wordline driver coupled to each of the read wordlines; forming a number of input/output controls coupled to certain ones of the read bit lines and wordlines; forming a read bit line decoder operatively coupled to the read bit line driver; and forming a read wordline decoder operatively coupled to the read wordline driver. - View Dependent Claims (25)
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Specification