Patent application number | Description | Published |
20080266932 | CIRCUIT FOR PROGRAMMING A MEMORY ELEMENT - An integrated circuit includes a memory element configured to be programmed to any one of at least three resistance states and a circuit. The circuit is configured to program the memory element to a selected one of the at least three resistance states by applying a pulse to the memory element. The pulse includes one of at least three tail portions wherein each tail portion corresponds to one of the at least three resistance states. | 10-30-2008 |
20090175071 | PHASE CHANGE MEMORY DYNAMIC RESISTANCE TEST AND MANUFACTURING METHODS - A method for testing an integrated circuit memory device includes applying a sequence of test pulses to a memory cell on the device, where the test pulses result in current through the memory cell having an amplitude dependent on the test pulse. Resistance in the memory cell is measured in response to the sequence of test pulses. A parameter set is extracted from the resistance measurements which includes at least one numerical coefficient that models dependency of the measured resistance on the amplitude of the current through the memory cell. The extracted numerical coefficient or coefficients are associated with the memory device, and used for controlling manufacturing operations. | 07-09-2009 |
20090207656 | OPERATING METHOD OF MEMORY - An operating method of a memory is provided. The memory includes a memory cell array composed of a plurality of memory cells, a plurality of bit lines, and a plurality of word lines. During programming the memory, a column of memory cells is selected. A voltage difference is respectively occurred between a bit line corresponding to first source/drain regions of the memory cells in the selected column and adjacent two bit lines, and a bias is respectively applied to a word line corresponding to a control gate of each memory cell in the selected column so as to allow a data bit of the memory cell at a plurality of predetermined programmed states and an unusable bit of each memory cell in an adjacent column which shares the same bit line with the selected column at an unusable state. | 08-20-2009 |
20090207658 | OPERATING METHOD OF MEMORY DEVICE - An operating method of a memory array is provided. The operating method includes performing a programming operation. The programming operation is performed by applying a first voltage to a bit line of the memory array and a second voltage to a plurality of word lines of the memory array to cause simultaneously programming a plurality of selected memory cells in the memory array | 08-20-2009 |
20090231942 | THREE-DIMENSIONAL MEMORY DEVICES AND METHODS OF MANUFACTURING AND OPERATING THE SAME - A method of accessing memory cells is disclosed. A first signal is sent to at least one layer select transistor. The at least one layer select transistor is activated based on the first signal. Signals are communicated to or from one or more memory cells based on the activated at least layer select transistor. | 09-17-2009 |
20100008153 | METHOD FOR OPERATING NONVOLATITLE MEMORY ARRAY - A method for programming a mixed nonvolatile memory array having a plurality of mixed memory cells, wherein each mixed memory cell includes a depletion mode memory cell and an enhanced mode memory cell. The method comprises steps of programming the enhanced mode memory cell in a way of channel hot carrier and programming the depletion mode memory cell in a way of band-to-band tunneling hot carrier. | 01-14-2010 |
20100009504 | SYSTEMS AND METHODS FOR A HIGH DENSITY, COMPACT MEMORY ARRAY - A memory array comprising vertical memory cells does not require any isolation layers between cells. Thus, a very compact, high density memory array can be achieved. Each memory cell in the memory array is configured to store 4 bits of data per cell. Multi-level charge techniques can be used to increase the number of bit per cell and achieve further increased density for the memory array. | 01-14-2010 |
20100084624 | Dielectric mesh isolated phase change structure for phase change memory - A method for manufacturing a memory device, and a resulting device, is described using silicon oxide doped chalcogenide material. A first electrode having a contact surface; a body of phase change memory material in a polycrystalline state including a portion in contact with the contact surface of the first electrode, and a second electrode in contact with the body of phase change material are formed. The process includes melting and cooling the phase change memory material one or more times within an active region in the body of phase change material without disturbing the polycrystalline state outside the active region. A mesh of silicon oxide in the active region with at least one domain of chalcogenide material results. Also, the grain size of the phase change material in the polycrystalline state outside the active region is small, resulting in a more uniform structure. | 04-08-2010 |
20100091558 | Dielectric-Sandwiched Pillar Memory Device - A memory device includes bottom and top electrode structures and a memory cell therebetween. The memory cell comprises bottom and top memory elements and a dielectric element therebetween. A lower resistance conduction path is formed through the dielectric element. The dielectric element may have an outer edge and a central portion, the outer edge being thicker than the central portion. To make a memory device, an electrical pulse is applied through the memory cell to form a conduction path through the dielectric element. A passivation element may be formed by oxidizing the outer surface of the memory cell which may also enlarge the outer edge of the dielectric element. | 04-15-2010 |
20100097851 | METHOD FOR PROGRAMMING A MULTILEVEL PHASE CHANGE MEMORY DEVICE - A method of programming a phase change device includes selecting a desired threshold voltage (Vth) and applying a programming pulse to a phase change material in the phase change device. The applying of the programming pulse includes applying a quantity of energy to the phase change material to drive at least a portion of this material above a melting energy level. A portion of the energy applied to the phase change material is allowed to dissipate below the melting energy level. The shape of the energy dissipation from the phase change material is controlled until the energy applied to the phase change material is less than a quenched energy level, to cause the phase change device to have the desired Vth. A remaining portion of the energy applied to the phase change material is allowed to dissipate to an environmental level. | 04-22-2010 |
20100110778 | PHASE CHANGE MEMORY PROGRAM METHOD WITHOUT OVER-RESET - Memory devices and methods for operating such devices are described herein. A method as described herein includes applying a fixed sequence of voltage pulses across the memory cell of increasing pulse height to change the resistance state from the lower resistance state to the higher resistance state. The fixed sequence of voltage pulses cause increasing current through the phase change memory element until change to the higher resistance state occurs, and after the change the voltage pulses in the fixed sequence causing a voltage across the phase change memory element less than the threshold voltage. | 05-06-2010 |
20100165711 | SET ALGORITHM FOR PHASE CHANGE MEMORY CELL - Memory devices and methods for operating such devices are described herein. A method is described herein for operating a memory cell comprising phase change material and programmable to a plurality of resistance states including a high resistance state and a lower resistance state. The method comprises applying a first bias arrangement to the memory cell to establish the lower resistance state, the first bias arrangement comprising a first voltage pulse. The method further comprises determining whether the memory cell is in the lower resistance state, and if the memory cell is not in the lower resistance state then applying a second bias arrangement to the memory cell. The second bias arrangement comprises a second voltage pulse having a pulse height greater than that of the first voltage pulse. | 07-01-2010 |
20100177553 | REWRITABLE MEMORY DEVICE - Memory devices described herein are programmed and erased by physical segregation of an electrically insulating layer out of a memory material to establish a high resistance state, and by re-absorption of at least a portion of the electrically insulating layer into the memory material to establish a low resistance state. The physical mechanism of programming and erasing includes movement of structure vacancies to form voids, and/or segregation of doping material and bulk material, to create the electrically insulating layer consisting of voids and/or dielectric doping material along an inter-electrode current path between electrodes. | 07-15-2010 |
20100221851 | TEST STRUCTURE AND METHOD FOR DETECTING CHARGE EFFECTS DURING SEMICONDUCTOR PROCESSING - A semiconductor process test structure comprises an electrode, a charge-trapping layer, and a diffusion region. The test structure is a capacitor-like structure in which the charge-trapping layer will trap charges during various processing steps. Gate-induced drain leakage (GIDL) measurement techniques can then be used to characterize the charging status of the test structure. | 09-02-2010 |
20100295009 | Phase Change Memory Cells Having Vertical Channel Access Transistor and Memory Plane - Memory devices are described along with methods for manufacturing. A memory device as described herein comprises a plurality of word lines overlying a plurality of bit lines, and a plurality of field effect transistors. Field effect transistors in the plurality of field effect transistors comprises a first terminal electrically coupled to a corresponding bit line in the plurality of bit lines, a second terminal overlying the first terminal, and a channel region separating the first and second terminals and adjacent a corresponding word line in the plurality of word lines. The corresponding word line acts as the gate of the field effect transistor. A dielectric separates the corresponding word line from the channel region. A memory plane comprises programmable resistance memory material electrically coupled to respective second terminals of the field effect transistors, and conductive material on the programmable resistance memory material and coupled to a common voltage. | 11-25-2010 |
20100314601 | PHASE CHANGE MEMORY HAVING STABILIZED MICROSTRUCTURE AND MANUFACTURING METHOD - A memory device having a phase change material element with a modified stoichiometry in the active region does not exhibit drift in set state resistance. A method for manufacturing the memory device includes first manufacturing an integrated circuit including an array of phase change memory cells with bodies of phase change material having a bulk stoichiometry; and then applying forming current to the phase change memory cells in the array to change the bulk stoichiometry in active regions of the bodies of phase change material to the modified stoichiometry, without disturbing the bulk stoichiometry outside the active regions. The bulk stoichiometry is characterized by stability under the thermodynamic conditions outside the active region, while the modified stoichiometry is characterized by stability under the thermodynamic conditions inside the active region. | 12-16-2010 |
20100328995 | METHODS AND APPARATUS FOR REDUCING DEFECT BITS IN PHASE CHANGE MEMORY - Phase change memory devices and methods for operating described herein are based on the discovery that, following an initial high current operation applied to a phase change memory cell to establish the high resistance reset state, the current-voltage (I-V) behavior of the memory cell under different bias voltages can be used to detect if the memory cell is a defect cell having poor data retention characteristics. | 12-30-2010 |
20100328996 | PHASE CHANGE MEMORY HAVING ONE OR MORE NON-CONSTANT DOPING PROFILES - A phase change memory device with a memory element including a basis phase change material, such as a chalcogenide, and one or more additives, where the additive or additives have a non-constant concentration profile along an inter-electrode current path through a memory element. The use of “non-constant” concentration profiles for additives enables doping the different zones with different materials and concentrations, according to the different crystallographic, thermal and electrical conditions, and different phase transition conditions. | 12-30-2010 |
20110012083 | PHASE CHANGE MEMORY CELL STRUCTURE - A memory cell described herein includes a memory element comprising programmable resistance memory material overlying a conductive contact. An insulator element includes a pipe shaped portion extending from the conductive contact into the memory element, the pipe shaped portion having proximal and distal ends and an inside surface defining an interior, the proximal end adjacent the conductive contact. A bottom electrode contacts the conductive contact and extends upwardly within the interior from the proximal end to the distal end, the bottom electrode having a top surface contacting the memory element adjacent the distal end at a first contact surface. A top electrode is separated from the distal end of the pipe shaped portion by the memory element and contacts the memory element at a second contact surface, the second contact surface having a surface area greater than that of the first contact surface. | 01-20-2011 |
20110049456 | PHASE CHANGE STRUCTURE WITH COMPOSITE DOPING FOR PHASE CHANGE MEMORY - A memory device is described using a composite doped phase change material between a first electrode and a second electrode. A memory element of phase change material, such as a chalcogenide, is between the first and second electrodes and has an active region. The phase change material has a first dopant, such as silicon oxide, characterized by tending to segregate from the phase change material on grain boundaries in the active region, and has a second dopant, such as silicon, characterized by causing an increase in recrystallization temperature of, and/or suppressing void formation in, the phase change material in the active region. | 03-03-2011 |
20110075475 | SET ALGORITHM FOR PHASE CHANGE MEMORY CELL - Memory devices and methods for operating such devices are described herein. A method is described herein for operating a memory cell comprising phase change material and programmable to a plurality of resistance states including a high resistance state and a lower resistance state. The method comprises applying a first bias arrangement to the memory cell to establish the lower resistance state, the first bias arrangement comprising a first voltage pulse. The method further comprises determining whether the memory cell is in the lower resistance state, and if the memory cell is not in the lower resistance state then applying a second bias arrangement to the memory cell. The second bias arrangement comprises a second voltage pulse having a pulse height greater than that of the first voltage pulse. | 03-31-2011 |
20110080780 | Method for Programming a Multilevel Phase Change Memory Device - A method of programming a phase change device includes selecting a desired threshold voltage (Vth) and applying a programming pulse to a phase change material in the phase change device. The applying of the programming pulse includes applying a quantity of energy to the phase change material to drive at least a portion of this material above a melting energy level. A portion of the energy applied to the phase change material is allowed to dissipate below the melting energy level. The shape of the energy dissipation from the phase change material is controlled until the energy applied to the phase change material is less than a quenched energy level, to cause the phase change device to have the desired Vth. A remaining portion of the energy applied to the phase change material is allowed to dissipate to an environmental level. | 04-07-2011 |
20110121411 | THREE-DIMENSIONAL MEMORY DEVICES AND METHODS OF MANUFACTURING AND OPERATING THE SAME - The invention provides a semiconductor cell comprising a gate, a dielectric layer, a channel layer, a source region, a drain region and an oxide region. The dielectric layer is adjacent to the gate. The channel layer is adjacent to the dielectric layer and is formed above a source region, a drain region, and an oxide region. | 05-26-2011 |
20110286283 | 3D TWO-BIT-PER-CELL NAND FLASH MEMORY - A 3D memory device is described which includes bottom and top memory cubes having respective arrays of vertical NAND string structures. A common source plane comprising a layer of conductive material is between the top and bottom memory cubes. The source plane is supplied a bias voltage such as ground, and is selectively coupled to an end of the vertical NAND string structures of the bottom and top memory cubes. Memory cells in a particular memory cube are read using current through the particular vertical NAND string between the source plane and a corresponding bit line coupled to another end of the particular vertical NAND string. | 11-24-2011 |
20120187362 | Phase Change Memory Cell Structure - A memory cell described herein includes a memory element comprising programmable resistance memory material overlying a conductive contact. An insulator element includes a pipe shaped portion extending from the conductive contact into the memory element, the pipe shaped portion having proximal and distal ends and an inside surface defining an interior, the proximal end adjacent the conductive contact. A bottom electrode contacts the conductive contact and extends upwardly within the interior from the proximal end to the distal end, the bottom electrode having a top surface contacting the memory element adjacent the distal end at a first contact surface. A top electrode is separated from the distal end of the pipe shaped portion by the memory element and contacts the memory element at a second contact surface, the second contact surface having a surface area greater than that of the first contact surface. | 07-26-2012 |
20120231613 | 3D MEMORY ARRAY ARRANGED FOR FN TUNNELING PROGRAM AND ERASE - A 3D memory device includes an array of semiconductor body pillars and bit line pillars, dielectric charge trapping structures, and a plurality of levels of word line structures arranged orthogonally to the array of semiconductor body pillars and bit line pillars. The semiconductor body pillars have corresponding bit line pillars on opposing first and second sides, providing source and drain terminals. The semiconductor body pillars have first and second channel surfaces on opposing third and fourth sides. Dielectric charge trapping structures overlie the first and second channel surfaces, providing data storage sites on two sides of each semiconductor body pillar in each level of the 3D array. The device can be operated as a 3D AND-decoded flash memory. | 09-13-2012 |
20120327708 | HIGH-ENDURANCE PHASE CHANGE MEMORY DEVICES AND METHODS FOR OPERATING THE SAME - Phase change based memory devices and methods for operating such devices described herein overcome the set or reset failure mode and result in improved endurance, reliability and data storage performance. A high current repair operation is carried out in response to a set or reset failure of a phase change memory cell. The higher current repair operation can provide a sufficient amount of energy to reverse compositional changes in the phase change material which can occur after repeated set and reset operations. By reversing these compositional changes, the techniques described herein can recover a memory cell which experienced a set or reset failure, thereby extending the endurance of the memory cell. In doing so, phase change based memory devices and methods for operating such devices are provided which have high cycle endurance. | 12-27-2012 |
20130028005 | RESISTIVE MEMORY ARRAY AND METHOD FOR CONTROLLING OPERATIONS OF THE SAME - A resistive memory and a method for controlling operations of the resistive memory are provided. The resistive memory has a first memory layer, a second memory layer and a medium layer. Each of the first memory layer and the second memory layer is used to store data. The medium layer is formed between the first memory layer and the second memory layer. The method comprises at least a step of measuring a resistance between the first memory layer and the second memory layer, and determining which one of a first state, a second state and a third state is a state of the resistive memory according to the measured resistance. A resistive memory array including an array of the above resistive memory units, word lines and bit lines is also described, wherein the word (bit) lines are coupled to the first (second) memory layers. | 01-31-2013 |
20130094273 | 3D MEMORY AND DECODING TECHNOLOGIES - A 3D memory device is based on an array of conductive pillars and a plurality of patterned conductor planes including left side and right side conductors adjacent the conductive pillars at left side and right side interface regions. Memory elements in the left side and right side interface regions comprise a programmable transition metal oxide which can be characterized by built-in self-switching behavior, or other programmable resistance material. The conductive pillars can be selected using two-dimensional decoding, and the left side and right side conductors in the plurality of planes can be selected using decoding on a third dimension, combined with left and right side selection. | 04-18-2013 |
20130153846 | THREE DIMENSIONAL MEMORY ARRAY ADJACENT TO TRENCH SIDEWALLS - A self-aligning stacked memory cell array structure and method for fabricating such structure. The memory cell array includes a stack of memory cells disposed adjacent to opposing sides of a conductive line that is formed within a trench. The memory cells are stacked such that the memory element surface of each memory cell forms a portion of the sidewall of the conductive line. The conductive line is formed within the trench such that electrical contact is made across the entire memory element surface of each memory cell. Such structure and method for making such structure is a self-aligning process that does not require the use of any additional masks. | 06-20-2013 |
20130242648 | APPROACH FOR PHASE CHANGE MEMORY CELLS TARGETING DIFFERENT DEVICE SPECIFICATIONS - A memory chip and methods of fabricating a memory device with different programming performance and retention characteristics on a single wafer. One method includes depositing a first bounded area of phase change material on the wafer and depositing a second bounded area of phase change material on the wafer. The method includes modifying the chemical composition of a switching volume of the first bounded area of phase change material. The method includes forming a first memory cell in the first bounded area of phase change material with a modified switching volume of phase change material and a second memory cell in the second bounded area of phase change material with an unmodified switching volume of phase change material such that the first memory cell has a first retention property and the second memory cell has a second retention property. The first retention property is different from the second retention property. | 09-19-2013 |
20130341583 | RESISTIVE MEMORY AND FABRICATING METHOD THEREOF - A resistive memory and a fabricating method thereof are provided. The resistive memory includes first and second electrodes, a variable resistance material layer, a first dielectric layer, and a second dielectric layer. The first electrode includes a first portion and a second portion. The second electrode is disposed opposite to the first electrode. The variable resistance material layer includes a sidewall and first and second surfaces opposite to each other, wherein the first surface is connected with the first portion of the first electrode and the second surface is electrically connected with the second electrode. The second portion surrounds the sidewall of the variable resistance material layer and is connected with the first portion. The first dielectric layer is disposed between the first and the second electrodes. The second dielectric layer is disposed between the variable resistance material layer and the second portion of the first electrode. | 12-26-2013 |
20130341753 | Three-dimensional array structure for memory devices - A disclosed memory device includes a three-dimension array structure that includes memory layers and transistor structures disposed between the memory layers. Each memory layer is connected to a common electrode, and each transistor structure includes transistors that share common column structures and common base structures. The transistors also each include a connector structure that is spaced apart from a common column structure by a common base structure. | 12-26-2013 |
20130343115 | RESISTANCE MEMORY CELL AND OPERATION METHOD THEREOF - A resistance memory cell is provided and includes a first electrode, a tungsten metal layer, a metal oxide layer, and a second electrode. The tungsten metal layer is disposed on the first electrode. The metal oxide layer is disposed on the tungsten metal layer. The second electrode includes a first connection pad, a second connection pad, and a bridge portion electrically connected between the first connection pad and the second connection pad. The bridge portion is disposed on the metal oxide layer or surrounds the metal oxide layer. The resistance memory cell adjusts a resistivity of the metal oxide layer through a first current path, passing through the metal oxide layer and the tungsten metal layer, or a second current path extending from the first connection pad to the second connection pad. | 12-26-2013 |
20140036570 | OPERATING METHOD FOR MEMORY DEVICE AND MEMORY ARRAY AND OPERATING METHOD FOR THE SAME - An operating method for a memory device and a memory array and an operating method for the same are provided. The operating method for the memory device comprises following steps. A memory device is made being in a set state. A method for making the memory device being in the set state comprises applying a first bias voltage to the memory device. The memory device in the set state is read. A method for reading the memory device in the set state comprises applying a second bias voltage to the memory device. A recovering bias voltage is applied to the memory device. The step for applying the recovering bias voltage is performed after the step for applying the first bias voltage or the step for applying the second bias voltage. | 02-06-2014 |
20140119127 | DIELECTRIC CHARGE TRAPPING MEMORY CELLS WITH REDUNDANCY - A memory cell array of dielectric charge trapping memory cells and method for performing program, read and erase operations on the memory cell array that includes bits stored at charge trapping sites in adjacent memory cells. A bit of information is stored at a first charge trapping site in a first memory cell and a second charge trapping site in a second adjacent memory cell. Storing charge at two trapping sites in adjacent memory cells increases data retention rates of the array of memory cells as each charge trapping site can be read to represent the data that is stored at the data site. Each corresponding charge trapping site can be read independently and in parallel so that the results can be compared to determine the data value that is stored at the data site in an array of dielectric charge trapping memory cells. | 05-01-2014 |
20140131653 | UNIPOLAR PROGRAMMABLE METALLIZATION CELL - A programmable metallization device comprises a first electrode and a second electrode, and a dielectric layer, a conductive ion-barrier layer, and an ion-supplying layer in series between the first and second electrodes. In operation, a conductive bridge is formed or destructed in the dielectric layer to represent a data value using bias voltages having the same polarity, enabling the use of diode access devices. To form a conductive bridge, a bias is applied that is high enough to cause ions to penetrate the conductive ion-barrier layer into the dielectric layer, which then form filaments or bridges. To destruct the conductive bridge, a bias of the same polarity is applied that causes current to flow through the structure, while ion flow is blocked by the conductive ion-barrier layer. As a result of Joule heating, any bridge in the dielectric layer disintegrates. | 05-15-2014 |
20140160852 | SEMICONDUCTOR DEVICE AND MANUFACTURING METHOD AND OPERATING METHOD FOR THE SAME - A semiconductor device and a manufacturing method and an operating method for the same are provided. The semiconductor device comprises a substrate, a doped region and a stack structure. The doped region is in the substrate. The stack structure is on the substrate. The stack structure comprises a dielectric layer, an electrode layer, a solid electrolyte layer and an ion supplying layer. | 06-12-2014 |
20140254257 | Memory And Memory Managing Method - A method for managing memory includes setting a state of a first memory cell to a first state representing a first data and setting a state of a second memory cell to a second state representing the first data. If the state of the second memory cell has changed to a third state representing a second data different from the first data, the method also includes changing the state of the second memory cell back to the second state. | 09-11-2014 |
20140264232 | LOW TEMPERATURE TRANSITION METAL OXIDE FOR MEMORY DEVICE - A metal oxide formed by in situ oxidation assisted by radiation induced photo-acid is described. The method includes depositing a photosensitive material over a metal surface of an electrode. Upon exposure to radiation (for example ultraviolet light), a component, such as a photo-acid generator, of the photosensitive material forms an oxidizing reactant, such as a photo acid, which causes oxidation of the metal at the metal surface. As a result of the oxidation, a layer of metal oxide is formed. The photosensitive material can then be removed, and subsequent elements of the component can be formed in contact with the metal oxide layer. The metal oxide can be a transition metal oxide by oxidation of a transition metal. The metal oxide layer can be applied as a memory element in a programmable resistance memory cell. The metal oxide can be an element of a programmable metallization cell. | 09-18-2014 |