Patent Description:
Over the past decades, hard disk drives have been applied as main data storage medium i.e. nonvolatile memory in e.g. mobile phones, personal computers, and data centers. More recently, NAND-type flash memory devices, i.e. NAND devices, have progressively been replacing hard disk drives in such applications. This replacement has been enabled by the small dimensions and high data rates of the NAND devices.

Non-volatile memory devices such as hard disk drives and NAND devices attain high densities by packing identical memory cells in dense two- or three-dimensional memory arrays. The memory cells are connected to a dense net of conductor lines that run in different directions across the memory array. Herein, in general, each memory cell consists of two elements. A first element is a storage element that stores one or more bits of information by altering a physical state of a material contained in the storage element. This may comprise a change in electrostatic charge, a change in magnetic or ferroelectric polarization or switching between amorphous and crystalline phases. The second element is an addressing element that connects the storage element to the conductor net. The addressing element ensures that each memory cell can be addressed individually for reading, writing, and erasing of information. Herein, data in a memory cell is addressed so that data stored in different memory cells that are connected to the same conductor grid is not disturbed. Typically, the addressing elements comprise a transistor or a diode. Typically, only <NUM> bit is stored in each memory cell.

Increasing the bit density of the nonvolatile memory requires reducing the dimensions of both the storage elements and addressing elements of the nonvolatile memory. The biggest challenge for scaling high-density memories is reducing the size of the addressing element and increasing the number of bits stored in each memory cell. NAND devices have, at present, attained the highest densities of all-solid-state memories because of their very compact addressing element at the limits of manufacturing resolution and storage of up to <NUM> bits per cell. Whereas storage elements can be envisaged that are smaller than what is achievable with electrostatic storage used in NAND devices, there is currently no known alternative addressing element that can be made more compact than NAND devices in a cost-effective way. A way to increase bit density is therefore to increase the number of bits that may be stored in each memory cell.

<NPL> have proposed a memory cell. Multiple bits may be stored in a single memory cell. Therein, the memory cell comprises a working electrode, a counter electrode, and a liquid electrolyte between the working electrode and the counter electrode. The liquid electrolyte comprises two ions e.g. copper ions and tin ions. Data is written by electrodeposition, wherein the ions are reduced and deposited over the working electrode. For instance, on application of a first cathodic potential E<NUM>, a first layer comprising a metal with the relatively higher electrode potential e.g. copper is deposited. For instance, on the application of a second cathodic potential E<NUM> < E<NUM>, a second layer comprising an alloy e.g. a copper-tin alloy is deposited. A thickness of a deposited layer may depend on a duration of an applied potential. For instance, a first thickness of the first layers may correspond to logic zero, and a second thickness of the first layers may correspond to logic unity. Similarly, a first thickness of the second layers may correspond to logic zero, and a second thickness of the second layers may correspond to logic unity. Herein, the first thickness and the second thickness of the first layers may be different from the first thickness and the second thickness of the second layers. Thereby, a stack comprising alternating first and second layers, wherein the first and second layers have a different composition, and wherein the layers have different thicknesses, may be deposited over the working electrode. This stack may correspond to stored binary data. The stored data may be read by electro-dissolution, wherein an anodic potential is applied to the working electrode so that the layers dissolve. Herein, the electro-dissolution is performed from the top layer of the stack and downward. By sensing a current flow through the working electrode as a function of time, the stored data may be read.

A drawback of the memory cell proposed by V. Ur'ev et al. is that a rate of writing data is, at present, limited. For instance, on writing, the ionic concentration of the liquid electrolyte reduces, thereby reducing the rate of writing data. Furthermore, diffusion of the ions of the liquid electrolyte may be a factor limiting the rate of writing data.

There is a need in the art for a memory device that solves one or more of the issues raised above.

<CIT> discloses a memory apparatus comprising a liquid electrolyte solution.

The invention is defined in the appended independent claims <NUM> and <NUM> - <NUM>.

Particular and preferred aspects of the invention are set out in the accompanying dependent claims.

Only embodiments of the description comprising all the technical features of the claims fall under the scope of protection of the claims while the remaining ones correspond to illustrative examples which are useful for the understanding of the relevant technical context.

Moreover, the terms top, bottom, over, under, and the like in the description and the claims are used for descriptive purposes and not necessarily for describing relative positions.

It is thus to be interpreted as specifying the presence of the stated features, integers, steps, or components as referred to, but does not preclude the presence or addition of one or more other features, integers, steps or components, or groups thereof. The word "comprising" according to the invention therefore also includes as one embodiment that no further components are present.

Similarly, it is to be noticed that the term "coupled", also used in the claims, should not be interpreted as being restricted to direct connections only. The terms "coupled" and "connected", along with their derivatives, may be used. Thus, the scope of the expression "a device A coupled to a device B" should not be limited to devices or systems wherein an output of device A is directly connected to an input of device B. It means that there exists a path between an output of A and an input of B which may be a path including other devices or means. "Coupled" may mean that two or more elements are either in direct physical or electrical contact, or that two or more elements are not in direct contact with each other but yet still co-operate or interact with each other.

In other instances, well-known methods, structures, and techniques have not been shown in detail in order not to obscure an understanding of this description.

In a first aspect, the present invention relates to a liquid electrochemical memory device comprising a memory region for storing at least two bits, the memory region having a first volume, a liquid electrolyte region fluidically connected to the memory region, the liquid electrolyte region having a second volume larger than the first volume, a working electrode exposed to the memory region, a counter electrode exposed to the liquid electrolyte region, an electrolyte filling the memory region and the liquid electrolyte region, in physical contact with the working electrode and the counter electrode, the electrolyte comprising at least two conductive species, and a control unit for biasing the working electrode and the counter electrode.

In embodiments, the memory region has a first width, perpendicular to a direction from the working electrode to the counter electrode, and the liquid electrolyte region has a second width, perpendicular to the direction, wherein the second width is larger than the first width. Thereby, the volume of the liquid electrolyte region can be relatively large, whereas the distance between the working electrode and the counter electrode remains relatively small.

In embodiments, each bit corresponds to a layer. In embodiments, the layer is present over the working electrode e.g. over a surface of the working electrode exposed to the memory region. Herein, the layer may be over part of the working electrode, or over a complete surface of the working electrode. In embodiments, each layer may be either a first layer (having a first composition) or a second layer (having a second composition, different from the first composition). However, the invention is not limited thereto and there may also be further layers having further compositions, different from the first and the second composition). Each layer may comprise at least one of the two conductive species. The two conductive species are a first conductive species and a second conductive species. However, this invention is not limited thereto, and the at least two conductive species may comprise further conductive species such as a third conductive species. Herein, the conductive species of the layers may have been deposited (e.g. by reduction) from the electrolyte. That is, the at least two conductive species may be in ionic form in the electrolyte and the at least two conductive species may be in metallic form in the layers.

In embodiments, the first layer may comprise a first ratio of the first conductive species to the second conductive species. In embodiments, the second layer may comprise a second ratio of the first conductive species to the second conductive species, the second ratio being different from the first ratio. In embodiments, each of the first layers may be present with either a first thickness or a second thickness, different from the first thickness. In embodiments, one of the first thickness and the second thickness may be <NUM>% larger, preferably <NUM>% larger, more preferably <NUM>% larger than the other of the first thickness and the second thickness. For instance, a first thickness of the first layers may correspond to logic zero, and a second thickness of the first layers may correspond to logic unity, thereby enabling a binary numerical system. In embodiments, each of the second layers may be present with either a first thickness or a second thickness, different from the first thickness. In embodiments, one of the first thickness and the second thickness is <NUM>% larger, preferably <NUM>% larger, more preferably <NUM>% larger than the other of the first thickness and the second thickness. In embodiments, a first thickness of the second layers may correspond to logic zero, and a second thickness of the second layers may correspond to logic unity, thereby enabling a binary numerical system. In embodiments, the liquid electrochemical memory device comprises a stack of alternating first layers and second layers over the working electrode. Herein, each layer of the stack of layers may correspond to a bit. Therefore, the stack of alternating first layers and second layers may correspond to stored data. That is, memory data may be stored in the memory region by a stack of alternating first layers and second layers. However, the invention is not limited to this way of encoding data. Also, other ways of encoding data in the stack may be envisaged. For example, each layer may encode more than a single binary number by depositing layers with a plurality of thicknesses. For example, when a layer can have four different thicknesses, the layer may correspond to two binary numbers at the same time. For example, when a layer can have eight different thicknesses, the layer may correspond to three binary numbers at the same time. In another example, the thickness of the first layer may be modulated to code for a binary number, whereas the thickness of the second layer may be always the same. In that case, the second layer serves as a separator between adjacent first layers i.e. bits.

The stored data may be read by electro-dissolution, e.g. by applying bias or current conditions to the working and counter electrodes so as to electro-dissolve material from the working electrode. Herein, the electro-dissolution is preferably performed from the top layer of the stack and downward. As the layers comprise conductive species, the layers themselves may also be conductive. In embodiments, the first layer and the second layer are conductive. Thereby, a voltage or current condition applied to the working electrode is also applied to a top layer of the stack. In embodiments, only a top layer of the stack is exposed to the electrolyte present in the memory region. By monitoring the amount of charge flowing through the working electrode or the voltage appearing at the working electrode, or in other words, by sensing a current flowing through the working electrode, an amount of charge flowing through the working electrode, or a potential level at the working electrode, as a function of time on electro-dissolution, the stored data may be read. Advantageously, as the layers of the stack may be conductive, further layers may be deposited over the stack e.g. on top of the stack.

In embodiments, the at least two conductive species have a different electrode potential. Advantageously, in these embodiments, a first layer deposited at a first potential may have a different ratio of the first conductive species to the second conductive species than a second layer deposited at a second potential. According to the invention, the conductive species are metallic species, that is, a metal ion in the electrolyte, and a metal after deposition. In embodiments, one of the conductive species (e.g. the first conductive species) is copper and another of the conductive species (e.g. the second conductive species) is cobalt, tin or nickel. This is advantageous because the difference in the electrode potential between copper, and any of cobalt, tin, and nickel is relatively large. Thereby, a difference in the ratio of the first conductive species to the second conductive species between the first layer and the second layer may easily be made large as well. As a result, the relatively large difference in ratio may result in a relatively larger difference in current through or potential level at the working electrode between electrodissolution of the first layer and of the second layer. Advantageously, the large difference in electrode potential may facilitate reading of the stored data.

In embodiments, the liquid electrochemical memory device comprises a reference electrode contacting the electrolyte. Preferably, the reference electrode is exposed to the liquid electrolyte region. In embodiments, the reference electrode consists of an inert material, such as carbon.

In embodiments, the electrolyte comprises water. Advantageously, water is a good solvent for conductive species. Advantageously, water is a cheap and safe material. In different embodiments, the electrolyte is a non-water-based electrolyte. Advantageously, in these embodiments, corrosion of elements of the liquid electrochemical memory device, e.g. of the layers, that is, of the data stored in the liquid electrochemical memory device, may be limited. In embodiments, the electrolyte preferably has a water concentration and oxygen concentration lower than 100ppm, more preferably lower than about 50ppm, even more preferably lower than 10ppm. In embodiments, the non-water-based electrolyte comprises an ionic liquid. Advantageously, ionic liquids may have a very low vapour pressure, so that production of the liquid electrochemical device in a vacuum environment is possible. The vacuum environment may be preferred during the production of the memory device (such as for example for certain deposition techniques such as physical vapor deposition). Furthermore, ionic liquids may have a high thermal stability and a high conductivity. In embodiments, the ionic liquid is liquid at at least a temperature in the range of from <NUM> to <NUM>. In embodiments, the ionic liquid electrolyte comprises a phosphate. An advantage of ionic liquids is that a concentration of conductive species therein may be very high. Therefore, advantageously, on electrodeposition of the conductive species over the working electrode, the concentration of conductive species may not be significantly reduced. Advantageously, thereby, a rate of deposition of the conductive species may remain the same, even after deposition of multiple bits e.g. layers comprising the conductive species.

In embodiments, the memory region is adapted for storing at least two bits. In embodiments, the memory region for storing at least two bits means that the memory region comprises space suitable for storing the at least two bits. In embodiments, the memory region is sufficiently large for comprising at least two layers. In embodiments, a thickness of each of the layers is from single-atom thickness up to <NUM>, preferably from <NUM> to <NUM>, even more preferably from <NUM> to <NUM>. The thinner a layer is, the faster writing and reading of data can be. Furthermore, the thinner a layer is, the less power or energy may be required for electrodepositing or electro-dissolving the layer. However, advantageously, thicker layers may be more stable and may provide a larger resolution to distinguish between first and second layers, that is, during reading of data. In embodiments, the memory region has a width of from <NUM> to <NUM>, preferably of from <NUM> to <NUM>. In embodiments, the width is perpendicular to a direction from the working electrode to the counter electrode. In embodiments, the memory region has a height, parallel to a direction from the working electrode to the counter electrode, of from <NUM> to <NUM>, preferably of from <NUM> to <NUM>. In embodiments, a width of each of the layers is from <NUM> to <NUM>, more preferably from <NUM> to <NUM>. Advantageously, when a layer has a small width, a current required to electrodeposit or electro-dissolve the layer may be smaller. Furthermore, advantageously, smaller dimensions of the layers may increase the bit density of the liquid electrochemical memory device.

A shape of the memory region may be any shape. That is, the memory region may have any shape suitable for comprising the at least two bits. In embodiments, the memory region comprises a container, such as a channel. In embodiments, the working electrode is at a first side of the container, such as at a first end of the channel, and the container is fluidically connected to the liquid electrolyte region at a second side of the container, such as at a second end of the channel, opposite to the first side. In embodiments, the first side is completely covered by the working electrode. Advantageously, in these embodiments, the width of the layers over the working electrode is limited by the width of the container, wherein the width is parallel to the surface of the working electrode. Thereby, the width of the layers and the amount of deposited material may be controlled. Furthermore, advantageously, in these embodiments, the width of each of the layers may be the same, that is, the layers may have a uniform width. Advantageously, the uniform width may result in a uniform rate of electrodeposition and electro-dissolution of the layers. In embodiments, a surface of the working electrode exposed to the memory region is flat. Advantageously, if the working electrode is flat, a layer electrodeposited over the working electrode may be flat and uniform, which may improve controllability of the reading and the writing of bits.

In embodiments, the second width, perpendicular to a direction from the working electrode to the counter electrode, of the liquid electrolyte region is larger than the first width, perpendicular to the direction from the working electrode to the counter electrode, of the memory region. In embodiments, the second width is at least <NUM>% larger, such as at least <NUM>% larger, than the first width. In embodiments, the first width is the width of the exposed surface of the working electrode. In embodiments, the first width is equal to the width of the bits, that is, of the stack of layers. In embodiments comprising the container, the first width equals the distance between two opposing walls of the container. In embodiments, the second width equals the distance between two opposite walls of the liquid electrolyte region. Advantageously, as the second width may be large, the volume of the liquid electrolyte region may be relatively large. Furthermore, as the first width may be small, the amount of conductive species that needs to be deposited to form a bit (e.g. a layer with a particular thickness) is relatively small, as the area of the bit may be small.

In embodiments, the liquid electrolyte region comprises a container. The shape of the container may be any shape. In preferred embodiments, the container has a cuboid shape, such as a rectangular cuboid shape. In embodiments, the liquid electrolyte region is located between the memory region and the counter electrode. In embodiments, the liquid electrolyte region has a height, parallel to a direction from the working electrode to the counter electrode, of from <NUM> to <NUM>, preferably of from <NUM> to <NUM>. In preferred embodiments, the height of the liquid electrolyte region is smaller than the height of the memory region. For instance, the height of the liquid electrolyte region may be from <NUM> to <NUM>% of the height of the memory region. In embodiments, the width of the liquid electrolyte region is from <NUM> to <NUM>, preferably from <NUM> to <NUM>. In embodiments, the second volume is from <NUM><NUM> to <NUM><NUM>, preferably from preferably from <NUM><NUM> nm<NUM> to <NUM><NUM>, more preferably from <NUM><NUM> nm<NUM> to <NUM><NUM>. The second volume of the liquid electrolyte region is larger than the first volume of the memory region. In embodiments, the first volume is from <NUM><NUM> to <NUM><NUM>, preferably from <NUM><NUM> nm<NUM> to <NUM><NUM>, more preferably from <NUM><NUM> nm<NUM> to <NUM><NUM>. For instance, the first volume may be from <NUM>% to <NUM>% of the second volume. In preferred embodiments, the volume of the liquid electrolyte region is larger than the added volume of all the memory regions fluidically coupled to the liquid electrolyte region. For instance, the first volume may be from <NUM>% to <NUM>% of the added volume of all the memory regions fluidically coupled to the liquid electrolyte region. Advantageously, the second volume of the liquid electrolyte may be large so that, on deposition of conductive species from the liquid electrolyte, the concentration of conductive species is not significantly changed. Thereby, advantageously, a rate of deposition may be constant even after deposition of a plurality of layers. At the same time, even though the second volume of the liquid electrolyte region may be relatively large, a distance between the working electrode and the counter electrode may remain relatively small. In embodiments, the distance between the working electrode and the counter electrode is from <NUM> to <NUM>, preferably from <NUM> to <NUM>. A small distance between the working electrode and the counter electrode may improve a rate of electrodeposition of conductive species in the memory region. For example, in these embodiments, a distance a conductive species may have to cover while moving from the counter electrode to the working electrode may be small. In embodiments, the liquid electrochemical memory device comprises a plurality of memory regions, each for storing at least two bits, and a corresponding number of working electrodes, each exposed to a different memory region. In embodiments, each of the plurality of memory regions may be fluidically connected to a different liquid electrolyte region. In these embodiments, the liquid electrolyte regions of neighbouring memory regions may not be fluidically coupled to each other. In preferred embodiments, the liquid electrolyte region comprises a single liquid electrolyte region fluidically coupled to the plurality of memory regions. In these embodiments, a large second volume for the liquid electrolyte region may be combined with a large bit density. In these embodiments, the second width may be larger than the first width of each of the plurality of memory regions combined. For instance, the first width of each of the plurality of memory regions combined may be from <NUM> to <NUM>% of the width of the second width. Furthermore, the single liquid electrolyte region may facilitate manufacturing. In embodiments, the liquid electrochemical memory device comprises a single counter electrode. Herein, the counter electrode may function as the counter electrode for each of the working electrodes. Advantageously, the single counter electrode may facilitate manufacturing.

In embodiments, the counter electrode comprises a plurality of counter electrodes. Advantageously, in these embodiments, excessive corrosion of the counter electrode may be prevented. In embodiments, each of the plurality of counter electrodes comprises a different material. In embodiments, the counter electrode comprises a layer comprising conductive species over a layer comprising an inert electrode material, such as carbon. The inert electrode material may prevent damaging the counter electrode. That is, when the conductive species are electro-dissolved in the liquid electrolyte from the counter electrode, further electro-dissolution from the counter electrode may be prevented by the layer comprising the inert electrode material. In embodiments, the layer comprising the conductive species is electro-deposited from the liquid electrolyte over the layer comprising the inert electrode material after manufacture of the liquid electrochemical memory device.

According to the invention, the counter electrode comprises the at least two conductive species. When applying appropriate voltage or current conditions to the working electrode, at least one conductive species may be electro-dissolved from the counter electrode into the liquid electrolyte. Alternatively, at least one conductive species may be electrodeposited on the counter electrode from the liquid electrolyte. Advantageously, thereby, the concentration of conductive species in the electrolyte may be controlled. Thereby, as the rate of electrodeposition of the conductive species depends on the concentration of the conductive species, the rate of electrodeposition of the conductive species in the memory region may be controlled. In embodiments, the counter electrode comprises an alloyed counter electrode, that is, wherein the at least two conductive species form an alloy. In different embodiments, the counter electrode comprises the at least two conductive species that are not alloyed. For instance, different regions of the counter electrode may consist of different conductive species. In these embodiments, each of the different regions may be in physical contact with the liquid. In these embodiments, different regions of the counter electrode may be electrically coupled to other regions of the working electrode. However, in particular embodiments, the different regions are each connected separately to the control unit. In other words, according to certain embodiments, the counter electrode comprises a plurality of counter electrodes, wherein each of the plurality of counter electrodes comprises another conductive species or another alloy of conductive species. Thereby, each of the plurality of counter electrodes may control the concentration of conductive species in the liquid electrolyte. In embodiments, the liquid electrochemical memory device comprises probing electrodes for detecting a concentration of conductive species in the liquid electrolyte. For instance, when the probing electrodes detect that the concentration of conductive species in the liquid electrolyte is below a threshold, conductive species may be electro-dissolved from the counter electrodes.

In embodiments, the electrolyte comprises additives for increasing a rate of electro-deposition. In embodiments, the electrolyte comprises additives for increasing a rate of electro-dissolution.

In embodiments, a concentration of one of the conductive species, i.e. a first conductive species, is at least ten times higher, preferably at least hundred times higher, than a concentration of another of the conductive species i.e. a second conductive species. In these embodiments, the first conductive species preferably has a lower electrode potential, i.e. reduction potential, than the second conductive species. For instance, the first conductive species may have an electrode potential which is at least <NUM> V lower than the second conductive species. A higher reduction potential of a conductive species may correspond with a greater affinity of the conductive species for electrons, and with a greater tendency to be reduced. When a potential is applied to the working electrode that is below the reduction potential of a conductive species in the electrolyte, the conductive species in the electrolyte may become reduced and deposited on the working electrode. When a first potential applied to the working electrode is below the reduction potential of the second conductive species i.e. the conductive species with the higher reduction potential, but above the reduction potential of the first conductive species, only the second conductive species may be deposited, thereby possibly forming a layer consisting of the second conductive species. When a second potential applied to the working electrode is below the reduction potential of the first conductive species and of the second conductive species, the first conductive species and the second conductive species may be deposited i.e. co-deposited, thereby forming a layer comprising an alloy. However, it may be preferred to deposit form layers that consist of one of the conductive species or that comprise <NUM> at% or more of a single conductive species. Pure layers may improve the uniformity of electro-dissolution. Furthermore, deposition of pure layers may avoid the formation of porous layers and layers with a rough surface. Finally, deposition of pure layers may also improve the selectivity of electro-dissolution of layers which may facilitate accurately detecting the bits stored in the memory region. To deposit relatively pure layers, use may be made of the fact that a higher concentration of conductive species in the electrolyte may result in a higher deposition rate. Therefore, when co-deposition occurs, the concentration of the conductive species in the deposited film depends on the concentration of the conductive species in the electrolyte. When the concentration of the first conductive species with the lower reduction potential is considerably higher than the concentration of the second conductive species, when the second potential is applied, the deposited layer may mostly consist of the first conductive species. That is, even though co-deposition may occur at the second potential. Thereby, at the second potential, layers may be formed that almost purely consist of the second conductive species. At the first potential, layers may be formed that almost purely consist of the first conductive species. Thereby, a material content of the deposited layers at the first potential and the second potential is very different. In embodiments wherein a concentration of the first conductive species is much higher (e.g. at least twice larger) than a concentration of the second conductive species, both at the first potential and at the second potential, relatively pure layers may be deposited. In embodiments comprising the stack of layers comprising alternating first layers and second layers, at least <NUM> at%, preferably at least <NUM> at%, of the first layers may be a first conductive species, and at least <NUM> at%, preferably at least <NUM> at%, of the second layers may be a second conductive species.

In embodiments, the liquid electrochemical memory device comprises a barrier between the counter electrode and the working electrode, wherein the barrier is permeable to at least one ion and not permeable to another ion. In embodiments, the barrier is located in the liquid electrolyte region. In embodiments, the at least one ion to which the barrier is permeable comprises a proton i.e. hydrogen cation. Advantageously, the barrier may prevent diffusion of the another ion to the working electrode. For example, the another ion may be electro-dissolved from the counter electrode, but it may be unwanted that the another ion is reduced and deposited on the working electrode. In embodiments, the another ion may be any ion. The barrier may in that case act as a salt bridge. In preferred embodiments, the another ion comprises the conductive species. Advantageously, the barrier may, for example, help to control the concentration of the conductive species that diffuses from the counter electrode to the working electrode. In embodiments, the barrier comprises a membrane or a porous material. In embodiments comprising the barrier, the electrolyte may comprise a first electrolyte and a second electrolyte. Herein, the first electrolyte may physically contact the counter electrode, and the second electrolyte may physically contact the working electrode. In embodiments, the barrier separates the first electrolyte from the second electrolyte. In embodiments, the second electrode comprises the conductive species. In embodiments, the first electrode does not comprise the conductive species.

In embodiments, the electrolyte comprises protective species with an electrode potential that is higher (e.g. at least <NUM> V higher) than an electrode potential of the conductive species. Before the liquid electrochemical memory device is powered down and is switched in retention mode wherein no external power source may be available, electrodes of the liquid electrochemical memory device in contact with the electrolyte may be covered by deposition of the protective species. Thereby, a protective layer may be formed over the electrodes. In embodiments, the liquid electrochemical memory device comprises the protective layer over electrodes of the liquid electrochemical memory device. In embodiments, the electrodes covered by the protective layer may comprise the working electrode, wherein the protective layers are formed over the working electrode such as on top of the bits i.e. the stack of layers. In embodiments, the electrodes covered by the protective layer may comprise the counter electrode. In embodiments, the electrodes covered by the protective layer may comprise the reference electrode. In embodiments, the liquid electrochemical memory device comprises a helping electrode comprising the protective species. Advantageously, in these embodiments, the protective species may be electro-dissolved from the helping electrode, into the electrolyte. Furthermore, the protective species may be electrodeposited from the electrolyte onto the helping electrode. Advantageously, in these embodiments, the electrolyte may not comprise the protective species during writing of bits i.e. deposition of first and second layers. Thereby, the protective species may not be deposited during the writing of bits. Advantageously, in these embodiments, the protective species may only be deposited when the liquid electrochemical memory device is switched into retention mode. The protective layer may prevent galvanic corrosion of the electrodes, which may for example occur during the retention mode. In embodiments, when the liquid electrochemical memory device is powered up again, the protective layer may be electro-dissolved from the electrodes covered by the protective layer, to form the protective species in the electrolyte. In these embodiments, the protectives species may subsequently be electrodeposited on the helping electrodes. As the protective species may have a higher electrode potential than the conductive species, selective electro-dissolution and electro-deposition of the protective species may be possible. In embodiments, the liquid electrochemical memory device comprises further probing electrodes for detecting a concentration of protective species in the liquid electrolyte. For instance, when the protective species are preferably removed from the liquid electrolyte e.g. during writing of bits, the further probing electrode may detect whether the protective species are still present in the liquid electrolyte.

In embodiments, the control unit may be any control unit suitable for biasing the working electrode and the counter electrode. Herein, the biasing may comprise that a potential difference is applied between the working electrode and the counter electrode. The biasing may comprise that a current is induced to flow through an external conductor connected to the working electrode and the counter electrode. In embodiments, the control unit is connected to an external conductor connected to the working electrode and the counter electrode.

In embodiments, the liquid electrochemical memory device comprises a current sensor. In embodiments, the liquid electrochemical memory device is configured so that the current sensor can detect a current flow through the working electrode. Thereby, on electro-dissolution of a bit e.g. a layer, a current flow induced by the electro-dissolution may be detected. As the current flow may depend on the material e.g. conductive species comprised in the bit e.g. in the layer, the current sensor may detect whether a first bit or a second bit is electro-dissolved. Furthermore, by sensing the current flow as dependent on time, a thickness of the first bit or the second bit may be detected. Thereby, the current sensor may be used for reading the bits stored in the memory region. The invention is however not limited to a current sensor. In embodiments, the liquid electrochemical memory device comprises a voltage sensor. In embodiments, the liquid electrochemical memory device is configured so that the voltage sensor can detect a potential at the working electrode. Thereby, on electro-dissolution of a bit e.g. a layer, a potential generated by the electro-dissolution may be detected. In embodiments, the control unit comprises the current sensor or the voltage sensor. In particular embodiments, the control unit comprises a charge sensor for sensing an amount of charge flow, that is, an integration of the current over time.

Any features of any embodiment of the first aspect may be independently as correspondingly described for any embodiment of any of the other aspects of the present invention.

In a second aspect, the present invention relates to a method for writing data in a liquid electrochemical memory device according to embodiments of the first aspect, the method comprising electrodepositing at least one of the two conductive species from the electrolyte thereby creating at least a bit in the memory region.

Any features of any embodiment of the second aspect may be independently as correspondingly described for any embodiment of any of the other aspects of the present invention.

In embodiments, electrodepositing is performed by applying bias or current conditions to the working and counter electrodes so as to electrodeposit the at least one of the conductive species, e.g. a layer comprising the at least one of the conductive species, in the memory region, such as over a surface of the working electrode exposed to the memory region. In embodiments, applying bias or current conditions comprises applying first bias or current conditions or applying second bias or current conditions. In embodiments, the method comprises cyclically performing the steps of a) applying first bias or current conditions to the working and counter electrodes, thereby creating a first bit e.g. a first layer in the memory region, the first bit comprising a first ratio of a concentration of first conductive species to a concentration of second conductive species; and b) applying second bias or current conditions to the working and counter electrodes, thereby depositing a second bit e.g. a second layer in the working region, the second bit comprising a second ratio of a concentration of first conductive species to a concentration of second conductive species. Herein, the first ratio and the second ratio are preferably different. For instance, the first ratio may be lower than the second ratio by <NUM> or more. By cyclically performing the steps a) and b), a stack of alternating first and second bits, that is, a stack of alternating first and second layers, may be formed.

In embodiments, the first and second bias or current conditions are adapted so that there is a conventional current flow from the working electrode, via an external conductor, to the counter electrode. That is, electrons flow from the counter electrode, via the external conductor, to the working electrode. At the working electrode, the electrons may be transferred to the conductive species in the electrolyte, so that the conductive species may become reduced. On reduction, the conductive species may be deposited on the working electrode to form a bit. In embodiments, the first and second bias or current conditions may be applied by the application of a voltage or the induction of a current by the control unit. In embodiments, the first and second bias or current conditions are adapted so that the working electrode is a negative electrode and the counter electrode is a positive electrode. In embodiments, the first and second bias or current conditions comprise a negative, that is, reducing, potential at the working electrode and a positive, that is, oxidizing potential at the counter electrode.

In preferred embodiments, the first bias or current conditions are adapted so that only second conductive species may be deposited and not first conductive species may be deposited. Herein, an electrode potential of the second conductive species may be higher than an electrode potential of the first conductive species. For example, applying the first bias or current conditions may comprise applying a first potential to the working electrode, wherein the first potential is higher (e.g. at least <NUM> V higher) than the electrode potential of the first conductive species, and lower (e.g. at least <NUM> V lower) than the electrode potential of the second conductive species.

In embodiments, the second bias or current conditions are adapted so that both the first conductive species and the second conductive species may be deposited. For example, applying the second bias or current conditions may comprise applying a second potential to the working electrode wherein the second potential is lower than the electrode potential of both the first and second conductive species. Advantageously, in these embodiments, the first ratio and the second ratio may be different.

The longer the bias or current conditions are applied, the more material may be deposited in the memory region, that is, the thicker a deposited layer may be. Hence, the composition of the deposited layer may depend on the bias or current conditions that are applied, and the thickness of the deposited layer may depend on the duration of the applied bias or current conditions.

In a third aspect, the present invention relates to a method for reading data in a liquid electrochemical memory device according to any according to any embodiment of the first aspect, the method comprising:.

In an embodiment of the third aspect, the present invention relates to a method for reading data in a liquid electrochemical memory device according to embodiments of the first aspect, the method comprising: applying bias or current conditions to the working and counter electrodes so as to electro-dissolve material from the working electrode; and monitoring the current level or amount of charge flowing through the working electrode, or monitoring the voltage level appearing at the working electrode during electro-dissolving, and/or the amount of time certain current or voltage levels are maintained at the working electrode during electro-dissolving.

Any features of any embodiment of the third aspect may be independently as correspondingly described for any embodiment of any of the other aspects of the present invention.

In embodiments of the third aspect, the present invention relates to a method for reading data in a liquid electrochemical memory device according to embodiments of the first aspect, the method comprising: applying bias or current conditions to the working and counter electrodes so as to electro-dissolve material from the working electrode; and monitoring the current level or amount of charge flowing through the working electrode, or monitoring the voltage level appearing at the working electrode during electro-dissolving, and/or the amount of time certain current or voltage levels are maintained at the working electrode during electro-dissolving.

In embodiments, applying bias or current conditions to the working and counter electrodes so as to electro-dissolve material from the working electrode comprises that a working electrode is a positive electrode and the counter electrode is a negative electrode. In embodiments, the bias or current conditions are applied by the control unit.

In embodiments, the applied bias or current conditions comprise that a positive voltage is applied to the working electrode. As a result of the applied bias or current conditions, material e.g. conductive species comprised in bits, that is, layers at the working electrode may become oxidized and thereby electro-dissolve in the electrolyte. The oxidation may comprise that electrons are transferred from the material to the working electrode. Thereby, a conventional current flow may be induced from the counter electrode, via an external conductor, to the working electrode. That is, electrons flow from the working electrode, via the externa conductive, to the counter electrode. The current flow may depend on the composition of the material, for instance on the electrode potential of the composition of the material.

In embodiments, the applied bias or current conditions comprise that a current is induced to flow from the counter electrode to the working electrode. That is, electrons are induced to flow from the working electrode to the counter electrode. Thereby, the material may be oxidized. As a result, a voltage may be generated at the working electrode. The voltage that is generated may depend on the material that is oxidized, for instance on the electrode potential of the composition of the material.

Therefore, monitoring the current level or the voltage level may yield information on the type of material that is electro-dissolved. For instance, in embodiments comprising a stack of alternating first and second layers, the current level or the voltage level may be different during electro-dissolution of the first layer than during electro-dissolution of the second layer. Monitoring the amount of time certain current or voltage levels are maintained may yield information about an amount of the material that is electro-dissolved. That is, the monitoring of the amount of time may yield information on a thickness of a bit or e.g. a thickness of a layer. Thereby, in embodiments comprising the stack of alternating first and second layers, the thicknesses of each of the alternating first and second layers may be detected, and thereby the data stored in the stack of alternating first and second layers may be read.

In embodiments, the applied bias or current conditions are constant. However, in different embodiments, the applied bias or current conditions may be modulated to increase a rate of reading. That is, read algorithms wherein the applied bias or current conditions are switchable may be envisaged to increase the rate of reading. For example, when one of the first or second layers electro-dissolves very slowly, the applied bias or current conditions may be adapted to increase the rate of electro-dissolution.

In a fourth aspect, the present invention relates to a method for producing a liquid electrochemical memory device according to embodiments of the first aspect, comprising: providing a memory region for storing at least two bits, the memory region having a first volume, and a working electrode exposed to the memory region, providing a liquid electrolyte region fluidically connected to the memory region, the liquid electrolyte region having a second volume larger than the first volume, and a counter electrode exposed to the liquid electrolyte region, providing an electrolyte in the memory region and in the liquid electrolyte region, the electrolyte comprising at least two conductive species, and providing a control unit for biasing the working electrode and the counter electrode.

Any features of any embodiment of the fourth aspect may be independently as correspondingly described for any embodiment of any of the other aspects of the present invention.

In embodiments, the control unit is provided in a substrate e.g. in a semiconductor substrate. In embodiments, the control unit is provided using commonly known metal-oxide-semiconductor (CMOS) technologies. In embodiments, the memory region is provided over e.g. on top of the substrate comprising the control unit.

The memory region may be provided using deposition and patterning techniques well known to a person skilled in the art. For example, deposition and patterning techniques known from back-end-of-line (BEOL) technology may be used. In embodiments, a metallization layer may be deposited over the semiconductor substrate. The working electrode may be provided on top of the metallization layer. In embodiments, the metallization layer may be patterned, thereby forming at least one metallization plug. In these embodiments, the working electrode may be provided e.g. deposited on a metallization plug. Providing the working electrode may be done by techniques known for a person skilled in the art, such as by depositing and patterning a conductive material for forming the working electrode. In embodiments, an intermetallic dielectric (IMD) layer may be deposited on the conductive layer. In embodiments, for instance, a container such as a channel may be etched through this IMD layer thereby exposing the working electrode. In these embodiments, the container may be the memory region. The deposition of the IMD layer and the etching through the IMD layer may be done using back-end-of-line (BEOL) techniques well known for a person skilled in the art. In embodiments, in the memory region and on top of the IMD a liquid electrolyte region is provided. In embodiments, the liquid electrolyte region is formed by depositing a dielectric layer and patterning this layer, thereby forming the liquid electrolyte region. In embodiments, the liquid electrolyte may be provided by filling the liquid electrolyte region and the memory region with the liquid electrolyte.

In preferred embodiments, the method comprises hermetically sealing the memory region and the liquid electrolyte region. In these embodiments, the liquid electrochemical memory device produced by the method comprises a hermetically sealed memory region and liquid electrolyte region. Advantageously, the hermetic sealing may prevent leaking of the electrolyte e.g. to other parts of the liquid electrochemical memory device. Advantageously, the hermetic sealing may ensure that the liquid electrolyte is not contaminated e.g. by oxygen. In embodiments wherein the liquid electrolyte comprises a very low amount of water, the hermetic sealing may prevent contamination of the liquid electrolyte by water.

In embodiments, the hermetic sealing may be provided by providing a hermetic capping layer on top of the liquid electrolyte region. In embodiments, the hermetic capping layer may be bonded to the substrate using die-to-die techniques or die-to-wafer or wafer-to-wafer bonding techniques. For the hermetic sealing, sealing techniques used for MEMS applications where also typically a cavity is present may be used.

Reference is made to <FIG>, which is a schematic representation of a liquid electrochemical memory device <NUM> according to embodiments of the present invention. The liquid electrochemical memory device <NUM> comprises a liquid electrolyte region <NUM> to which a counter electrode <NUM> is exposed. The liquid electrochemical memory device <NUM> further comprises a memory region <NUM> that in this example is a channel, and that is fluidically coupled to the liquid electrolyte region <NUM>. A liquid electrolyte is present in the memory region <NUM> and in the liquid electrolyte region <NUM>. The liquid electrolyte comprises at least two conductive species. A working electrode <NUM> is exposed to the memory region <NUM>. A control unit <NUM> is electrically connected to working electrode <NUM> and the counter electrode <NUM> for biasing the working electrode <NUM> and the counter electrode <NUM>. A first width of the memory region <NUM>, perpendicular to a direction from the working electrode <NUM> to the counter electrode <NUM>, is smaller than a second width of the liquid electrolyte region <NUM>, perpendicular to the direction. Furthermore, in this example, a second volume of the liquid electrolyte region is larger than a first volume of the memory region. In this way, the second volume of liquid electrolyte present in the memory region <NUM> and in the liquid electrolyte region <NUM> may be sufficiently large, whereas a distance between the working electrode <NUM> and the counter electrode <NUM> may remain small. Furthermore, in this example, because a width of the memory region <NUM> is relatively small, also a bit e.g. layer deposited in the memory region <NUM> is relatively small. Therefore, for the electrodeposition of a bit e.g. layer comprising conductive species with a particular width, the amount of conductive species from the electrolyte needed for the electrodeposition may be relatively small. Thereby, in this example, electrodeposition may not significantly influence a concentration of the conductive species in the electrolyte. Therefore, a rate of electrodeposition may remain similar e.g. large even after electrodeposition of a plurality of bits.

In this example, the liquid electrochemical device <NUM> furthermore comprises a stack of layers <NUM> in the memory region <NUM>, over i.e. on top of the working electrode <NUM>. The stack of layers <NUM> comprises alternating first layers <NUM> and second layers <NUM>. Each layer <NUM> or <NUM> corresponds to a bit of data.

Reference is made to <FIG>, which is a schematic cross-sectional representation of the stack of layers <NUM>. In this example, the stack of layers <NUM> comprises eight alternating first layers <NUM> and second layers <NUM>. The first layers <NUM> may have a first thickness <NUM> or a second thickness <NUM>, wherein the first thickness <NUM> is, in this example, <NUM> times as large as the second thickness <NUM>. The invention is however not limited thereto. The second layer <NUM> may have a first thickness <NUM> or a second thickness <NUM>, wherein the first thickness <NUM> is, in this example, <NUM> times as large as the second thickness <NUM>. The invention is however not limited thereto. In this example, the first layers with first thickness <NUM> have a same thickness as the second layers with first thickness <NUM>, and the first layers with second thickness <NUM> have a same thickness as the second layers with second thickness <NUM>. The invention is however not limited thereto, and the thicknesses may be different. In this example, the first thickness <NUM> or <NUM> corresponds to unity in a binary numerical system, that is, indicated by the zeroes and ones at the right of each layer <NUM> and <NUM> and <NUM> and <NUM>. In this example, the second thickness <NUM> or <NUM> corresponds to zero in a binary numerical system. Thereby, the stack of layers <NUM> corresponds to (from top to bottom) <NUM> in binary data.

Bias or current conditions may be applied to the working electrode <NUM> and the counter electrode <NUM> so as to electro-dissolve material, that is, the stack of layers <NUM>, from the working electrode <NUM>. In this example, a positive voltage is applied to the working electrode <NUM>, so that the layers <NUM> and <NUM> are electro-dissolved, from top to bottom, from the stack of layers <NUM>. The electro-dissolution results in a flow of electrons i.e. a current through the working electrode <NUM>. The current may be detected as a function of time, for instance using a current sensor. Reference is made to <FIG>, which is a plot of the current I as a function of time t, generated during the electro-dissolution of the stack of layers <NUM>. Herein, the current through the working electrode <NUM> has been monitored as a function of time. When first layers <NUM> are electro-dissolved, the current is larger than when the second layers <NUM> are electro-dissolved. Thereby, it is possible to distinguish between electro-dissolution of first layers <NUM> and second layers <NUM>. Layers with the first thickness <NUM> and <NUM> take a larger amount of time to electro-dissolve than layers with the second thickness <NUM> and <NUM>. Thereby, it is possible to distinguish, by sensing the current, between electro-dissolution of layers with the first thickness <NUM> and <NUM> and layers with the second thickness <NUM> and <NUM>. Hence, by sensing the current that is generated on application of the bias or current conditions so as to electro-dissolve material from the working electrode <NUM>, the bits stored in the stack of layers <NUM> may be read, indicated by the zeroes and ones.

Reference is made to <FIG>, which is a schematic vertical cross-sectional representation of a liquid electrochemical memory device according to embodiments of the present invention. In this example, the liquid electrochemical memory device comprises a plurality of memory regions <NUM>, that is, an array of memory regions <NUM>. In this example, the liquid electrochemical memory device comprises a corresponding number of working electrodes <NUM>, each exposed to a different memory region <NUM>. In this example, the liquid electrolyte region <NUM> comprises a single liquid electrolyte region <NUM> fluidically coupled to the plurality of memory regions <NUM>. The working electrodes <NUM> and counter electrode <NUM> are connected to a control unit <NUM>. In this example, each of the plurality of working electrodes <NUM> may be individually addressable by the control unit <NUM>.

Bits i.e. a stack of layers <NUM> may be present in the memory regions <NUM>, that is, over the working electrode <NUM> of the memory region <NUM>. In this example, each of the memory regions <NUM> is a nanochannel that has a width of <NUM>, and a length of <NUM>. For example, the layers may have an average thickness of <NUM>. Thereby, in this example, <NUM> layers may be deposited in each of the memory regions <NUM>, corresponding to <NUM> bits.

In this example, the liquid electrolyte region <NUM> and the memory region <NUM> are hermetically sealed. Thereby, no liquid electrolyte comprised in the liquid electrolyte region <NUM> and in the memory region <NUM> may leak out of the liquid electrochemical memory device, and furthermore, the liquid electrolyte may not become contaminated. For this, a hermetic capping layer <NUM> has been obtained over the liquid electrolyte region <NUM>. Herein the hermetic capping layer <NUM> comprises the counter electrode <NUM>.

Reference is made to <FIG>, which is a schematic vertical cross-sectional representation of a liquid electrochemical memory device according to embodiments of the present invention. In this example, the liquid electrochemical memory device comprises a layer <NUM> comprising a plurality of memory regions and working electrodes exposed to the memory regions (memory regions and working electrodes are not shown).

In this example, a control unit <NUM> and a plurality of memory regions and working electrodes may be obtained on a substrate e.g. a single silicon chip. For this, for example a modified CMOS process may be used. A hermetic capping <NUM> may be attached to the substrate for instance using die-to-die or die-to-wafer techniques.

In this example, the hermetic capping <NUM> has a smaller width than the substrate, so that bonding pads <NUM> on the substrate are exposed for electrically connecting a wire <NUM> to the control unit <NUM>. This is however not necessary, and alternatively, the hermetic capping layer <NUM> may comprise bonding pads <NUM> that are, e.g. via a conductor through the hermetic capping layer <NUM>, electrically connected to the control unit <NUM>.

In this example, the hermetic capping layer <NUM> comprises the counter electrode <NUM> electrically connected to the control unit <NUM>. Therefore, the counter electrode <NUM> in the capping hermetic layer <NUM> may be biased by the control circuit <NUM>.

Reference is made to <FIG>, which is a schematic vertical cross-sectional representation of a liquid electrochemical memory device according to embodiments of the present invention. In this example, the liquid electrochemical memory device comprises a barrier <NUM> in the liquid electrolyte region <NUM>. The barrier <NUM> is permeable to at least one ion, e.g. protons, but not to another ion. In this example, the barrier <NUM> is not permeable to the conductive species. The electrolyte filling the liquid electrolyte region in this example comprises a first electrolyte <NUM> contacting a counter electrode <NUM> in a hermetic capping layer <NUM> and a second electrolyte <NUM> contacting the working electrode in the memory regions (not shown in detail, but present in layer <NUM>). In this example, the second electrolyte <NUM> comprises the conductive species.

Reference is made to <FIG>, which is a schematic vertical cross-section of a liquid electrochemical memory device according to embodiments of the present invention. For filling the liquid electrolyte region <NUM> and the memory region, comprised in the layer <NUM>, with liquid electrolyte, a hole may be provided in a cap <NUM>, in a support of the cap <NUM>, or in the substrate <NUM>. Via the hole <NUM>, <NUM>, or <NUM>, the liquid electrolyte region <NUM> and the memory region may be filled with the liquid electrolyte, for instance by capillary force or injection with a needle. Advantageously, when a liquid electrolyte with a low vapor pressure is used, filling may be performed under vacuum. The vacuum may prevent trapping of air bubbles in the liquid electrolyte region <NUM> and the memory region. The hole <NUM>, <NUM>, or <NUM> may, after the filling, be sealed by application of a sealing material on top of the hole <NUM>, <NUM>, or <NUM>. Alternatively, a sealing film may be deposited over the hole <NUM>, <NUM>, or <NUM>, wherein the sealing film may for instance cover a surface comprising the hole <NUM>, <NUM>, or <NUM>. In embodiments wherein a sealing film is deposited with a technique requiring high deposition temperatures, the liquid electrolyte preferably has a boiling temperature at least that of the deposition temperature. In embodiments wherein a sealing film is deposited with a technique requiring low pressure, the liquid electrolyte preferably has a low vapor pressure. In embodiments wherein the liquid electrolyte is nonaqueous, the vacuum process may additionally serve to remove water, oxygen and other contaminants from the electrolyte.

Reference is made to <FIG>, which is a schematic vertical cross-section of a liquid electrolyte memory device according to embodiments of the present invention. In this example, a substrate <NUM> comprises a layer <NUM> comprising the memory regions and the working electrodes, and further comprises a control unit <NUM>. The substrate <NUM> may be submerged in a bath <NUM> comprising the liquid electrolyte. Subsequently, a hermetic capping layer <NUM> is submerged and positioned on top of the substrate <NUM>. Thereby, liquid electrolyte may become trapped in the liquid electrolyte region <NUM> and the memory regions. The hermetic capping layer <NUM> and the substrate <NUM> may be connected to a voltage source <NUM> that is also connected to a counter electrode <NUM> that is also submerged in the bath <NUM>. A voltage may then be applied, so that the hermetic capping layer <NUM> and the substrate <NUM> act as working electrode. Thereby, a metallic film e.g. comprising conductive species in the liquid electrolyte in the bath <NUM> may be electro-deposited on the outer surface of the hermetic capping layer <NUM> and the substrate <NUM>. The metallic film may hermetically seal and mechanically connect the hermetic capping layer <NUM> and the substrate <NUM> to each other, thereby forming a joined hermetic capping layer <NUM> and substrate <NUM> i.e. a liquid electrochemical memory device. In addition, mechanical pressure and thermal treatment may be applied to the joined hermetic capping layer <NUM> and substrate <NUM> after removal from the bath <NUM>, to improve mechanical and electrical connection between the hermetic capping layer <NUM> and the substrate <NUM>.

Reference is made to <FIG>, which is a schematic vertical cross-section of a liquid electrochemical memory device according to embodiments of the present invention. In this example, at least one of the counter electrodes comprises conductive species <NUM>. From the counter electrode comprising conductive species <NUM>, conductive species may be electro-dissolved in the liquid electrolyte. In addition, conductive species may be electro-deposited from the liquid electrolyte onto the counter electrode comprising the conductive species <NUM>. Thereby, the counter electrode comprising the conductive species <NUM> may control the concentration of conductive species in the electrolyte. In addition, the liquid electrochemical memory device may comprise a probing electrode <NUM>. The probing electrode <NUM> may detect the concentration of conductive species in the liquid electrolyte. If, for instance, a concentration of conductive species in the liquid electrolyte is below a threshold, a control unit <NUM> may induce the counter electrode comprising the conductive species <NUM> to electro-dissolve conductive species into the liquid electrolyte. If, for instance, a concentration of conductive species in the liquid electrolyte is above a threshold, a control unit <NUM> may induce the counter electrode comprising the conductive species <NUM> to electro-deposit conductive species from the liquid electrolyte on the surface of the counter electrode comprising the conductive species <NUM>.

Reference is made to <FIG>, which is a schematic vertical cross-section of a liquid electrochemical memory device according to embodiments of the present invention. In this example, the liquid electrochemical memory device comprises a helping electrode <NUM>. The helping electrode <NUM> comprises protective species. The protective species have an electrode potential that is higher (e.g. at least <NUM> V higher) than an electrode potential of the conductive species in the electrolyte. The liquid electrochemical memory device may be powered down and switched in retention mode wherein no external power source may be available. Before the liquid electrochemical memory device is powered down, the helping electrode <NUM> may be biased by the control unit <NUM> so that protective species are electro-dissolved in the liquid electrolyte. Subsequently, the protective species may be electro-deposited on electrodes of the liquid electrochemical memory device, such as on a working electrode <NUM> exposed to a memory region <NUM>, and on a counter electrodes <NUM>. The arrows in <FIG> indicate that protective species move from the helping electrode <NUM> to the electrodes that are to be protected. Thereby, a protective film may be formed over exposed surfaces of the electrodes. The protective film may prevent galvanic corrosion of the electrodes.

Reference is made to <FIG>. For instance, after turning on the liquid electrochemical memory device, the protective species may be electro-dissolved from the working electrode <NUM> and the counter electrodes <NUM>, and electro-deposited on the helping electrode <NUM>. The arrows in <FIG> indicate that protective species move from the electrodes that are to be protected to the helping electrode <NUM>.

Reference is made to <FIG>. In embodiments, the liquid electrochemical memory device according to embodiments of the present invention may comprise a reference electrode <NUM> for sensing a potential in the liquid electrolyte. Preferably, the reference electrode <NUM> is located in the proximity of a memory region (not shown, but comprised in layer <NUM>). In this example, the reference electrode <NUM> is connected to a hermetic capping layer <NUM>. In this example, the reference electrode <NUM> is relatively thick, so that at least part of the reference electrode <NUM> is close to the memory region. The sidewalls of the reference electrode <NUM> that may be not close to the memory region may be covered by an insulating material <NUM>. Thereby, only a potential in the proximity of the memory region may be sensed by the reference electrode <NUM>.

Reference is made to <FIG>. In another example, the reference electrode <NUM> may be located at an end of a channel <NUM>, wherein the channel <NUM> may for instance have the same dimensions of a memory region <NUM>. For instance, the channel <NUM> may be formed simultaneously with the memory region <NUM>. Alternatively, the reference electrode <NUM> may be located on top of a surface <NUM> of the substrate.

Reference is made to <FIG>. In a further example, the liquid electrochemical memory device is a stacked liquid electrochemical memory device. Thereby, a bit density of the liquid electrochemical memory device may be increased. In this example, on top of a silicon substrate <NUM> there is a layer <NUM> comprising an array of memory regions and working electrodes, and a control unit <NUM>. On top of the substate <NUM>, a first hermetic capping layer <NUM> may be provided comprising a first liquid electrolyte region <NUM> and a first counter electrode <NUM>. A further layer <NUM> comprising memory regions, working electrodes and a separate control unit <NUM> may be provided on top of the first capping layer <NUM>. The separate control unit <NUM> is however not required, and instead, a single control unit <NUM> may be used to control all electrodes of the stacked liquid electrochemical memory device. On the further layer <NUM>, a second capping layer <NUM> may be provided, the second capping layer <NUM> comprising a second electrolyte region <NUM> and a second counter electrode <NUM>. The electrolyte in the two liquid electrolyte regions <NUM> and <NUM> may be the same or may be different. Alternatively, the liquid electrolyte regions <NUM> and <NUM> may be fluidically connected to each other. Thereby, the electrolyte may move freely between the liquid electrolyte regions <NUM> and <NUM>.

Claim 1:
A liquid electrochemical memory device (<NUM>) comprising:
- a memory region (<NUM>) for storing at least two bits, the memory region (<NUM>) having a first volume,
- a liquid electrolyte region (<NUM>) fluidically connected to the memory region (<NUM>), the liquid electrolyte region (<NUM>) having a second volume larger than the first volume,
- a working electrode (<NUM>) exposed to the memory region (<NUM>),
- a counter electrode (<NUM>) exposed to the liquid electrolyte region (<NUM>),
- a liquid electrolyte filling the memory region (<NUM>) and the liquid electrolyte region (<NUM>), in physical contact with the working electrode (<NUM>) and the counter electrode (<NUM>), the liquid electrolyte comprising at least two metallic species, and
- a control unit (<NUM>) for biasing the working electrode (<NUM>) and the counter electrode (<NUM>),
characterized in that the counter electrode (<NUM>) comprises the at least two metallic species,
wherein said metallic species are metal ions when in the electrolyte, and metals when deposited.