The invention relates to an electrochemical energy source, comprising: a substrate, and at least one stack deposited onto said substrate, the stack comprising at least the active layers: an anode, a cathode, and an intermediate solid-state electrolyte separating said anode and said cathode. The invention also relates to an electronic device provided with an electrochemical energy source according to the invention. The invention further relates to a method for the manufacturing of an electrochemical source according to the invention, comprising the step of: A) depositing at least one stack deposited onto a substrate, the stack comprising at least the following active layers: an anode, a cathode, and an intermediate solid-state electrolyte separating said anode and said cathode.
Electrochemical energy sources based on solid-state electrolytes are known in the art. These (planar) energy sources, or ‘solid-state batteries’, efficiently convert chemical energy into electrical energy and can be used as the power sources for portable electronics. At small scale such batteries can be used to supply electrical energy to e.g. microelectronic modules, more particular to integrated circuits (IC's). An example hereof is disclosed in the international patent application WO2005/027245, where a solid-state thin-film battery, in particular a lithium ion battery, is fabricated directly onto a structured silicon substrate provided with multiple slits or trenches in which an electron-conductive barrier layer, and a stack of a silicon anode, a solid-state electrolyte, and a cathode are deposited as active layers successively. The slits or trenches are provided in the substrate to increase the contact surface area between the different components of the stack to improve the rate capacity of the battery. The structured substrate may comprise one or more electronic components to form a so-called system-on-chip. The barrier layer is adapted to counteract diffusion of intercalating lithium into said substrate, which diffusion would result in a significant diminished storage capacity of the electrochemical source. Although the known battery exhibits commonly superior performance as compared to conventional solid-state batteries, the known battery has several drawbacks. It has been found that a major drawback of the known battery is that the active layers of the stack will commonly easily degrade due to an non-optimum choice of layer materials and/or the deposition order of the active layers of the stack. This degradation of one or more active layers may be manifested in that these active layers may decompose, may react with adjacent active layers to form interfacial layers with inferior properties and/or may (re)crystallize to form phases with unwanted properties.
It is an object of the invention to provide a relatively stable electrochemical energy source.
This object can be achieved by providing an electrochemical energy source according to the preamble, characterized in that each active layer of the stack which is deposited prior to a subsequent active layer of the stack has a higher annealing temperature than the annealing temperature of the subsequent active layer. It has been found that the degradation of active layers in conventional energy sources known from the prior art, is often caused during deposition, in particular during annealing (also known as curing), of an active layer at a relatively high annealing temperature which may easily overheat, and consequently degrade adjacent active layers already deposited onto the substrate and annealed at a relatively low annealing temperature. This overheating of active layers of the stack deposited earlier may result in decomposition of these layers, allowing these layers to react with other adjacent layers to form detrimental interfacial layers with inferior properties, and/or allowing these layers to (re)crystallize to form phases with undesired properties. By gearing the annealing temperatures of the different active layers, and hence the active layers as such, into a successive order, degradation of these active layers can be prevented in a relatively efficient manner. According to the invention, the deposition order of the different active layers of the stack of the electrochemical energy source according to the invention is dictated by the order of the successive annealing temperatures, or temperature ranges, of the active layers to obtain a relatively stable electrochemical energy source having a relatively reliable performance, and which be manufactured in a relatively reliable manner. During manufacturing of the energy source according to the invention this means in general that the active layer deposited firstly can be deposited and/or annealed at any temperature (as long as the substrate allows it). The subsequent active layer of the stack shall be deposited/annealed at a temperature lower, and preferably significantly lower (about 50° C.), than the first active layer, and so on. This inherently means that the final active layer of the stack shall be deposited at the lowest temperature. Commonly, the annealing process is considered as being a (final) part of the deposition process of an active layer, wherein each active layer has its own optimum annealing temperature, or annealing temperature range, with which this active layer will acquire the specific material properties needed to function properly in the battery stack. Besides the critical deposition order which is applied to the electrochemical energy source according to the invention, preferably the materials of the different active layers are mutually chemically stable and compatible. A reaction between two chemically incompatible materials should preferably be avoided at any (annealing) temperature to secure a durable and adequate functioning of the electrochemical energy source according to the invention.
In a preferred embodiment the solid-state electrolyte is deposited on top of the cathode, and the anode is deposited on top of the solid-state electrolyte. According to this embodiment a stack is applied, wherein the cathode, the solid-state electrolyte, and the anode are deposited successively onto the substrate. The reason to apply this specific deposition order is that commonly the annealing temperature of the cathode is higher than the annealing temperature of the solid-state electrolyte which is thereupon higher than the annealing temperature of the anode. Although it is expected that commonly this deposition order will be applied in most electrochemical energy sources according to the invention, the invention is not limited to this specific deposition order. It could also be conceivable for a person skilled in the art to apply a reverse stack of an anode, on top of which an electrolyte is deposited, on top of which electrolyte a cathode is deposited. This reverse stack will probably be applied in case the annealing temperature of the anode is higher than the annealing temperature of the electrolyte which is thereupon higher than the annealing temperature of the cathode.
The electrochemical energy source preferably comprises at least two current collectors connected to the anode and to the cathode of the stack respectively. It is generally known to apply current collectors as electrode terminals. In case e.g. a Li-ion battery with a LiCoO2 cathode is applied, preferably an aluminium current collector is connected to the LiCoO2 cathode. Alternatively or in addition a current collector manufactured of, preferably doped, semiconductor such as e.g. Si, GaAs, InP, as of a metal such as silver, gold, platinum, copper or nickel may be applied as current collector in general with solid-state energy sources according to the invention. The current collectors are not part of the stack as defined above. Current collectors are commonly deposited at room temperature. Preferably a corrosion resistant current collector, such as a platinum current collector, is deposited onto the substrate, in case the first active layer of the stack is to be deposited in an oxygen environment at an annealing temperature (considerably) higher than room temperature. In case said first active layer is deposited in an inert environment, wherein practically no oxygen is present, at an increased annealing temperature the current collectors may be made of a material which is (significantly) less corrosion resistant, such as copper for example.
In a preferred embodiment of the energy source according to the invention the substrate and the anode are separated by means of an electron-conductive barrier layer adapted to at least substantially preclude diffusion of intercalating active species into said substrate. This preferred embodiment is commonly very advantageous, since intercalating reactive species taking part of the (re)charge cycles of the energy system according to the invention often diffuse into the substrate, such that these reactive species do no longer participate in the (re)charge cycles, resulting in a reduced storage capacity of the electrochemical source. Commonly, a monocrystalline silicon conductive substrate is applied to carry electronic components, such as integrated circuit, chips, displays, et cetera. This crystalline silicon substrate suffers from the drawback that the intercalating species diffuse relatively easily into said substrate, resulting in a reduced capacity of said energy source. For this reason it is considerably advantageous to apply a barrier layer onto said first substrate to preclude said unfavourable diffusion into the substrate. Migration of the intercalating species will be blocked at least substantially by said barrier layer, as a result of which migration of these species through the substrate will no longer occur. It is in particularly advantageous to apply a barrier layer in case the anode is connected to the substrate, wherein the anode is adapted for storage of active species in an atomic state. In lithium ion batteries commonly an (amorphous) silicon anode is deposited onto a (monocrystalline) silicon substrate, said silicon anode being adapted to store lithium species in an atomic state. To prevent a loss of effective active species preferably a barrier layer as defined above is applied to mutually separate the (silicon) anode and the (silicon) substrate. In case the anode is, however, not adapted to store active species in atomic state but rather in ionic state, commonly the application of a barrier layer is no longer required. An example of an anode which is adapted to store active species in ionic state is an oxygen containing anode. In this latter case, preferably a relatively corrosion resistant current collector, which may be made of platinum, is connected to the oxygen containing anode to counteract oxidation of the current collector during deposition of the anode layer. In case an electron-conductive barrier layer is applied this barrier layer may (also) be used to function as a current collector for the anode. In a preferred embodiment the barrier layer is preferably at least substantially made of at least one of the following compounds: tantalum (Ta), tantalum nitride (TaN), titanium (Ti), and titanium nitride (TiN). These compounds have as common property a relatively dense structure which is permeable for electrons and impermeable for the intercalating species, among which lithium (ions). The material of the barrier layer is however not limited to these compounds.
Preferably, the electrochemical energy source is formed by at least one battery selected from the group consisting of alkaline batteries and alkaline earth batteries. Alkaline (earth) storage batteries such as nickel-cadmium (NiCd), nickel-metal hydride (NiMH), or lithium-ion (Li-ion) storage batteries are commonly highly reliable, have a satisfying performance, and are capable of being miniaturized. For these advantages, they are used both as the power sources of portable appliances and industrial power sources, depending on their size. Preferably, the at least one electrode of the energy source, preferably formed by battery, is adapted for storage of ions of at least one of following elements: hydrogen (H), lithium (Li), beryllium (Be), magnesium (Mg), copper (Cu), silver (Ag), aluminium (Al), sodium (Na) and potassium (K), or any other suitable element which is assigned to group 1 or group 2 of the periodic table. So, the electrochemical energy source of the energy system according to the invention may be based on various intercalation mechanisms and is therefore suitable to form different kinds of batteries, e.g. Li-ion batteries, NiMH batteries, et cetera.
In a preferred embodiment the cathode is made of at least one material selected from the group consisting of: LiCoO2 (600-800° C.) LiMn2O4 (˜600° C.), LiFePO4 (˜700° C.), V2O5 (˜500° C.), MoO3 (˜280° C.), WO3 (˜300° C.), and LiNiO2. It is has been found that at least these materials are highly suitable to be applied in lithium ion energy sources and, moreover, these materials have a predefined optimum annealing temperature range or temperature range (cited above in parentheses), based upon which an optimum deposition order may be determined. Examples of a cathode in case of a proton based energy source are Ni(OH)2 and NiM(OH)2, wherein M is formed by one or more elements selected from the group of e.g. Cd, Co, or Bi. It may be clear that also other cathode materials may be used in the electrochemical energy source according to the invention. The anode is preferably made of at least one material selected from the group consisting of: Si (<<600° C.), SnOx (˜350° C.), Li4Ti5O12 (600-800° C.), SiOx, LiSiON, LiSnON, and LiSiSnON, in particular LixSiSn0.87O1.20N1.72. As the cathode materials, these materials are suitable to be applied in a lithium ion battery, and, moreover, have a predefined optimum annealing temperature or temperature range (cited above in parentheses). The solid-state electrolyte is made of at least one material selected from the group consisting of: Li5La3Ta2O12 (Garnet-type class; 600-700° C.), LiPON (˜room temperature), LiNbO3 (˜400° C.), LiTaO3 (˜400° C.), and Li9SiAlO8 (˜900° C.), These solid-state electrolyte materials are suitable to be applied in lithium ion batteries, and have a known optimum annealing temperature (cited above in parentheses). Other solid-state electrolyte materials which may be applied smartly are lithium orthotungstate (Li2WO4), Lithium Germanium Oxynitride (LiGeON), Li14ZnGe4O16 (lisicon), Li3N, beta-aluminas, or Li1.3Ti1.7Al0.3(PO4)3 (nasicon-type). A proton conducting electrolyte may for example be formed by TiO(OH), or ZrO2Hx.
In a preferred embodiment the substrate is at least partially made of silicon. More preferably, a monocrystalline silicon conductive substrate is applied to carry electronic components, such as integrated circuit, chips, displays, et cetera. This crystalline silicon substrate suffers from this drawback that the intercalating active species diffuse relatively easily into said substrate, resulting in a reduced capacity of said energy source. For this reason it is considerably advantageous to apply a barrier layer onto said substrate to preclude said unfavourable diffusion into the substrate.
The invention also relates to an electronic device provided with at least one electrochemical energy source according to the invention. An example of such an electric device is a shaver, wherein the electrochemical energy source may function for example as backup (or primary) power source. Other applications which can be enhanced by providing a backup power supply comprising an energy system according to the invention are for example portable RF modules (like e.g. cell phones, radio modules, et cetera), sensors and actuators in (autonomous) micro systems, energy and light management systems, but also digital signal processors and autonomous devices for ambient intelligence. It may be clear this enumeration may certainly not being considered as being limitative. Another example of an electric device wherein an energy source according to the invention may be incorporated (or vice versa) is a so-called ‘system-in-package’ (SiP). In a system-in-package one or multiple electronic components and/or devices, such as integrated circuits (ICs), chips, displays, et cetera, are embeddded at least partially in the substrate, in particuarly a monocrystalline silicon conductive substrate, of the electrochemical energy source according to the invention.
The invention further relates to a method according to the preamble, characterized in that during step A) the active layers of stack are deposited in a deposition order wherein an subsequent active layer of the stack which is deposited onto a prior active layer of the stack has a lower annealing temperature than the annealing temperature of said prior active layer of the stack. Advantages of this method have already been elucidated above in a comprehensive manner. Preferably, during step A) the cathode, the solid-state electrolyte, and the anode are deposited successively onto the substrate. Commonly this deposition order will be in harmony with a decrease in an optimum annealing temperature for the active layers of the stack respectively. In a preferred embodiment the method further comprises step B) of depositing a first current collector onto the substrate prior to step A), on top of which current collector the stack is deposited during step A). In another preferred embodiment the method further comprises step C) of depositing a second current collector onto the stack deposited onto the substrate during step A). Particular examples of materials of active layers of the stack, and of the current collector(s) to be applied have already been elucidated above.
The invention is illustrated by way of the following non-limitative examples, wherein:
Considering the entire deposition of the different active layers 3, 4, 5, 8, 9 and in particular the active layers 3, 4, 5 of battery stack 2 again, including the data given in Table 1, several possible problems due to a non-optimum deposition order are expected to occur. The deposition of the first layer 1, id est the barrier layer 8, onto the substrate 6 at room temperature using Atomic Layer Deposition (ALD) will be readily feasible, as well as the deposition of the silicon anode 3 (substantially) below 600° C., preferably at a few hundred degrees Celsius. Deposition of the solid-state electrolyte 4 made of LiNbO3 at temperatures below 450° C. will yield amorphous material as required. However, deposition of LiNbO3 will require an oxygen atmosphere and temperatures around 200° C. in order to decompose metal-organic precursors used during deposition. This can result in the formation of SiCO2 at the Si/LiNbO3 interface of the anode 3 and the electrolyte 4, which is unwanted as SiCO2 will probably act as a blocking layer.
Subsequent deposition of LiCoO2 to form the cathode 5 at temperatures below 600° C. will yield merely amorphous material, which is electrochemically inferior to the preferred HT crystalline phase. However, post annealing at 800° C., in order to crystallize the cathode 5 will cause additional phenomena in the underlying and already deposited layers; the LiNbO3 electrolyte 4 has a crystallization temperature of about 470° C., and will hence crystallize at this relatively high annealing temperature, resulting in inferior Li-ion conducting properties. The amorphous Si of the anode 3 crystallizes to polycrystalline Si, which is not detrimental to the Li-intercalating behave of the anode 3. Hugely increasing the annealing temperature of the cathode 5 will result in severe intermixing at the Si/LiNbO3 interface of the anode 3 and the electrolyte 4 as both are not chemically stable. The deposition of the last layer, the cathode current collector 9, can be done under relatively mild conditions once again at room temperature and no problems are expected during this deposition step. The above shows that deposition of the active layers 3, 4, 5 of the battery stack 2 is not straight-forward and might yield potential bottlenecks.
Considering this improved deposition order, it can be seen that the optimum annealing temperature to obtain an active material layer 12, 13, 14 of the stack 11 in the preferred phase is lower for each subsequent active layer 13, 14 than the optimum annealing temperature for each active layer 12, 13 deposited earlier than the subsequent layers 13, 14 of the stack 11. During manufacturing of the electrochemical energy source 10 as shown in
It should further be noted that the above-mentioned embodiments illustrate rather than limit the invention, and that those skilled in the art will be able to design many alternative embodiments without departing from the scope of the appended claims. In the claims, any reference signs placed between parentheses shall not be construed as limiting the claim. Use of the verb “comprise” and its conjugations does not exclude the presence of elements or steps other than those stated in a claim. The article “a” or “an” preceding an element does not exclude the presence of a plurality of such elements. The mere fact that certain measures are recited in mutually different dependent claims does not indicate that a combination of these measures cannot be used to advantage.
Number | Date | Country | Kind |
---|---|---|---|
06119297.7 | Aug 2006 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/IB07/53312 | 8/20/2007 | WO | 00 | 2/23/2009 |