Patent Application
20170301897
The present embodiments relate to thin film encapsulation (TFE) technology used to protect active devices, and more particularly to encapsulating electrochemical devices.
Thin film encapsulation technology is often employed in devices where the devices are purely electrical devices or electro-optical devices, such as Organic Light Emitting Diodes (OLED). Other than possibly experiencing a generally small global thermal expansion from heat generation during the device operation, these electrical devices and electro-optical devices do not exhibit volume changes during operation, since just electrons and photons are transported within the devices during operation. Such global effects due to global thermal expansion of a device may affect in a similar fashion every component of a given device including the thin film encapsulant, and thus, may not lead to significant internal stress. In this manner, the functionality of the thin film encapsulant in a purely electrical device or electro-optic device is not generally susceptible to stresses from non-uniform expansion during operation.
Notably, in an electrochemical device (“chemical” portion), matter such as elements, ions, or other chemical species having a physical volume (the physical volume of electrons may be considered to be approximately zero) are transported within the device during operation with physical volume move. For known electrochemical devices, e.g., a lithium thin film battery (LiTFB) based upon lithium (Li), Li is transported from one side to the other side of a battery as electrons are transported in an external circuit connected to the LiTFB, where the electrons move in an opposite direction to the chemical and elements. One particular example of the volume change experienced by a LiTFB is as follows. When charging a thin film battery having a lithium cobalt oxide (LiCoO2) cathode (˜15 μm to 17 μm thick LiCoO2), an amount of Li equivalent to several micrometers thick layer, such as 6 micrometers (assuming 100% density), may be transported to the anode when loading is approximately 1 mAhr/cm2. When Li returns to the cathode side in a discharge process, a comparable volume reduction may result on the anode side (assuming 100% efficiency). The cathode side may also undergo a volume change in an opposite manner, while such changes are much smaller as compared to the anode side.
As such, known thin film encapsulant structures may be lacking the ability to accommodate such volume change in a robust manner, to ensure the thin film encapsulant continues to provide protection of the electrochemical device during repeated cycling of the device.
With respect to these and other considerations the present disclosure is provided.
In one embodiment, a thin film device may include an active device region, the active device region having reversible motion at least along a first direction between a first device state and a second device state. The thin film device may also include a thin film encapsulant disposed adjacent the selective expansion region, wherein the thin film encapsulant comprises a first thickness in the first device state and a second thickness in the second device state. The first thickness may be greater than the second thickness by 10% or greater, wherein the thin film encapsulant comprises a laser-etchable material.
In another embodiment, a thin film battery may include a cathode region comprising a diffusant; an anode, wherein transport of the diffusant takes place between the cathode region to and the anode; and a thin film encapsulant disposed adjacent the anode. The thin film encapsulant may include a first thickness in a first device state and a second thickness in a second device state, the first thickness being greater than the second thickness by 10% or greater, wherein the thin film encapsulant comprises a laser-etchable material.
The present embodiments will now be described more fully hereinafter with reference to the accompanying drawings, where some embodiments are shown. The subject matter of the present disclosure may be embodied in many different forms and are not to be construed as limited to the embodiments set forth herein. These embodiments are provided so this disclosure will be thorough and complete, and will fully convey the scope of the subject matter to those skilled in the art. In the drawings, like numbers refer to like elements throughout.
The present embodiments are related to thin film encapsulant materials and processes, where a thin film encapsulant is used to minimize ambient exposure of active devices. The present embodiments provide novel structures and materials combinations for thin film encapsulants. In various embodiments a thin film encapsulant may be provided to encapsulate active device regions where motion takes place within the active device region during operation. The thin film encapsulant and the active device region may be referred to herein as a “device.” In addition, the active device region may constitute an active device as detailed below. The motion within an active device region of the overall device may extend up to serval micrometers, for example. Examples of active devices forming all or part of the active device region include piezoelectric devices, shape memory alloy devices, MEMS device, as well as electrochemical devices such as thin film batteries wherein the active component materials are highly sensitive/reactive to moisture or other ambient materials. To this end, known electrochemical devices such as thin film batteries may be provided with encapsulation to protect the active component materials. The present embodiments also address a problem encountered in devices such as thin film batteries, where a large physical volume change (expansion and contraction) may take place during the operation of the device. More particularly, as noted, volume changes in a device such as a Li thin film battery may take place in a localized or non-uniform manner in a “selective expansion” region, such as an anode. Various embodiments of the disclosure provide appropriate structures and appropriate thin film encapsulant materials and methods of applying such materials in a device, such as a thin film battery, resulting in device structures meeting stringent thin film encapsulant requirements. The present embodiments may also provide structures and materials in a thin film encapsulant serving a combination of other functions. These other functions may include providing improved planarization capability, chemical stability when in contact with diffusant species such as Li, and adequate absorption of laser irradiation over given wavelengths, to provide maskless patternability.
In various embodiments, a device such as a thin film device, is provided with a novel thin film encapsulant region (or, simply, “thin film encapsulant”). As noted, the device may be a piezoelectric device, shape memory alloy device, MEMS device in some embodiments. In other embodiments, the film device may be a thin film battery or electrochromic window. In these embodiments, the active device region may exhibit reversible motion at least along a first direction between a first device state and a second device state, where motion takes place over a scale of tenths of micrometers or up to several micrometers. The embodiments are not limited in this context. The reversible motion may take place in a plurality of cycles, such as tens of cycles, hundreds of cycles, thousands of cycles, millions of cycles, and so forth.
In embodiments where active device is an electrochemical device such as a thin film battery, the active device region may include a source region comprising a diffusant, as well as a selective expansion region, wherein transport of the diffusant takes place from the source region to the selective expansion region. According to various embodiments, the transport of diffusant may take place reversibly between the source region and the selective expansion region. In embodiments where the thin film device is a Li thin film battery, a cathode, such as a solid state cathode, may act as the source region and may include a material such as LiCoO2 or similar material. In embodiments of a Li thin film battery, an anode may act as a selective expansion region, where a large volume change takes place selectively in the selective expansion region, as opposed to other regions in the thin film device.
To accommodate changes in volume in a selective expansion region, various embodiments provide materials and/or structures in a thin film encapsulant, where the thin film encapsulant is effective to accommodate volume expansion and contraction in the selective expansion region, rendering a more robust thin film device.
According to various embodiments, the thin film encapsulant may include at least one layer and may encapsulate at least portions of the source region and selective expansion region. In various embodiments, the thin film encapsulant, at least in a portion adjacent the selective expansion region, may reversibly vary thickness from a first thickness to a second thickness to accommodate changes in volume or thickness of materials in the selective expansion region. For example, in a thin film battery where an anode or a portion of an anode may constitute a selective expansion region, as a result of lithium migration, the anode may change in thickness by several micrometers between a charged state and a discharged state in the thin film battery. In the present embodiments, the thin film encapsulant may expand or contract in thickness to accommodate for the increase or decrease in anode thickness, resulting in less stress, less mechanical failure, and better protection of the active device of a thin film device. Depending upon the thickness of the thin film encapsulant, the change in thickness between a first thickness in a charged state and a second thickness in discharged state may be as follows. The first thickness may be greater than the second thickness by 5% or more, and in some examples, the first thickness is greater than the second thickness by 10% or more. The embodiments are not limited in this context.
According to various embodiments, the thin film encapsulant may include at least one layer comprising a laser-etchable material and in particular a material etchable according to laser ablation or similar process. In a thin film encapsulant containing a laser-etchable material, electromagnetic radiation of a given wavelength of a laser beam is highly absorbed in the thin film encapsulant. Examples of suitable radiation wavelengths include the range from 157 nm to 1064 nm. For example, for a laser beam having a wavelength in the visible range, a transparent or completely clear-appearing polymer layer may not be highly absorbent of the electromagnetic radiation of the laser beam. For the same laser beam having wavelength in the visible range, an opaque, black, or translucent polymer layer may be highly absorbent of the electromagnetic radiation, and may accordingly be deemed a laser-etchable material. The embodiments are not limited in this context. In this manner, a patterned thin film device such as a thin film battery may be formed, where the active device portions of the thin film battery as well as a volume-change-accommodating encapsulant can be patterned using a maskless process. A useful maskless process includes laser patterning, suitable to define the final device structure including the thin film encapsulant.
Turning now to
Turning now to
In some embodiments the thin film encapsulant 110 includes a polymer stack (not separately shown in
In various embodiments, the thin film encapsulant 110 may have an elongation property of at least 5%. In particular embodiments, the elongation to break may be 70% or greater for at least one polymer layer of the thin film encapsulant.
According to various embodiments, the thin film encapsulant 110 may include a polymer layer having a thickness of 10 μm to 50 μm, and the selective expansion region 108 may constitute an anode. The anode thickness may change by at least 1 μm between a charged state and a discharged state. In specific embodiments, the polymer layer of the thin film encapsulant 110 may constitute a polymer layer stack including multiple sub-layers of different polymers, where at least one sub-layer is soft and pliable. By proper choice of the thickness of thin film encapsulant and the materials for a thin film encapsulant, the thin film encapsulant 110 may have adequate flexibility to accommodate expansion and contraction of at least 1 μm when the thin film device 100 is cycled between states, such as a charged state and discharged state in embodiments of a thin film battery. The accommodation of changes in volume of the selective expansion region 108 may be accomplished in a manner avoiding stress-induced cracking in the encapsulant materials, as well as delamination or other degradation, where such degradation may compromise the integrity of the thin film device being protected.
According to various embodiments of the disclosure a thin film encapsulant may be formed from a multilayer stack, where the multilayer stack includes at least one polymer layer. In specific embodiments, a given polymer “layer” is arranged as a polymer layer stack having a plurality of polymer sub-layers as described above. In particular embodiments, the thin film encapsulant 110 may include a getter/absorbent infused polymer material, a porous low dielectric constant material, an epoxy, a printed circuit board material, a photo-resist material, or a silver paste, and combinations thereof. In addition to the aforementioned materials, particular examples of suitable polymer materials include silicone, rubber, urethane, polyurethane, polyurea, polytetrafluoroethylene (PTFE), parylene, polypropylene, polystyrene, polyimide, nylon, acetal, ultem, acrylic, epoxy, and phenolic polymers. The embodiments are not limited in this context.
In various embodiments, the thin film encapsulant 110 may be arranged with a dyad, where a given dyad includes a polymer layer and a rigid moisture barrier layer such as a dielectric layer or a metal layer, or combinations of metal layer and dielectric layer. The dyad may act as a “functional dyad” where at least one layer of the functional dyad provides a diffusion barrier to contaminants such as moisture; and at least one layer includes a soft and pliable layer for accommodating changes in dimension of an active device region in a reversible manner. A suitable metal layer may include Cu, Al, Pt, Au, or other metal. A rigid dielectric layer may be composed of a known material such as silicon nitride where the rigid dielectric layer has a combination of relatively high elastic modulus and hardness, for example. In the case of silicon nitride, the Vicker's hardness is ˜13 GPa, and Young's Modulus is ˜43500 Kpsi or ˜300 GPa). Accordingly, the rigid dielectric layer is less pliable than the polymer layer (e.g., exemplary mechanical properties of polymer layers include silicone: hardness of ˜A40 Shore A, Young's Modulus of ˜0.9 Kpsi or ˜6.2 MPa; Parylene-C: hardness of ˜Rockwell R80, Young's Modulus of ˜400 Kpsi or ˜2.8 GPa; KMPR: Young's Modulus of ˜1015 Kpsi or ˜7.0 GPa; polyimide: hardness of D87 Shore D, Young's Modulus of ˜2500 Kpsi or ˜17.2 GPa). Other examples of appropriate rigid dielectric materials include sputtered dielectric materials (i.e. sputtered Pyrex or similar borosilicate material), low temperature spin-on or powder coated dielectric or glaze coatings (processed with or without surface Rapid Thermal Processing to improve barrier properties).
As used herein, a “soft and pliable” material may refer to a material having an elastic (Young's) modulus less than 20 GPa, for example, while a “rigid material” such as a rigid metal or rigid dielectric may have an elastic modulus greater than 20 GPa. Other characteristic properties associated with a soft and pliable material include a relatively high elongation to break, such as 70% or greater for at least one polymer layer of the thin film encapsulant. In some examples, such as silicone, a soft and pliable material may have an elongation to break up to 200% or greater.
The dielectric breakdown voltage of a rigid dielectric layer may exceed 4 MV/cm in some examples. The high dielectric breakdown strength may in general be an indication of high electrical resistivity. For rigid dielectrics (and polymers) in a battery of the present embodiments, a high electrical resistivity, as indicated by the high dielectric breakdown voltage, prevents shorting from anode current collector or cathode current collector through the thin film encapsulant.
In some embodiments, the thin film encapsulant may be arranged having a plurality of dyads.
Configurations where a polymer layer such as polymer layer 120 is a polymer layer stack including multiple polymer sub-layers may provide advantages over configurations having just one polymer layer. For example, a three-layer polymer layer stack may have an inner polymer layer exhibiting soft and pliable properties and outer polymer layers, where the outer polymer layers are harder and function to distribute stress more uniformly. The harder polymer layers may accordingly reduce localized abnormally high stress points, where such stress points would otherwise cause puncturing of the rigid dielectric layer 122, for example.
Turning now to
As shown in
As additionally shown in
In various embodiments, at least the thin film encapsulant 212 may be patterned by a laser etching process, in particular by a maskless laser process, such as laser ablation. The material(s) of the thin film encapsulant 212, including individual polymer layers, as well as any rigid dielectric or metal layers, such as a rigid metal layer, may be designed to absorb the electromagnetic radiation of a given laser used to perform laser ablation. In some embodiments, having a laser wavelength in the high energy range (i.e. green, UV, deep UV) is useful to provide good layer-by-layer material ablation control. Hence, a thin film encapsulant material having good light absorption properties in these laser wavelengths may be patterned more effectively. Providing coloration in a thin film encapsulant material is useful to enable laser beam absorption. For example, magenta coloring of a thin film encapsulant will work well in conjunction with the use of green lasers since green light absorption is maximized for this color. Black coloring also works well for thin film encapsulant coloring. Also, dyes and pigments for use as thin film encapsulant material coloring material may be selected so as not to have chemical reactivity with battery cell materials of interest.
While in some of the aforementioned embodiments suitable radiation wavelengths may include the range from 266 nm to 1064 nm, in other embodiments excimer laser radiation may be used to pattern at least the thin film encapsulant part of a device. In this case the optical properties of materials such as polymers in the thin film encapsulant may include a layer absorbent to laser radiation at a wavelength in a range of 157 nm to 1064 nm. In particular, the thin film encapsulant may be tuned to be highly absorbent at the wavelength of a given excimer laser, such as ˜157 nm, 172 nm, 193 nm, 248 nm, 1064 nm. Accordingly, radiation wavelengths useful for patterning a thin film encapsulant in the present embodiments may extend between 157 nm to 1064 nm. As disclosed herein above, a thin film encapsulant may be formed for a thin film device where the structure and materials of the thin film encapsulant accommodate selective volume changes taking place within certain regions (a “selective expansion region”) of the thin film device. The selective volume changes may be reversible volume changes where a component such as an anode increases in thickness and decreases in thickness. The materials of the thin film encapsulant may be tailored so a maskless process, such as laser ablation may be used to pattern the thin film devices. In this manner, electrochemical device structures able to accommodate volume expansion during cycling between different states may be conveniently be formed using a combination of deposition processes and maskless patterning.
There are multiple advantages provided by the present embodiments, including the ability to reduce the amount of non-active packaging materials used in a thin film device, leading to enhanced energy density of these devices, as well as the further advantage of the ability to conveniently form a thin film device using maskless patterning of the thin film encapsulant.
The present disclosure is not to be limited in scope by the specific embodiments described herein. Indeed, other various embodiments of and modifications to the present disclosure, in addition to those described herein, will be apparent to those of ordinary skill in the art from the foregoing description and accompanying drawings. Thus, such other embodiments and modifications are intended to fall within the scope of the present disclosure. Furthermore, the present disclosure has been described herein in the context of a particular implementation in a particular environment for a particular purpose, while those of ordinary skill in the art will recognize the usefulness is not limited thereto and the present disclosure may be beneficially implemented in any number of environments for any number of purposes. Thus, the claims set forth below are to be construed in view of the full breadth and spirit of the present disclosure as described herein.
This Application claims priority to U.S. provisional patent application No. 62/322,415, filed Apr. 14, 2016, entitled Volume Change Accommodating TFE Materials, and incorporated by reference herein in its entirety.
| Number | Date | Country | |
|---|---|---|---|
| 62322415 | Apr 2016 | US |
