1. Field of the Invention
The present invention relates to transistor devices formed on flexible substrates, and more specifically to a device including a first dielectric layer formed by anodizing a patterned metal, with an optional subsequently formed second dielectric layer thereover.
2. Description of the Prior Art
There exists today many types and techniques for fabricating flat-panel display devices, for example of the type used as a computer display, television monitor, etc. For the purposes herein, the term “display” will generically encompass all such devices. Displays may be comprised of active matrix or passive matrix elements, and may be either transmissive or reflective. At the core of each picture element, or pixel, of these displays is most commonly a thin-film transistor (TFT). Transmissive and reflective displays typically include polysilicon or amorphous silicon thin-film transistors. Organic semiconductor thin film transistors are also becoming increasingly important.
Displays are generally comprised of at least a substrate and a backplane. The backplane forms the electrical interconnection of the display and typically comprises electrodes, capacitors, and transistors for addressing the individual pixels making up the display. The substrate forms the structure carrying the backplane, and is often (but not always) the structure upon which the backplane is formed. Substrates may be divided into classes of either rigid or flexible. As their classification suggests, rigid substrates are not intended to be bent, flexed, or deformed. In many applications, rigidity is desirable, for example in computer displays (desktop and portable), television monitors, cell phone and PDA displays, etc. However, in certain applications a flexible display, i.e., one able to bend, fold, roll, etc., is desirable. In these applications, the substrate and backplane must be sufficiently flexible to accommodate.
Formation of backplanes on rigid substrates is better known and more common today than is forming backplanes on flexible substrates. Many of the current limitations on using flexible substrates originate with the process requirements and structures of the devices, such as the thin-film transistors (TFTs), which comprise the backplane.
As an example, a schematic illustration of the backplane circuitry 10 of a typical prior art TFT display array is provided in
In one typical example, backplane 10 may be formed by a series of depositions and etchings on a rigid substrate (e.g., glass). An active medium (e.g., a liquid crystal, not shown) is deposited at least over the pixel electrodes 40, 42. Optical properties of localized regions of the active medium may then be altered in response to voltages or currents produced by the pixel electrodes, when polarizing films are placed on either side of the display. For example, the active medium at a given pixel electrode may become transparent or opaque in response to a voltage applied to the pixel electrode, thereby forming the appearance of a rectangle, dot, etc. at that pixel. The application of a color filter or filter grid (not shown) over the active material can provide the appearance of a colored rectangle, dot, etc. Images may then be formed on the array by individually addressing the TFTs in each of the plurality of pixels forming the backplane matrix.
Of particular relevance to the present invention, the aforementioned dielectric layer 50 is typically formed by a relatively high temperature process, such as chemical vapor deposition (CVD). This high temperature process is most often compatible with typical rigid substrates. There is, however, a desire to use flexible substrates in order to produce flexible displays, sensor arrays, etc. Unfortunately, the material from which the flexible substrates are formed cannot withstand typical high temperature deposition processes. For example, above about 150° C., the typical flexible substrate material deforms. Furthermore, typical dielectric layers formed by higher temperature processes exhibit high intrinsic mechanical stress, which deforms the substrate and makes alignment for subsequent processing steps difficult.
There have been efforts to develop deposition processes compatible with flexible substrates, but such efforts have heretofore failed to produce effective results. For example, low temperature deposition processes have been developed, for example for forming the dielectric layer. However, dielectric layers formed by these processes have typically been of poor quality and exhibit poor performance, for example due to a high density of pin holes, excessive leakage currents, etc. Efforts to address the quality of the dielectric layers, for example by forming a relatively dense or thick dielectric layer have proved inadequate since as the density or thickness of the dielectric layer increases, so does the mechanical stress within the layer, resulting in deformation of the substrate and difficulty with alignment for subsequent processing steps. Furthermore, obtaining proper operating capacitance of the gate dielectric limits the thickness of the dielectric layer.
Another impediment associated with using a flexible substrate is surface roughness. Flexible substrates have a relatively higher surface roughness that traditional non-flexible substrates such as glass. Surface roughness is important when depositing organic semiconductors, as the surface roughness affects the organization of the polymer chains which determine the mobility of the material. Forming an organic semiconductor on a rough base results in ineffective polymer self-organization, and hence poor mobility and degraded device performance.
Efforts to address the roughness issue have again focused on forming a relatively thick dielectric layer. However, such a thick dielectric introduces the aforementioned stress and thickness-based capacitance issues, as well as so-called step coverage problems (e.g., non-uniform layer thicknesses at top, side, and corner of gate electrode), and the associated difficulties with controlling parasitic capacitances and shorts.
Accordingly, the present invention is directed to a method of forming, and structure so formed, operable as a thin film transistor. More particularly, the present invention is directed to a gate dielectric formed by a low temperature (e.g., at or below 150° C.) process. The method, and the structure so produced, is compatible with flexible substrates, enabling the production of, for example, flexible display and sensor arrays. A novel flexible display and a novel flexible sensor array are thus enabled.
According to one aspect of the invention the method begins with the deposition of a gate metal on a flexible substrate. The gate metal is patterned to form transistor gate structures and gate lines. The gate metal is then anodized to form a first dielectric layer which is self-patterning with the patterned gate metal. A second dielectric layer is then formed or deposited by a low temperature process over the first dielectric layer. The second dielectric layer is then patterned such that it is roughly the width of the anodized first dielectric layer. Importantly, all steps to this point in the process are performed at a low temperature, preferably at or below 150° C. The dielectric material therefore resides solely over the gate metal, providing a structure with minimized dielectric-induced intrinsic stress, and hence minimized deformation of the substrate.
According to a second aspect of the invention, the second dielectric layer is deposited such that a relatively smooth, uniform top surface is presented on which a semiconductor layer can subsequently be deposited. The smooth, uniform top surface allows an organic semiconductor material to self-organize, thereby providing desired electron/hole mobility in the layer of that material.
The above is a summary of a number of the unique aspects, features, and advantages of the present invention. However, this summary is not exhaustive. And while an example of the present invention has been described in terms of a display device, an array of other assemblies such as radiation detectors (x-ray, radar, etc.), micro-electro-mechanical structural elements (MEMS), flexible antennas or, generally, an assembly of sensors or actuators or an assembly of circuit elements may similarly be produced. Thus, these and other aspects, features, and advantages of the present invention will become more apparent from the following detailed description and the appended drawings, when considered in light of the claims provided herein.
In the drawings appended hereto like reference numerals denote like elements between the various drawings. While illustrative, the drawings are not drawn to scale. In the drawings:
a-3f are cut-away side views of a TFT device during manufacture according to one embodiment of the present invention.
a-4b are optical micrographs of a portion of a TFT fabricated according to the embodiment of the present invention illustrated in
a and 18b are graphs of the transfer and output characteristics, respectively, of a TFT according to the second embodiment of the present invention.
a-28c are optical micrographs of portions of an array of pixels, manufactured according to the embodiment of the present invention illustrated in
a and 29b are graphs of the transfer and output characteristics, respectively, of a TFT according to the third embodiment of the present invention.
According to a first embodiment of the present invention, illustrated in
As an alternative to the process so far, a layer of aluminum may initially be deposited over substrate 72, and patterned to form a gate sub-structure. The aforementioned layer 74 of tantalum is then deposited over the aluminum gate sub-structure. The tantalum layer is patterned such that it encloses the aluminum sub-structure over substrate 74. While not required by the present invention, this tantalum/aluminum gate structure provides increased conductivity for gate lines and similar structures, if required.
With reference now to
The source/drain metal layer 82 may next be deposited over Ta2O5 dielectric layer 80 and the exposed portions of substrate 27, as illustrated in
The structure formed so far is then subjected to an etch which removes portions of the source/drain metal layer 82 exposed by masking structures 84, leaving source electrode 86 and drain electrode 88. Furthermore, Ta2O5 dielectric layer 80 is resistant to the etching performed, and thus remains intact even after the etching has removed that portion of the source/drain metal layer 82 previously disposed thereover. Conventional metal etching chemicals can be used. The structure at this stage appears as shown in
The final step illustrated in this embodiment of the present invention is shown in
There is a certain degree of control over the thickness of Ta2O5 dielectric layer 80 permitted in the aforementioned anodizing of tantalum gate structure 78. For example, according to one embodiment of the present invention, the anodizing is performed at room temperature, and at a rate of approximately 18 Å/volts, consuming approximately 1 nm of tantalum for each 2 nm of Ta2O5. Using a limiting voltage of approximately 150 volts produces a 270 nm thick layer of Ta2O5, as illustrated in
It will be noted from
Finally, in addition to the formation of individual TFTs, the gate dielectric according to the present invention is also used to electrically isolate the gate and data metal lines in an array of interconnected TFTs of the type described above. It is important that the gate and data lines do not short where they overlap, and by using the gate dielectric for this purpose, no separate additional fabrication steps are required to electrically isolate the lines. Thus as will be appreciated by one skilled in the art, the approach described above can also be applied to electrically isolate overlapping metal address lines.
It will be appreciated from the foregoing that Ta2O5 dielectric layer 80 is formed only over tantalum gate structure 78. This should be contrasted with the prior art, in which dielectric material is typically deposited as a continuous film over the entire substrate and intermediate structures formed thereon. Continuous films of sputtered or PECVD material typically have a large mechanical stress arising both from the intrinsic structure of the film and the different thermal expansion compared to the substrate. The stress in such a continuous film tends to deform a plastic substrate because it is a soft material with a low elastic modulus, which renders the alignment of subsequent layers of the device difficult if not impossible. The selective formation of the Ta2O5 dielectric layer 80 according to the present invention greatly reduces the intrinsic stress because less of the surface is covered with material, enabling accurate registration following the formation of the dielectric layer.
Furthermore, typical prior art high performance patterned dielectric layers are obtained by using high temperature processing (e.g., above 160° C.) and low particle count clean rooms. As previously mentioned, these high temperature processes are incompatible with materials used for flexible substrates. By substituting printing technology in place of PECVD, strictly low temperature process are employed. As an added benefit, the requirement of an ultra-clean processing environment is eased by the use of printing technology for pattern fabrication.
As previously mentioned, typical flexible substrates present a rougher surface on which materials are deposited as compared to corresponding rigid substrates such as glass. This surface roughness is essentially replicated by the various layers deposited over the substrate, and in particular by the dielectric layer. While some of this surface roughness can be reduced by forming a thick dielectric layer, as previously mentioned, strain and capacitance concerns limit the thickness of the dielectric layer. The surface roughness presented by the layer immediately below the semiconductor layer has an impact on the performance characteristics (e.g., electron/hole mobility) of the semiconductor layer. It is therefore desirable to provide a mechanism for reducing roughness of the surface upon which the semiconductor material is formed.
Accordingly, pursuant to a second embodiment of the present invention, a second dielectric layer is formed over the Ta2O5 dielectric layer of the prior embodiment. With reference to
With reference now to
In order to mitigate adverse effects of the relatively rough surface presented by the substrate and transmitted by the various layers formed thereover, according to this embodiment, a second dielectric layer 112 is next applied over Ta2O5 layer 110, as shown in
Continuous layers formed over a substrate contribute to mechanical stress within the formed structure. This stress is easily capable of shrinking or expanding a flexible substrate. Even a very small change in dimension (known as run out) affects the alignment of the structures, precluding further manufacturing steps. An advantage of the first embodiment described above is that a minimum amount of material remains on the substrate surface. This means that the stress and run-out is reduced, and in-process deformation of the substrate can be eliminated. With a similar goal in mind, according to this second embodiment, an optional step of masking and removing sections of the second dielectric layer 112 may be performed as illustrated in
In this second embodiment, the anodized dielectric (Ta2O5 layer 112) allows for patterning of the second dielectric layer 112 without causing shunts in areas of metal overlap. The removal of the excess second dielectric layer 112 then further reduces the intrinsic stress within the built-up structure, addressing the concerns about run-out. However, while the remainder of the description of this embodiment will show second dielectric layer 112 etched to form second dielectric island 116, it will be appreciated that this etching is optional, and that the balance of the description may apply equally to a device with second dielectric layer 112 unetched.
The source/drain metal layer 118 may next be deposited over the structure, as illustrated in
The structure formed so far is then etched to remove portions of the source/drain metal layer 118 exposed by masking structures 120, leaving source electrode 122 and drain electrode 124. The structure at this stage appears as shown in
The final step illustrated in this embodiment of the present invention is shown in
Another advantage of the present embodiment is that a pixel storage capacitor associate with the TFT for each pixel maybe formed for example of Ta2O5 by anodizing together with the anodizing of the TFT elements previously described. The TFT, which includes the second dielectric material, can then be manufactured with a lower parasitic capacitance for higher device performance. This allows for the formation of physically smaller storage capacitors on pixel arrays with desired higher aperture ratios.
We have fabricated polymer-based TFTs using the aforementioned process.
According to a third embodiment of the present invention, an amorphous silicon based TFT is constructed incorporating the aforementioned dual dielectric structure. The steps of a process according to this embodiment is shown in
At this point, a second dielectric layer 142 is next applied over Ta2O5 layer 140. The material comprising second dielectric layer 142 will depend upon the semiconductor material used, the process employed for deposition, the desired thickness of that layer, the electrical characteristics (e.g., capacitance) desired, etc. According to one example, the second dielectric layer 142 comprises PECVD deposited Si3N4, SiO2 or related compositions.
With reference now to
In order to alleviate the intrinsic stresses developed by the continuous coverage of second dielectric layer 142, semiconductor layer 144, and N+ layer 146, the optional step of masking and removing sections of these layers may be performed as illustrated in
In the description associated with
With reference next to
A device according to this third embodiment was built and tested.
Performance of the device according to this third embodiment was measured, and the results are shown in
While a plurality of preferred exemplary embodiments have been presented in the foregoing detailed description, it should be understood that a vast number of variations exist, such as different materials and stack combinations, and these preferred exemplary embodiments are merely representative examples, and are not intended to limit the scope, applicability or configuration of the invention in any way. In addition, the foregoing examples have focused on the TFTs and pixels, but these elements may form parts of a wide variety of devices, from LCDs, electrophoretic displays, and the like, to sensors of a wide variety. Accordingly, the foregoing detailed description provides those of ordinary skill in the art with a convenient guide for implementation of the invention, and contemplates that various changes in the functions and arrangements of the described embodiments may be made without departing from the spirit and scope of the invention defined by the claims thereto.
The U.S. Government has a fully paid-up license in this invention and the right in limited circumstances to require the patent owner to license others on reasonable terms as provided for by the terms of contract number 70NANB3H3029 awarded by the Department of Commerce, Advanced Technology Program.