Coating processes – Measuring – testing – or indicating – Thickness or uniformity of thickness determined
Reexamination Certificate
2001-04-20
2003-05-06
Bueker, Richard (Department: 1762)
Coating processes
Measuring, testing, or indicating
Thickness or uniformity of thickness determined
C427S010000, C427S066000, C427S532000, C427S534000, C427S553000, C427S554000, C427S255600, C118S664000, C134S001000, C134S002000, C134S018000, C134S019000
Reexamination Certificate
active
06558735
ABSTRACT:
CROSS REFERENCE TO RELATED APPLICATIONS
Reference is made to commonly assigned U.S. patent application Ser. No. 09/839,885 filed concurrently herewith entitled “Controlling the Thickness of an Organic Layer in an Organic Light-Emitting Device” by Steven A. Van Slyke et al., the disclosure of which is incorporated herein by reference.
FIELD OF THE INVENTION
The present invention relates generally to monitoring and controlling formation of organic layers by physical vapor deposition in making organic light-emitting devices.
BACKGROUND OF THE INVENTION
An organic light-emitting device, also referred to as an organic electroluminescent device, can be constructed by sandwiching two or more organic layers between first and second electrodes.
In a passive matrix organic light-emitting device of conventional construction, a plurality of laterally spaced light-transmissive anodes, for example indium-tin-oxide (ITO) anodes are formed as first electrodes on a light-transmissive substrate such as, for example, a glass substrate. Two or more organic layers are then formed successively by vapor deposition of respective organic materials from respective sources, within a chamber held at reduced pressure, typically less than 10
−3
Torr. A plurality of laterally spaced cathodes are deposited as second electrodes over an uppermost one of the organic layers. The cathodes are oriented at an angle, typically at a right angle, with respect to the anodes.
Such conventional passive matrix organic light-emitting devices are operated by applying an electrical potential (also referred to as a drive voltage) between appropriate columns (anodes) and, sequentially, each row (cathode). When a cathode is biased negatively with respect to an anode, light is emitted from a pixel defined by an overlap area of the cathode and the anode, and emitted light reaches an observer through the anode and the substrate.
In an active matrix organic light-emitting device, an array of anodes are provided as first electrodes by thin-film transistors (TFTs) which are connected to a respective light-transmissive portion. Two or more organic layers are formed successively by vapor deposition in a manner substantially equivalent to the construction of the aforementioned passive matrix device. A common cathode is deposited as a second electrode over an uppermost one of the organic layers. The construction and function of an active matrix organic light-emitting device is described in U.S. Pat. No. 5,550,066, the disclosure of which is herein incorporated by reference.
Organic materials, thicknesses of vapor-deposited organic layers, and layer configurations, useful in constructing an organic light-emitting device, are described, for example, in U.S. Pat. Nos. 4,356,429; 4,539,507; 4,720,432; and 4,769,292, the disclosures of which are herein incorporated by reference.
In order to provide an organic light-emitting device which is substantially uniform and of precise thickness, the formation of organic layers of the device has to be monitored or controlled. Such control of vapor deposition of organic layers by sublimation or evaporation of organic material from a source is typically achieved by positioning a monitor device within the same vapor deposition zone in which the substrate or structure is to be coated with the organic layer. Thus, the monitor device receives an organic layer at the same time as the organic layer is being formed on the substrate or structure. The monitor device, in turn, provides an electrical signal which is responsive to a rate at which the organic layer is being formed on the monitor device and, therefore, related to a rate at which the organic layer is being formed on the substrate or structure which will provide the organic light-emitting device. The electrical signal of the monitor device is processed and/or amplified, and is used to control the rate of vapor deposition and the thickness of the organic layer being formed on the device substrate or structure by adjusting a vapor source temperature control element, such as, for example, a source heater.
Well known monitor devices are so-called crystal mass-sensor devices in which the monitor is a quartz crystal having two opposing electrodes. The crystal is part of an oscillator circuit provided in a deposition rate monitor. Within an acceptable range, a frequency of oscillation of the oscillator circuit is approximately inversely proportional to a mass-loading on a surface of the crystal occasioned by a layer or by multiple layers of material deposited on the crystal. When the acceptable range of mass-loading of the crystal is exceeded, for example by build-up of an excess number of deposited layers, the oscillator circuit can no longer function reliably, necessitating replacement of the “overloaded” crystal with a new crystal mass-sensor. Such replacement, in turn, requires discontinuation of the vapor deposition process.
In addition, when certain types of organic layers are deposited onto crystal mass-sensor devices there can be a tendency for the layers to start cracking and flaking from the mass-sensor surface after coating thickness build-up on the order of 500-2,000 nanometer (nm). This can cause the crystal mass-sensor to become inaccurate in its coating rate measurement capability at thicknesses well below the aforementioned mass-loading limit.
In development efforts, several organic light-emitting devices can typically be prepared before a crystal mass-sensor must be replaced due to excessive mass-loading or cracking and flacking of a deposited film. This does not present a problem in such efforts, since other considerations usually require disruption of vapor deposition by opening the deposition chamber for manual replacement of substrates or structures, replenishment of organic material in relatively small vapor sources, and the like.
However, in a manufacturing environment, designed for repeatedly making a relatively large number of organic light-emitting devices, replacement of “overloaded” crystal mass-sensors or cracked and flaking organic coatings on crystal mass-sensors would constitute a serious limitation because a manufacturing system is configured in all aspects to provide the capacity of producing all organic layers on numerous device structures and, indeed, to produce fully encapsulated organic light-emitting devices.
SUMMARY OF THE INVENTION
It is, therefore, an object of the present invention to form an organic layer by providing a reusable sensor for controlling the thickness of such layer. This object is achieved in a method for depositing an evaporated or sublimed organic layer onto a structure which will form part of an organic light-emitting device, comprising the steps of:
a) depositing at a deposition zone organic material forming a layer of the organic light-emitting device;
b) providing a movable sensor which, when moved into the deposition zone and is being coated during the depositing step, provides a signal representing the thickness of the organic material forming the layer;
c) controlling the deposition of the organic material in response to the signal to control a deposition rate and thickness of the organic layer formed on the structure;
d) moving the movable sensor from the deposition zone to a cleaning position; and
e) removing organic material from the movable sensor to permit reuse of the movable sensor.
It is an advantage of the present invention that crystal mass-sensors which control the thickness of one or more organic layers in a light-emitting device can be cleaned and reused thereby providing a more efficient manufacturing process.
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patent
Hrycin Anna L.
Marcus Michael A.
Van Slyke Steven A.
Bueker Richard
Owens Raymond L.
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