Abstract:
Temperature-sensing apparatus is mounted within a wafer chuck to contact the underside surface of a wafer secured thereby. Photoluminescent material on a sensing element that is mounted in resilient contact with a wafer emits luminous flux in response to radiant-energy stimulation with a characteristic intensity that varies with time as a function of temperature. An optical channel couples radiant energy between the photoluminescent material and a remote optical analyzer that supplies pulses of radiant energy and receives the luminous flux to determine the temperature of the sensing element in contact with the wafer.

Description:
RELATED APPLICATION  
       [0001]    This application is a continuation of application Ser. No. 10/170,920 entitled “Temperature Sensing in Controlled Environment”, filed on Jun. 12, 2002 by Abid L. Khan, which claims priority from provisional application Serial No. 60/315,878, entitled “Wafer Temperature Measurement and Control in Real Time Under Processing Conditions,” filed on Aug. 29, 2001, by Abid Khan. 
     
    
     
       FIELD OF THE INVENTION  
         [0002]    This invention relates to remote temperature sensing in a controlled environment and more particularly to measuring the temperature of a semiconductor wafer within a process chamber.  
         BACKGROUND OF THE INVENTION  
         [0003]    Contemporary processing equipment for fabricating semiconductor devices commonly include reaction chambers for controlling chemical or electrochemical processing of a semiconductor substrate, or wafer. During such controlled processing, the wafer may be subjected to corrosive chemicals or gas plasmas at elevated temperatures that must be carefully monitored. In addition, the wafer is commonly held in fixed position within the reaction chamber, typically by a vacuum chuck or electrostatic chuck that maintains the rigid fixation from the underside of the wafer. Thus, sensing of the wafer temperature during processing within such a reaction chamber has limited remote-sensing techniques, for example, to optical pyrometry or contact thermometry based upon sensing temperature of the wafer at selected few locations about the wafer. Of course, it is desirable to have temperature sensing not adversely affect the temperature of the object being measured, so techniques involving negligible thermal mass are preferred. Thus, optical measurements and miniature thermocouples are favored for wafer temperature measurements. However, the presence of high-frequency electrical signals associated with gas plasmas commonly inhibit measurement of low-levels signals attributable to thermocouples used in contact thermometry, and ionized plasma gases and various surface coatings deposited on the wafer with various emission coefficients adversely affect the accuracy of optical pyrometry techniques.  
         SUMMARY OF THE INVENTION  
         [0004]    In accordance with one embodiment of the present invention, optical techniques and thermal contact techniques combine to accurately sense the temperature of the underside of a wafer. Specifically, one or more temperature sensors are disposed at locations within the area of a wafer chuck to make direct thermally-conductive contact with the underside of the wafer, and to provide optical signal indications of temperature for remotely sensing and monitoring the wafer to provide accurate indication of its processing temperature. In this configuration, the temperature-sensing technique of the present invention is unaffected by high-energy radio frequency signals associated with gas-plasma processing of the wafer, or by ambient conditions of reduced pressure and corrosive atmosphere. 
       
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0005]    [0005]FIG. 1 is a partial sectional view of a thermal sensor in accordance with one embodiment of the present invention;  
         [0006]    [0006]FIG. 2 is a sectional view of a mounting spring in the embodiment of FIG. 1; and  
         [0007]    [0007]FIG. 3 is a graph illustrating the non-linear force versus displacement characteristics of the mounting spring of FIG. 2. 
     
    
     DETAILED DESCRIPTION OF THE INVENTION  
       [0008]    Referring now to FIG. 1, there is shown a partial sectional view of a wafer chuck  7 , with a temperature-sensing structure  11  according to one embodiment of the present invention built into the chuck to contact the underside of a wafer supported on the chuck  7 . Specifically, an electrostatic wafer chuck  7  may include an electrode  13  having a generally round planar surface  15  that is disposed to support a wafer of slightly greater diameter, and that includes a layer  17  of dielectric material such as aluminum oxide, or the like, interposed between the electrode  13  and a wafer (not shown) positioned on the upper surface of the dielectric layer  17 . One or more lower layers  19  of insulating material are interposed between the electrode  13  and a base  21 . The electrode  13  and a similar electrode structure at a spaced location about the base  21 , insulated from electrode  13  and having an upper surface coplanar with the surface  15  of electrode  13  thus form an electrostatic chuck in known manner. Bipolar electrical signals applied to such electrodes thus establish an electrostatic field therebetween upon application of suitable voltage and polarities that exerts a substantial force on a wafer in a direction toward the surface  15  in known manner to retain the wafer firmly secured to the planar upper surface of the chuck.  
         [0009]    In accordance with the illustrated embodiment of the present invention, a tiny, thermally-conductive sensing element  23  is mounted within a recess  25  within the surface  15  of electrode  13  to protrude slightly above the planar surface  15  for assured thermally-conductive contact with the underside surface of a wafer positioned on the surface  15 . Resilient mounting of the sensing element  23  is provided by a circular or disc-like spring  26 , as illustrated in sectional view in FIG. 2, which surrounds the sensing element  23 . Preferably, the spring  26  provides progressively greater spring force with deflection or displacement, as illustrated in FIG. 3, to increase resilient bias of the sensing element  23  against the underside of a wafer as such wafer is drawn into engagement with the surface  15  of the wafer chuck. The spring may be formed of metallic or polymer material with cross-section that increases with radius from the central aperture  28 , as shown in FIG. 2, in which the thermal element  23  is supported. The sensing element  23  is formed of highly thermally-conductive material such as aluminum or titanium or ceramic material, and may be similarly coated with dielectric material on the exposed surface, as in layer  15  or  19 . Additionally, an annulus  27  is disposed within the recess above the disc spring  26  to surround (but not touch) the sensing element  23  and thereby serve as a shield or barrier to the migration into the structure of gases or chemicals that are present within the operating environment. The disc spring  26  that supports the sensing element  23  is, in turn, coaxially supported about its periphery by a cup-shaped element  31  that is coaxially positioned within the recess  25 . The axial position within the recess  25  of the cup-shaped element  31  and of the associated disc spring  26  and sensing element  23  is determined by rotational adjustment of the element  31  within the threaded attachment to the base collar  33 . The element  31  and base collar  33  and disc spring  26  and shield  27  may all be formed of low thermally-conductive materials such as polymers or ceramics to inhibit heat transfer from the wafer via contacting sensing element  23 .  
         [0010]    In accordance with the present invention, the temperature of the sensing element  23  is determined by an actinically-sensitive a photoluminescent material which fluoresces with a decaying intensity as a function of temperature following pulsed light stimulation of the material. The underside of the sensing element  23  is configured in an inverted cup shape to facilitate deposition thereon of such material, as well as to promote focusing or intensifying the luminescent flux about the end  36  of an optical fiber  38 . Such photoluminescent material, designated as Alpha Phosphor Dots, or AccuDot-6.4, is commercially available, for example, from Luxtron Corp. of Santa Clara, Calif.  
         [0011]    In accordance with the illustrated embodiment of the present invention, the optical fiber  38  is embedded and sealed within the base  21  with the end  36  of the fiber disposed away from, and in axial alignment with, the underside of the sensing element  23 . In this way, light flux can be supplied to and received from the sensing element  23  along the optical channel of the fiber  38 . Thus, a stimulating light pulse may be supplied by optical analyser  39  along the optical channel including fiber  38  and optical fiber cable  41 , and resultant fluorescent light flux may be transmitted from the underside of sensing element  23  along the optical channel back to the optical analyzer  39 . An optical coupling is formed at the interface of an opposite end  43  of the fiber  38  with the mating end  45  of the optical fiber cable  41  to facilitate convenient detachment of the cable  41  and analyzer  39  from the base  21  of the wafer chuck. A ferrule  47  surrounding the mating end  45  of the optical cable is threaded  49  for mating threaded attachment within recess  51  in the base  21 .  
         [0012]    In operation, a semiconductor wafer of silicon or gallium arsenide, or the like, is positioned on the upper surface  15  of the wafer chuck over one or more sensor elements  23  that contact the underside of the wafer (not shown). As the wafer is pulled down into engagement with the surface  15  of the chuck by electrostatic force (or alternatively by a vacuum-based chuck where feasible within an operating environment), the disc spring  26  supporting the sensing element  23  deflects and resiliently urges the sensing element  23  into good thermal contact with the underside of the wafer. The fluorescent material of the type previously described that is disposed on the underside of the sensing element  23  is illuminated by a light pulse supplied thereto along the optical channel  38 ,  41  from the optical analyzer  39 . Such fluorescent material, at substantially the same temperature as the sensing element  23  which is at substantially the wafer temperature, exhibits a characteristic luminous output with an intensity that decays with time at a rate determined in known manner by the temperature. Thus, periodic excitation of the fluorescent material with light pulses or other radiant energy from the analyzer  39  produces luminescent responses that can be detected via the optical channel  38 ,  41  and analyzed in known manner to yield accurate indication of temperature of a wafer in contact with the sensing element  23 . In a preferred embodiment of the invention, the wafer chuck  7  operates on electrostatic attraction in accordance with Coulomb&#39;s law in known manner, and promotes convenient repeatable operation even within a vacuum environment and in applications requiring gas under pressure supplied to the underside of the wafer (e.g., for cooling). The disc spring  26  thus produces low resilient force, upon initial displacements to facilitate pulling the wafer down against the protruding sensing element  23  and into contact with the surface  15  of the chuck, and produces non-linearly increased resilient force to assure good thermal contact of the sensing element  23  against the wafer while firmly secured against the upper surface  15  of the chuck.  
         [0013]    Therefore, sensing wafer temperature within a controlled environment in accordance with the present invention relies upon components of low thermal mass and low thermal resistance to assure prompt and accurate temperature measurement of a wafer of semiconductor or other material. In addition, sensing wafer temperature in accordance with the present invention assures low latency of measurement response without significantly adversely affecting the temperature of a wafer being measured. Sensing temperature in accordance with the present invention is immune from the effects of high frequency energy and luminous plasmas commonly present in semiconductor processing chambers, and produces prompt and repeatably accurate indications of the wafer temperature within the processing environment.