Patent Document

FIELD OF THE INVENTION  
       [0001]     The present invention relates to equipment used in the manufacture of semiconductor wafers in general, and more specifically, to systems and methods for dispensing photo resist.  
       BACKGROUND OF THE INVENTION  
       [0002]     Commonly, in semiconductor manufacturing, photo resist coaters dispense a thin layer of liquid photo resist on to a spinning silicon wafer as a step in the photolithographic process. The chemical properties of the photo resist change with exposure to light and this property is utilized to create a mask during various steps in the sequence of building circuit patterns on the semiconductor wafer.  
         [0003]     The photo resist coater will typically include a dispensing nozzle or tube portion that receives photo resist from a flow line and dispenses the photo resist through a nozzle tip on to the wafer at a controlled rate. The flow line carrying the photo resist to the nozzle is connected to a reservoir containing photo resist. A pumping system transfers the photo resist through the flow line to the nozzle as needed. Coaters often include multiple photo resist dispensing nozzles which can each be connected to different reservoirs through separate flow lines. Such configurations make different types of photo resist or other chemicals readily available during the wafer manufacturing process.  
         [0004]     Typically, the photo resist coater includes a dispense system controller or main controller which receives the specific details of the photo resist dispensing operations and carries out the operations of the photo resist coater tool. A secondary controller, called the pump controller, is typically configured to control the pumping system in communication with the main controller. During a production photo resist dispensing operation, the nozzle is typically positioned over a spinning wafer in a production position. For example, the wafer may be positioned on a rotatable plate, sometimes referred to as a coater plate. As photo resist is applied, the nozzle may oscillate back and forth from a central position above the wafer to a position near the edge to uniformly coat the wafer.  
         [0005]     After a photo resist dispensing operation, some photo resist will typically remain in the tip of the nozzle and be exposed to air causing it to thicken and dry. If left unattended, this residual photo resist thickens and creates clumps in the tip of the nozzle. Such effects are referred to herein as coagulation. During a subsequent photo resist dispense operation, such coagulation can result in the formation of debris on the semiconductor wafer, creating defects which result in electrical failures of the semiconductor circuits.  
         [0006]     Other types of chemicals used in the photo coat process include solvents whose function is to remove a thicker-layer of photo resist, sometimes referred to as an edge-bead, which builds up at the edge of a wafer during the photo coating process. Solvents are often paired with specific types of photo resist. One such solvent, Propylene Glycol Monomethyl Ether Acetate, or PGMEA, is typically paired with the Shipley AR3™ type photo resist. During edge bead removal, the PGMEA solvent is transferred from a reservoir and through a separate flow line and nozzle to the very edge of the wafer or to the underside of the wafer near the edge to remove unwanted photo resist. Other solvents used in the photo coat process, which may be used with other types of photo resist, include N-butyl Acetate, Acetone, Cyclohexnone, Ethyl Lactate, N-Methylpyrrolidone (NMP) (1-methyl, 2-Pyrrolidone), Tetrahydrofuran (THF), Propylene Glycol Monomethyl Ether (PGME), and Methyl amyl keytone (MAK.)  
         [0007]     When the photo resist dispense nozzle has completed a production photo resist dispensing operation, the nozzle is rotated to an idle position. The nozzle stays in the idle position, filled with photo resist, until the next wafer lot is available. To mitigate coagulation while in this idle position, the nozzle is situated above a solvent cup containing solvent, such as PGMEA. The nozzle does not come into contact with liquid solvent in the cup, but rather, receives solvent vapors from the cup. Interaction of solvent vapors with the photo resist delays photo resist coagulation in the tip of the nozzle. This reduces, but does not eliminate, clogging of the nozzle.  
         [0008]     To further reduce photo resist coagulation in the tip of the dispensing nozzle, a “dummy dispense” operation may be performed. That is, while the dispensing nozzle is in the idle position, the photo resist pump is periodically activated to apply fresh photo resist to the nozzle and the nozzle tip. During a dummy dispense operation, photo resist is pumped though the nozzle and into the solvent cup. The dummy dispense procedure may be repeated periodically while the nozzle is in the idle position. A drain in the solvent cup prevents overfilling of the cup and permits flushing of photo resist with solvent and replenishing the cup with the solvent.  
         [0009]     It is now recognized that a more economical and effective procedure may be had to address problems relating to coagulation of photo resist in the nozzle tip.  
       SUMMARY OF THE INVENTION  
       [0010]     The afore-described procedures are, at best, wasteful resulting in substantial loss of expensive chemicals. The present invention provides a solution for avoiding coagulation of photo resist in manufacturing equipment.  
         [0011]     In one form of the invention, a method is provided for manufacturing microelectronic devices. According to one embodiment, the method includes providing a photo resist coater tool having a coater plate and a nozzle connected to a fluid flow line. The nozzle is positionable over the coater plate. A valve assembly is positioned in the flow line to control flow between at least two fluid inputs and the nozzle. A wafer is positioned on the coater plate and the valve assembly is operated to dispense photo resist from the first of the fluid inputs and through the nozzle onto the wafer. The valve assembly stops the flow of photo resist and the nozzle is positioned over a solvent drain. The valve assembly then sends a solvent from a second of the fluid inputs through the flow line and nozzle to reduce coagulation of the photo resist in or about the nozzle.  
         [0012]     In another form of the invention, a system is provided for dispensing photo resist which includes a nozzle configured to alternately receive photo resist for delivery on to a plurality of wafers or liquid solvent to prevent coagulation of photo resist in the nozzle when the nozzle is idle. In an example embodiment, at least two flow lines provide fluid communication to a valve positioned between the flow lines and the nozzle. One of the flow lines receives fluid from a photo resist source and the second flow line receives fluid from a solvent source. The valve is configured to select the movement of fluid from one or another of the flow lines and thereby enables movement of solvent through the nozzle to flush photo resist from the nozzle.  
     
    
     DISCRIPTION OF THE FIGURES  
       [0013]      FIG. 1  is a side elevation view in schematic form of a photo resist dispensing system according to the invention;  
         [0014]      FIG. 2  is a partial schematic view from above of the photo resist dispensing system of  FIG. 1 ; and  
         [0015]      FIG. 3  is an exemplary flow control diagram for use in conjunction with the invention. 
     
    
     DETAILED DESCRIPTION OF THE INVENTION  
       [0016]     With reference to the figures generally, exemplary embodiments of a method and a photo resist coater tool system  1  for photo resist dispensing according to the invention are now described. As shown in  FIG. 1 , the photo resist coater tool system  1  includes a movable dispensing nozzle  2  having a nozzle tip  4  for dispensing fluid. Movement of the dispensing nozzle  2  is effected by a nozzle positioning mechanism  3 . The system may be configured to have multiple nozzles such as nozzle  2 . For simplicity, only one such nozzle  2  is shown while it is to be understood that the principles of this invention may be applied to multiple nozzles in photo resist coater tools.  
         [0017]     A switching mechanism, such as a valve  20 , is positioned to selectively control flow of fluid through dispensing nozzle  2  to the nozzle tip  4 . The valve  20  is conventional and may be of the electronic, electromagnetic, pneumatic or hydraulic type and is shown as a three-way valve. A first input port  21  of the valve  20  is connected to a photo resist flow line  22  which can send photo resist  29  to the dispensing nozzle  2  from a photo resist source  24 . An in-line photo resist pump  26  facilitates the transfer of photo resist. A second input port  23  to the valve  20  is connected to a solvent flow line  18  along which solvent  19  is sent to the dispensing nozzle  2  from a solvent source  14  via an in-line solvent pump  16 . An output port  27  of the valve  20  is connected to the dispensing nozzle  2  to selectively dispense photo resist  29  or solvent  19  through the nozzle tip  4  depending on which of the input ports  21 ,  23  the valve  20  is configured to receive fluid from. A main controller  6  is configured to effect the movement of the dispensing nozzle  2  through communication with the nozzle positioning mechanism  3  and to control the input of fluid through one of the input ports  21 ,  23  of the valve  20 . The main controller  6  also controls the activation of the solvent pump  16  and the photo resist pump  24  through communication with the pump controller  12 . A valve control line  33  indicates communication from the main controller  6  to the valve  20 , while a positioning control line  34  indicates communication from the main controller  6  to the nozzle positioning mechanism  3 . A pump control line  35  indicates communication from the main controller  6  to the pump controller  12 . Photo resist pump control line  36  and solvent pump control line  37  indicate communication between photo resist pump  26  and the solvent pump  16  to the pump controller  12 .  
         [0018]     Referring next to the schematic view of  FIG. 2 , alternate positions of the dispensing nozzle  2  are illustrated. The dispensing nozzle  2  will typically be in a production position  8  (illustrated with phantom lines) for dispensing photo resist  29  on to a semiconductor wafer  25  positioned on a coater plate  28 . When the production photo resist dispensing process is complete, the dispensing nozzle  2  is rotated to an idle position  10  over a solvent drain  30 . Dispensing nozzle rotation is effected about axis  38  by the nozzle positioning mechanism  3  as illustrated by the arrows numbered  40  and  42 .  
         [0019]     Again, referring to  FIG. 1 , when a production photo resist dispensing step is about to occur, the main controller  6  directs the nozzle positioning mechanism  3  to position the dispensing nozzle  2  over a semiconductor wafer  25  positioned on coater plate  28 . The main controller  6  then actuates the valve  20  to receive input fluid from the photo resist flow line  22  and, via the pump controller  12 , activates the photo resist pump  26  to send photo resist  29  from the photo resist source  24  through the photo resist flow line  22  through valve  20  to the nozzle tip  4  to be dispensed on to the wafer  25 . When the dispensing nozzle  2  has completed a production photo resist dispensing operation, the main controller  6  signals the pump controller  12  to stop sending photo resist  29  and close the input  21  to valve  20 . The main controller then activates the nozzle positioning mechanism  3  to rotate the dispensing nozzle  2  to the idle position  10  over a solvent drain  30 . Because the invention is based on a different principle than the interaction of solvent vapors with photo resist, the solvent drain  30  does not require that a solvent feed line be connected to fill the solvent drain  30  as present in a conventional the solvent cup, although the invention may incorporate this feature to provide solvent vapors about the dispensing nozzle  2 .  
         [0020]     In the idle position  10 , the nozzle tip  4  typically retains some photo resist  29  thereabout, as residual from the previous production dispensing operation. The dispensing nozzle  2  may remain in the idle position  10  with photo resist  29  in the dispensing nozzle  2  and nozzle tip  4  in preparation for a subsequent production photo resist dispense operation. After a predetermined amount of time in the idle position  10 , with no further wafers in queue for the production photo resist dispense operation, the main controller  6  actuates the valve  20  to open the input port  23  to the solvent flow line  18 . The main controller  6  also signals the pump controller  12  to activate the solvent pump  16  to send solvent  19  from a solvent source  14  through the solvent flow line  18  through the valve  20  to the nozzle tip  4  to flush residual photo resist  29  through the nozzle tip  4  and fill the dispensing nozzle  2  and nozzle tip  4  with solvent.  
         [0021]     Solvent  19  remains in the dispensing nozzle  2  until the next production photo resist dispense operation is initiated, thus eliminating the need for a dummy dispense operation. When a subsequent group of wafers, referred to herein as a next production lot, become available for a production photo dispense operation, the main controller  6  signals the photo resist pump to fill the dispensing nozzle  2  with photo resist  29 , thereby replacing the solvent  19  with photo resist  29 .  
         [0022]      FIG. 3 , a flow control diagram, provides a more detailed sequence of steps applicable to the embodiment of the invention shown in  FIGS. 1 and 2 . The sequence, beginning at step  80  assumes that the photo resist coater tool system  1  has the dispensing nozzle  2  in the idle position  10  with the valve  20  open to the photo resist flow line  22 . The sequence of steps will typically be initiated and controlled by signals from the main controller  6 , with secondary instructions sent to the pumps from the pump controller  12 .  
         [0023]     If a production lot has entered the queue for a production photo resist dispense, the system  1  begins a production dispense operation in which the main controller  6  sends a signal to move the dispensing nozzle  2  to the production position  8  (step  85 ) and a wafer is loaded onto the coater plate  28  (step  90 ). The main controller  6  then sends a signal to the pump controller  12  to actuate the photo resist pump  26  to dispense photo resist  29  onto the wafer  25 . The photo resist pump  26  is subsequently shut off when the dispense operation for the wafer is complete (step  95 ).  
         [0024]     If other wafers in the production lot remain in queue, the system  1  sequentially loads the remaining wafers on to the coater plate  28  (step  90 ) and continues with the production dispense operation (step  95 ). Otherwise, the dispensing nozzle  2  moves to the idle position  10  (step  110 ) and a time period is counted by the main controller  6  (step  115 ). If it is determined at step  80 , that there are no further wafers in queue, the dispensing nozzle  2  remains in the idle position  10  and the time period is counted (step  115 ). A reasonable time period for the photo resist coater tool to remain in the idle position  10  before beginning the solvent flush is 30 minutes, but the period may range from less than 10 minutes to over 60 minutes. The length of the time period may depend on factors, such as the type of photo resist and solvent, viscosity of the photo resist, and the configuration of the dispensing nozzle  2  and nozzle tip, as well as, environmental conditions such as room temperature and humidity.  
         [0025]     If wafers arrive in queue before the time period lapses (step  120 ), the dispensing nozzle  2  is moved into the production position  8  (step  85 ) to begin another production dispense operation. If no subsequent lot enters the queue before the time period ends (step  120 ), the main controller  6  sends a signal to open the valve  20  to the solvent flow line  18  (step  125 ) and the pump controller  12  actuates the solvent pump  14  to send solvent  19  to the dispensing nozzle  2  and nozzle tip  4  (step  130 ) to clear them of photo resist  29 .  
         [0026]     After flushing the dispensing nozzle  2  and nozzle tip  4  with solvent, the pump controller  12  shuts off the solvent pump  14  (step  135 ). The photo resist coater tool  1  remains in this state with the dispensing nozzle  2  in idle position  10  until a subsequent lot arrives in queue for the production dispense operation. When the subsequent lot arrives, the main controller  6  opens the valve  20  to the photo resist flow line  22  (step  140 ) and sends a signal to the pump controller  12  to actuate the photo resist pump  24  to fill the dispensing nozzle  2  and nozzle tip  4  with photo resist  29  (step  145 ). After the dispensing nozzle  2  and nozzle tip  4  are filled with photo resist, the pump controller  12  sends a signal to disable the photo resist pump  24  (step  150 ). The dispensing nozzle  2  then moves to a production position  8  to perform for another production dispense operation on the next wafer in queue (step  85 ).  
         [0027]     It is to be understood that the above description of the invention is intended to be illustrative and not restrictive. Many additions and modifications will be apparent to those of skill in the art. The invention may be practiced in a number of industries pertaining to electronics manufacturing where a photo resist coating process is used. Accordingly, the scope of the invention is only limited by the claims which follow.

Technology Category: 3