Abstract:
Methods of forming integrated circuit devices include depositing an electrically insulating layer onto an integrated circuit substrate having integrated circuit structures thereon. This deposition step results in the formation of an electrically insulating layer having an undulating surface profile, which includes at least one peak and at least on valley adjacent to the at least one peak. A non-uniform thickening step is then performed. This non-uniform thickening step includes thickening a portion of the electrically insulating layer by redepositing portions of the electrically insulating layer from the least one peak to the at least one valley. This redeposition occurs using a sputter deposition technique that utilizes the electrically insulating layer as a sputter target.

Description:
FIELD OF THE INVENTION 
       [0001]    The present invention relates to integrated circuit fabrication methods and, more particularly, to methods of fabricating field effect transistors in integrated circuit substrates. 
       BACKGROUND OF THE INVENTION 
       [0002]    Conventional techniques to increase the levels of device integration on integrated circuit substrates can often lead to reductions in device yield and device reliability. Some of these reductions in device yield may be caused by the formation of voids or gaps within electrically insulating layers and also within electrical interconnects that may extend through one or more electrically insulating layers. In particular, the conformal deposition of relatively thick electrically insulating layers on closely-spaced integrated circuit structures having relatively narrow aspect ratios may lead to the formation of voids in the spaces between the integrated circuit structures. These voids can result in the formation of electrical shorts between electrical interconnects and other integrated circuit structures formed on the substrate. One attempt to address this problem includes the use of thinner insulating layers, however, the use of thinner insulating layers may lead to increases in parasitic capacitive coupling between adjacent integrated circuit structures, which can lower device operating speeds. Etch-back and other planarization techniques have also been developed to make the surface profiles of deposited insulating layers more uniform and limit the range of peaks and valleys in the surface profile. Unfortunately, such planarization techniques may not be effective when the layers to be planarized are located very close to a primary surface of an integrated circuit substrate. 
       SUMMARY OF THE INVENTION 
       [0003]    Embodiments of the present invention include methods of forming integrated circuit structures and devices using insulator deposition and insulator gap filling techniques, to thereby define insulating layers having more uniform surface profiles. According to some of these embodiments, methods to form integrated circuit devices include depositing an electrically insulating layer onto an integrated circuit substrate having integrated circuit structures thereon. This deposition step results in the formation of an electrically insulating layer having an undulating surface profile, which includes at least one peak and at least on valley adjacent to the at least one peak. A non-uniform thickening step is then performed. This non-uniform thickening step includes thickening a portion of the electrically insulating layer by redepositing portions of the electrically insulating layer from the least one peak to the at least one valley. This redeposition occurs using a sputter deposition technique that utilizes the electrically insulating layer as a sputter target. 
         [0004]    According to some of these embodiments, the depositing step includes depositing the electrically insulating layer onto the integrated circuit substrate using a plasma deposition process. In particular, the depositing step may include depositing a silicon nitride layer using a first plasma that receives an inert gas (e.g., argon gas), a nitrogen containing gas and a silicon containing gas (e.g., SiH 4 ) as source gases. In addition, the thickening step may include redepositing portions of the silicon nitride layer using a second plasma that receives the inert gas and the nitrogen containing gas, but not the silicon containing gas, as source gases. According to aspects of these embodiments, the plasma bias power used to establish the second plasma is greater than about two times a plasma bias power used to establish the first plasma. The thickening step may also be followed by a step of depositing additional silicon nitride onto the silicon nitride layer using a third plasma equivalent to the first plasma. Another thickening step may then be performed, which follows the step of depositing the additional silicon nitride. 
         [0005]    Additional embodiments of the present invention include methods of forming field effect transistors by forming first and second insulated gate electrodes at side-by-side locations on an integrated circuit substrate and then forming a silicon nitride layer on the first and second insulated gate electrodes and in a gap between the first and second insulated gate electrodes. This step of forming the silicon nitride layer may include depositing the silicon nitride layer using a chemical vapor deposition process (e.g., PECVD) and/or a plasma deposition process. The silicon nitride layer is then selectively thickened. In particular, a portion of the silicon nitride layer located in the gap is then thickened by transferring portions of the silicon nitride layer extending opposite the first and second insulated gate electrodes into the gap using a sputtering process. 
         [0006]    Still further embodiments of the present invention include depositing an electrically insulating layer on an integrated circuit substrate using a first deposition technique and then recessing a first portion of the deposited electrically insulating layer. This recessing step, which may be performed using a plasma redeposition technique having different process conditions relative to the first deposition technique, includes bombarding the first portion of the electrically insulating layer with a sufficient quantity of plasma ions to thereby physically remove electrically insulating material from the first portion of the electrically insulating layer and redeposit the removed electrically insulating material onto a second portion of the electrically insulating layer. 
         [0007]    Additional methods of forming integrated circuit devices include depositing an electrically insulating layer having an undulating surface profile with at least one peak and at least on valley, using a first plasma established in a plasma deposition chamber. The composition of the first plasma is then adjusted by lowering a concentration of at least one source gas supplied thereto (e.g., SiH 4 ), to thereby cause recession of the at least one peak and redepositing of material removed from the at least one peak into the at least one valley. This adjusting step may also be followed by a step of readjusting the composition of the first plasma by increasing the concentration of the at least one source gas supplied thereto, to thereby cause deposition of additional electrically insulating material on the at least one peak. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0008]      FIGS. 1A-1B  are cross-sectional views of intermediate structures that illustrated methods of forming integrated circuit devices according to embodiments of the invention. 
           [0009]      FIG. 2A  is a flow diagram of process steps that illustrates methods of forming integrated circuit devices according to embodiments of the present invention. 
           [0010]      FIG. 2B  is a flow diagram of process steps that illustrates methods of forming integrated circuit devices according to additional embodiments of the present invention. 
       
    
    
     DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS 
       [0011]    The present invention will now be described more fully hereinafter with reference to the accompanying drawings, in which preferred embodiments of the invention are shown. This invention may, however, be embodied in different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. In the drawings, the thickness of layers and regions are exaggerated for clarity. It will also be understood that when a layer is referred to as being “on” another layer or substrate, it can be directly on the other layer or substrate, or intervening layers may also be present. Like numbers refer to like elements throughout. 
         [0012]      FIGS. 1A-1B  illustrate methods of forming integrated circuit devices according to first embodiments of the present invention. As illustrated by  FIG. 1A , a plurality of integrated circuit structures are formed at side-by-side locations on an integrated circuit substrate  10 . These structures may include, but are not limited to, structures having relatively narrow aspect ratios (i.e., narrow width-to-height ratios), such as passive electronic devices, interconnects, insulated gate electrodes, etc. These insulated gate electrodes are illustrated as including a gate insulating region  12 , an electrically conductive gate electrode  14  and a gate capping layer  16 . Electrically insulating sidewall spacers  18  are also provided on sidewalls of the gate electrodes  14 , as illustrated. 
         [0013]      FIG. 1A  also illustrates the formation of an electrically insulating layer  20  as a conformal layer that extends on the integrated circuit structures and in the gaps or spacing between the integrated circuit structures. As illustrated, the electrically insulating layer  20  may have an undulating surface profile with at least one peak (e.g., on top of each gate electrode) and at least one valley (e.g., in the spaces and gaps between the gate electrodes). According to some embodiments of the invention, the electrically insulating layer  20  may be a silicon nitride layer. This silicon nitride layer may be formed using a plasma deposition process (e.g., HDP (high density plasma) process). This plasma deposition process may include establishing a first plasma in a plasma processing chamber, using an inert gas (e.g., argon gas), a nitrogen containing gas (e.g., N 2  gas) and a silicon containing gas (e.g., SiH 4 ) as source gases. The first plasma may be established as a relatively low power (e.g., 400 W bias power), high frequency (HF) plasma and the volumetric flow rate of silane (i.e., SiH 4 ) as a source gas may be about 90 sccm. Alternatively, the silicon nitride layer may be formed in a deposition chamber using a chemical vapor deposition technique (e.g., PECVD). 
         [0014]    Referring now to  FIG. 1B , a step is then performed to selectively thicken portions of the electrically insulating layer  20  by redepositing portions of the electrically insulating layer  20 . This redepositing includes transferring portions of the electrically insulating layer  20  from the peaks to the valleys, to thereby define redeposited insulating regions  22 . This transfer of insulating material from the peaks to the valleys may occur in the plasma processing chamber, with the peaks of the electrically insulating layer  20  acting essentially as sputter targets for charged ions (e.g., nitrogen ions) generated within the plasma processing chamber. These charged ions impact and dislodge the insulating material from the peaks in the electrically insulating layer  20  and at least some of this dislodged material redeposit in the valleys of the electrically insulating layer  20  to thereby define redeposited insulating regions  22 . The electrically insulating layer  20  and the redeposited insulating regions  22  may then be exposed to a sufficient dose of UV radiation to thereby improve a tensile strength of the insulating regions  22 . 
         [0015]    In particular, a second plasma may be established in the plasma processing chamber using an inert gas (e.g., argon gas) and a nitrogen containing gas (e.g., N 2  gas), but not an appreciable amount of a silicon containing gas, as source gases. The second plasma may be established as a relatively high power (e.g., 1200 W bias power), high frequency (HF) plasma and the volumetric flow rate of the silicon containing source gas may be set to a low level, including about 0 sccm. The high level of the plasma bias power associated with the second plasma should be at least two times greater than the plasma bias power associated with the first plasma. 
         [0016]      FIG. 2A  is a flow diagram of process steps that illustrates additional methods  30  of forming integrated circuit devices, according to embodiments of the present invention. As illustrated by Block  32 , a plurality of integrated circuit structures (e.g., passive and/or active structures) are formed on a surface of an integrated circuit substrate. At least one electrically insulating layer is then deposited on the integrated circuit substrate. This deposition step-may be performed using a chemical vapor deposition technique or a plasma deposition technique, for example. Other deposition techniques may also be used. This at least one electrically insulating layer extends on the integrated circuit structures and in the gaps (e.g., spaces) extending between adjacent ones of the integrated circuit structures, Block  34 . Based on this deposition step, the resulting electrically insulating layer may have an undulating surface profile with at least one peak (e.g., on top of the integrated circuit structures) and at least one valley (e.g., in the spaces and gaps between the integrated circuit structures). In alternative embodiments of the invention, the electrically insulating layer may be formed using a dual-stress liner fabrication technique, which may accompany formation of CMOS integrated circuits having closely adjacent NMOS and PMOS transistors. 
         [0017]    The electrically insulating layer is then selectively thickened, Block  36 . In particular, portions of the electrically insulating layer extending in the gaps between the integrated circuit structures are thickened by transferring electrically insulating material from the peaks of the electrically insulating layer to the valleys of the electrically insulating layer. This material transfer step is performed by using the peaks of the electrically insulating layer as sputter targets for high energy ions (e.g., N+ ions) established in a high density plasma. The use of the peaks of the electrically insulating layer as sputter targets causes recession of the peaks in the electrically insulating layer and a redeposition of electrically insulating material into the valleys. As illustrated by the decision Block  38 , the steps illustrated by Blocks  34  and  36  may be repeated to define a sufficiently thick electrically insulating layer. Additional process steps may then be performed to complete an integrated circuit fabrication process at the semiconductor wafer level, Block  40 . 
         [0018]      FIG. 2B  is a flow diagram of process steps that illustrates methods  50  of forming integrated circuit devices, according to embodiments of the present invention. As illustrated by Block  52 , a highly integrated array of insulated gate electrodes are formed on a surface of an integrated circuit substrate. At least one silicon nitride layer is then deposited on the integrated circuit substrate, Block  34 . This deposition step may be performed using a chemical vapor deposition technique or a plasma deposition technique, for example. Other deposition techniques may also be used. The silicon nitride layer is deposited to extend on the insulated gate electrodes and in the gaps (e.g., spaces) extending between adjacent ones of the insulated gate electrodes. Based on this conformal deposition step, the resulting silicon nitride layer may have an undulating surface profile with at least one peak (e.g., on top of the insulated gate electrodes) and at least one valley (e.g., in the spaces and gaps between the insulated gate electrodes). 
         [0019]    The silicon nitride layer is then selectively thickened, Block  56 . In particular, portions of the silicon nitride layer extending in the gaps between the insulated gate electrodes are thickened by transferring silicon nitride material from the peaks of the silicon nitride layer to the valleys of the silicon nitride layer. This material transfer step is performed by using the peaks of the silicon nitride layer as sputter targets for high energy ions (e.g., N+ ions) established in a high density plasma. The use of the peaks of the silicon nitride layer as sputter targets causes recession of the peaks in the silicon nitride layer and a redeposition of silicon nitride material into the valleys. As illustrated by the decision Block  58 , the steps illustrated by Blocks  54  and  56  may be repeated to define a sufficiently thick silicon nitride layer. Additional process steps may then be performed to complete an integrated circuit fabrication process at the semiconductor wafer level, Block  60 . 
         [0020]    In the drawings and specification, there have been disclosed typical preferred embodiments of the invention and, although specific terms are employed, they are used in a generic and descriptive sense only and not for purposes of limitation, the scope of the invention being set forth in the following claims.