公开(公告)号：US07459364B2

公开(公告)日：2008-12-02

申请号：US11178709

申请日：2005-07-11

申请人： Sang-Hoon Lee ,  Hun-Hyeoung Leam ,  Jai-Dong Lee ,  Jung-Hwan Kim ,  Young-Sub You ,  Ki-Su Na ,  Woong Lee ,  Yong-Sun Lee ,  Won-Jun Jang

发明人： Sang-Hoon Lee ,  Hun-Hyeoung Leam ,  Jai-Dong Lee ,  Jung-Hwan Kim ,  Young-Sub You ,  Ki-Su Na ,  Woong Lee ,  Yong-Sun Lee ,  Won-Jun Jang

IPC分类号： H01L21/336

CPC分类号： H01L27/115 ,  H01L27/11521 ,  Y10S438/978

摘要： A method of forming a floating gate of a non-volatile memory device can include etching a mask pattern formed between field isolation regions in a field isolation pattern on a substrate to recess a surface of the mask pattern below an upper surface of adjacent field isolation regions to form an opening having a width defined by a side wall of the adjacent field isolation regions above the surface. Then the adjacent field isolation regions is etched to increase the width of the opening.

摘要翻译： 形成非易失性存储器件的浮置栅极的方法可以包括在衬底上的场隔离图案中蚀刻在场隔离区域之间形成的掩模图案，以将掩模图案的表面凹陷在相邻场隔离区域的上表面之下 以形成具有由表面上方的相邻场隔离区域的侧壁限定的宽度的开口。 然后蚀刻相邻的场隔离区以增加开口的宽度。

公开(公告)号：US20060068547A1

公开(公告)日：2006-03-30

申请号：US11178709

申请日：2005-07-11

申请人： Sang-Hoon Lee ,  Hun-Hyeoung Leam ,  Jai-Dong Lee ,  Jung-Hwan Kim ,  Young-Sub You ,  Ki-Su Na ,  Woong Lee ,  Yong-Sun Lee ,  Won-Jun Jang

发明人： Sang-Hoon Lee ,  Hun-Hyeoung Leam ,  Jai-Dong Lee ,  Jung-Hwan Kim ,  Young-Sub You ,  Ki-Su Na ,  Woong Lee ,  Yong-Sun Lee ,  Won-Jun Jang

IPC分类号： H01L21/336

CPC分类号： H01L27/115 ,  H01L27/11521 ,  Y10S438/978

摘要： A method of forming a floating gate of a non-volatile memory device can include etching a mask pattern formed between field isolation regions in a field isolation pattern on a substrate to recess a surface of the mask pattern below an upper surface of adjacent field isolation regions to form an opening having a width defined by a side wall of the adjacent field isolation regions above the surface. Then the adjacent field isolation regions is etched to increase the width of the opening.

摘要翻译： 形成非易失性存储器件的浮置栅极的方法可以包括在衬底上的场隔离图案中蚀刻在场隔离区域之间形成的掩模图案，以将掩模图案的表面凹陷在相邻场隔离区域的上表面之下 以形成具有由表面上方的相邻场隔离区域的侧壁限定的宽度的开口。 然后蚀刻相邻的场隔离区域以增加开口的宽度。

公开(公告)号：US20070026651A1

公开(公告)日：2007-02-01

申请号：US11480380

申请日：2006-07-05

申请人： Hun-Hyeoung Leam ,  Hyeon-Deok Lee ,  Young-Sub You ,  Won-Jun Jang ,  Woong Lee ,  Jung-Hyun Park ,  Sang-Kyoung Lee ,  Jung-Geun Jee ,  Sang-Hoon Lee

发明人： Hun-Hyeoung Leam ,  Hyeon-Deok Lee ,  Young-Sub You ,  Won-Jun Jang ,  Woong Lee ,  Jung-Hyun Park ,  Sang-Kyoung Lee ,  Jung-Geun Jee ,  Sang-Hoon Lee

IPC分类号： H01L21/38

CPC分类号： H01L21/28273 ,  H01L21/32115 ,  H01L27/115 ,  H01L27/11521 ,  H01L29/42324

摘要： In a method of manufacturing a semiconductor device such as a flash memory device, an insulating pattern having an opening is formed to partially expose a surface of a substrate. A first silicon layer is formed on the exposed surface portion of the substrate and the insulating pattern. The first silicon layer has an opened seam overlying the previously exposed portion of the substrate. A heat treatment on the substrate is performed at a temperature sufficient to induce silicon migration so as to cause the opened seam to be closed via the silicon migration. A second silicon layer is then formed on the first silicon layer. Thus, surface profile of a floating gate electrode obtained from the first and second silicon layers may be improved.

摘要翻译： 在制造诸如闪速存储器件的半导体器件的方法中，形成具有开口的绝缘图案以部分地暴露衬底的表面。 第一硅层形成在基板的露出表面部分和绝缘图案上。 第一硅层具有覆盖衬底的先前暴露部分的开口接缝。 在足以诱导硅迁移的温度下进行在基板上的热处理，以便通过硅迁移使开放的接缝闭合。 然后在第一硅层上形成第二硅层。 因此，可以提高从第一和第二硅层获得的浮栅的表面轮廓。

公开(公告)号：US07410869B2

公开(公告)日：2008-08-12

申请号：US11480380

申请日：2006-07-05

申请人： Hun-Hyeoung Leam ,  Hyeon-Deok Lee ,  Young-Sub You ,  Won-Jun Jang ,  Woong Lee ,  Jung-Hyun Park ,  Sang-Kyoung Lee ,  Jung-Geun Jee ,  Sang-Hoon Lee

发明人： Hun-Hyeoung Leam ,  Hyeon-Deok Lee ,  Young-Sub You ,  Won-Jun Jang ,  Woong Lee ,  Jung-Hyun Park ,  Sang-Kyoung Lee ,  Jung-Geun Jee ,  Sang-Hoon Lee

IPC分类号： H01L21/336

CPC分类号： H01L21/28273 ,  H01L21/32115 ,  H01L27/115 ,  H01L27/11521 ,  H01L29/42324

摘要： In a method of manufacturing a semiconductor device such as a flash memory device, an insulating pattern having an opening is formed to partially expose a surface of a substrate. A first silicon layer is formed on the exposed surface portion of the substrate and the insulating pattern. The first silicon layer has an opened seam overlying the previously exposed portion of the substrate. A heat treatment on the substrate is performed at a temperature sufficient to induce silicon migration so as to cause the opened seam to be closed via the silicon migration. A second silicon layer is then formed on the first silicon layer. Thus, surface profile of a floating gate electrode obtained from the first and second silicon layers may be improved.

摘要翻译： 在制造诸如闪速存储器件的半导体器件的方法中，形成具有开口的绝缘图案以部分地暴露衬底的表面。 第一硅层形成在基板的露出表面部分和绝缘图案上。 第一硅层具有覆盖衬底的先前暴露部分的开口接缝。 在足以诱导硅迁移的温度下进行在基板上的热处理，以便通过硅迁移使开放的接缝闭合。 然后在第一硅层上形成第二硅层。 因此，可以提高从第一和第二硅层获得的浮栅的表面轮廓。

公开(公告)号：US07297620B2

公开(公告)日：2007-11-20

申请号：US10839934

申请日：2004-05-06

申请人： Young-Sub You ,  Hun-Hyeoung Leam ,  Seok-Woo Nam ,  Bong-Hyun Kim ,  Woong Lee ,  Sang-Hoon Lee

发明人： Young-Sub You ,  Hun-Hyeoung Leam ,  Seok-Woo Nam ,  Bong-Hyun Kim ,  Woong Lee ,  Sang-Hoon Lee

IPC分类号： H01L21/3205 ,  H01L21/4763 ,  H01L21/31 ,  H01L21/469

CPC分类号： H01L21/0223 ,  H01L21/02255 ,  H01L21/02332 ,  H01L21/0234 ,  H01L21/31662

摘要： In methods of forming an oxide layer and an oxynitride layer, a substrate is loaded into a reaction chamber having a first pressure and a first temperature. The oxide layer is formed on the substrate using a reaction gas while increasing a temperature of the reaction chamber from the first temperature to a second temperature under a second pressure. Additionally, the oxide layer is nitrified in the reaction chamber to form the oxynitride layer on the substrate. When the oxide layer and/or the oxynitride layer are formed on the substrate, minute patterns of a semiconductor device, for example a DRAM device, an SRAM device or an LOGIC device may be easily formed on the oxide layer or the oxynitride layer.

摘要翻译： 在形成氧化物层和氧氮化物层的方法中，将衬底装载到具有第一压力和第一温度的反应室中。 使用反应气体在基板上形成氧化物层，同时在第二压力下将反应室的温度从第一温度升至第二温度。 此外，氧化物层在反应室中被硝化以在衬底上形成氧氮化物层。 当在衬底上形成氧化物层和/或氧氮化物层时，可以容易地在氧化物层或氧氮化物层上形成半导体器件（例如DRAM器件，SRAM器件或LOGIC器件）的微小图案。

公开(公告)号：US20080090424A1

公开(公告)日：2008-04-17

申请号：US11973042

申请日：2007-10-05

申请人： Young-Sub You ,  Hun-Hyeoung Leam ,  Seok-Woo Nam ,  Bong-Hyun Kim ,  Woong Lee ,  Sang-Hoon Lee

发明人： Young-Sub You ,  Hun-Hyeoung Leam ,  Seok-Woo Nam ,  Bong-Hyun Kim ,  Woong Lee ,  Sang-Hoon Lee

IPC分类号： H01L21/469

CPC分类号： H01L21/0223 ,  H01L21/02255 ,  H01L21/02332 ,  H01L21/0234 ,  H01L21/31662

摘要： In methods of forming an oxide layer and an oxynitride layer, a substrate is loaded into a reaction chamber having a first pressure and a first temperature. The oxide layer is formed on the substrate using a reaction gas while increasing a temperature of the reaction chamber from the first temperature to a second temperature under a second pressure. Additionally, the oxide layer is nitrified in the reaction chamber to form the oxynitride layer on the substrate. When the oxide layer and/or the oxynitride layer are formed on the substrate, minute patterns of a semiconductor device, for example a DRAM device, an SRAM device or an LOGIC device may be easily formed on the oxide layer or the oxynitride layer.

摘要翻译： 在形成氧化物层和氧氮化物层的方法中，将衬底装载到具有第一压力和第一温度的反应室中。 使用反应气体在基板上形成氧化物层，同时在第二压力下将反应室的温度从第一温度升至第二温度。 此外，氧化物层在反应室中被硝化以在衬底上形成氧氮化物层。 当在衬底上形成氧化物层和/或氧氮化物层时，可以容易地在氧化物层或氧氮化物层上形成半导体器件（例如DRAM器件，SRAM器件或LOGIC器件）的微小图案。

公开(公告)号：US07521375B2

公开(公告)日：2009-04-21

申请号：US11973042

申请日：2007-10-05

申请人： Young-sub You ,  Hun-Hyeoung Leam ,  Seok-Woo Nam ,  Bong-Hyun Kim ,  Woong Lee ,  Sang-Hoon Lee

发明人： Young-sub You ,  Hun-Hyeoung Leam ,  Seok-Woo Nam ,  Bong-Hyun Kim ,  Woong Lee ,  Sang-Hoon Lee

IPC分类号： H01L21/31 ,  H01L21/469

CPC分类号： H01L21/0223 ,  H01L21/02255 ,  H01L21/02332 ,  H01L21/0234 ,  H01L21/31662

摘要： In methods of forming an oxide layer and an oxynitride layer, a substrate is loaded into a reaction chamber having a first pressure and a first temperature. The oxide layer is formed on the substrate using a reaction gas while increasing a temperature of the reaction chamber from the first temperature to a second temperature under a second pressure. Additionally, the oxide layer is nitrified in the reaction chamber to form the oxynitride layer on the substrate. When the oxide layer and/or the oxynitride layer are formed on the substrate, minute patterns of a semiconductor device, for example a DRAM device, an SRAM device or an LOGIC device may be easily formed on the oxide layer or the oxynitride layer.

摘要翻译： 在形成氧化物层和氧氮化物层的方法中，将衬底装载到具有第一压力和第一温度的反应室中。 使用反应气体在基板上形成氧化物层，同时在第二压力下将反应室的温度从第一温度升至第二温度。 此外，氧化物层在反应室中被硝化以在衬底上形成氧氮化物层。 当在衬底上形成氧化物层和/或氧氮化物层时，可以容易地在氧化物层或氧氮化物层上形成半导体器件（例如DRAM器件，SRAM器件或LOGIC器件）的微小图案。

公开(公告)号：US07041558B2

公开(公告)日：2006-05-09

申请号：US10698825

申请日：2003-10-31

申请人： Young-Sub You ,  Hun-Hyeoung Leam ,  Sang-Hoon Lee

发明人： Young-Sub You ,  Hun-Hyeoung Leam ,  Sang-Hoon Lee

IPC分类号： H01L21/8247

CPC分类号： H01L27/11521 ,  H01L21/28273 ,  H01L21/324 ,  H01L27/115 ,  H01L29/42324 ,  Y10S438/926

摘要： Disclosed herein is a method of forming a floating gate in a non-volatile memory device having a self-aligned shallow trench isolation (SA-STI) structure. First, a tunnel oxide layer is formed on a semiconductor substrate having a SA-STI structure. Next, a first floating gate layer is formed on the tunnel oxide layer at a first temperature of no less than about 530° C. A second floating gate layer is then formed on the first floating gate layer at a second temperature of no more than 580° C. After depositing the first floating gate layer, the second floating gate layer is in-situ deposited to prevent the growth of a native oxide layer on the surface of the first floating gate layer. Thus, gate resistance can be reduced and process time can be shortened.

公开(公告)号：US07524747B2

公开(公告)日：2009-04-28

申请号：US11371897

申请日：2006-03-08

申请人： Young-Sub You ,  Hun-Hyeoung Leam ,  Sang-Hoon Lee

发明人： Young-Sub You ,  Hun-Hyeoung Leam ,  Sang-Hoon Lee

IPC分类号： H01L21/4763

CPC分类号： H01L27/11521 ,  H01L21/28273 ,  H01L21/324 ,  H01L27/115 ,  H01L29/42324 ,  Y10S438/926

摘要： Disclosed herein is a method of forming a floating gate in a non-volatile memory device having a self-aligned shallow trench isolation (SA-STI) structure. First, a tunnel oxide layer is formed on a semiconductor substrate having a SA-STI structure. Next, a first floating gate layer is formed on the tunnel oxide layer at a first temperature of no less than about 530° C. A second floating gate layer is then formed on the first floating gate layer at a second temperature of no more than 580° C. After depositing the first floating gate layer, the second floating gate layer is in-situ deposited to prevent the growth of a native oxide layer on the surface of the first floating gate layer. Thus, gate resistance can be reduced and process time can be shortened.

摘要翻译： 本文公开了一种在具有自对准浅沟槽隔离（SA-STI）结构的非易失性存储器件中形成浮置栅极的方法。 首先，在具有SA-STI结构的半导体衬底上形成隧道氧化层。 接下来，在不少于约530℃的第一温度下在隧道氧化物层上形成第一浮栅层。然后在不大于580°的第二温度下在第一浮栅上形成第二浮栅层 在沉积第一浮栅之后，第二浮栅层被原位沉积以防止第一浮栅层表面上的自然氧化物层的生长。 因此，可以减小栅极电阻，并且可以缩短处理时间。

公开(公告)号：US20060151811A1

公开(公告)日：2006-07-13

申请号：US11371897

申请日：2006-03-08

申请人： Young-Sub You ,  Hun-Hyeoung Leam ,  Sang-Hoon Lee

发明人： Young-Sub You ,  Hun-Hyeoung Leam ,  Sang-Hoon Lee

IPC分类号： H01L29/76 ,  H01L29/745

CPC分类号： H01L27/11521 ,  H01L21/28273 ,  H01L21/324 ,  H01L27/115 ,  H01L29/42324 ,  Y10S438/926

摘要： Disclosed herein is a method of forming a floating gate in a non-volatile memory device having a self-aligned shallow trench isolation (SA-STI) structure. First, a tunnel oxide layer is formed on a semiconductor substrate having a SA-STI structure. Next, a first floating gate layer is formed on the tunnel oxide layer at a first temperature of no less than about 530° C. A second floating gate layer is then formed on the first floating gate layer at a second temperature of no more than 580° C. After depositing the first floating gate layer, the second floating gate layer is in-situ deposited to prevent the growth of a native oxide layer on the surface of the first floating gate layer. Thus, gate resistance can be reduced and process time can be shortened.