| ²é¿´: 263 | »Ø¸´: 3 | |||
| µ±Ç°Ö÷ÌâÒѾ´æµµ¡£ | |||
·çÓê182ľ³æ (ÕýʽдÊÖ)
|
[½»Á÷]
¡¾ÇóÖú¡¿Çë½Ì¸ßÊÖ
|
||
|
²»Í¬·Ç½ðÊôÔªËزôÔÓTiO2µÄ͸Éäµç¾µÍ¼¼ûͼ5-2Ëùʾ¡£ÓÉͼÖпÉÒÔ¿´³ö£¬ÖƱ¸µÄ´¿TiO2Á£¾¶¾ùÔÈ£¬´óСÔÚ20 nm×óÓÒ£»N²ôÔÓTiO2ÖдæÔÚÁ½ÖֳߴçµÄ¾§Á££¬½áºÏXRD¼ÆËã·ÖÎö£¬½Ï´óµÄÁ£¾¶ÊǽðºìʯÏ࣬½ÏСµÄÁ£¾¶ÊÇÈñîÑ¿óÏࣻS²ôÔÓTiO2Ò²´æÔÚÁ½ÖÖ¾§ÐÍ£¬µ«¾§Á£³ß´ç²î±ð²»ÈçN²ôÔÓµÄÃ÷ÏÔ£¬Õâ¿ÉÄÜÊÇÒòΪ¾§Ïà×é³É²»Í¬Ôì³ÉµÄ£»N-S¹²²ôÔÓTiO2µÄÁ£¾¶×îС£¬Ô¼ÔÚ15 nm×óÓÒ£¬Óë¼ÆËãÖµ£¨¼û±í5-1£©Ïà·û¡£ Çë²»ÒªÖ±½Ó¸´ÖÆ·ÒëÈí¼þ£¡£¡£¡£¡£¡£¡£¡ |
»Ø¸´´ËÂ¥» ²ÂÄãϲ»¶
323·Ö£¨¼ÆËã»úÊÓ¾õºÍ´óÄ£ÐÍÏîÄ¿£©ÄÜÖ±½ÓÉÏÊÖ
ÒѾÓÐ3È˻ظ´
-
¸´ÊÔµ÷¼Á
ÒѾÓÐ3È˻ظ´
-
311·Ö 22408 Çóµ÷¼Á
ÒѾÓÐ3È˻ظ´
-
320·ÖÈ˹¤ÖÇÄܵ÷¼Á
ÒѾÓÐ7È˻ظ´
-
Ò»Ö¾Ô¸Ö£´ó0705Çóµ÷¼Á
ÒѾÓÐ4È˻ظ´
-
0703»¯Ñ§
ÒѾÓÐ10È˻ظ´
-
301Çóµ÷¼Á
ÒѾÓÐ10È˻ظ´
-
306·Ö²ÄÁÏÓ뻯¹¤Çóµ÷¼Á
ÒѾÓÐ6È˻ظ´
-
²ÄÁϵ÷¼Á
ÒѾÓÐ11È˻ظ´
-
324Çóµ÷¼Á
ÒѾÓÐ9È˻ظ´
¡ï ¡ï ¡ï ¡ï ¡ï ¡ï ¡ï
·çÓê182(½ð±Ò+7,VIP+0): 9-26 08:58
·çÓê182(½ð±Ò+7,VIP+0): 9-26 08:58
| The TEM images of TiO2 samples doped with different non-metallic elements are shown in Fig. 5-2. From the figure, it can be seen that all grains in the pure TiO2 sample are uniform in size which is around 20 nm in diameter; Two grain sizes can be found in the N-doped sample. With the help of XRD measurements, it is found that the large size is ascribed to ½ðºìʯÏà and the smaller size to ÈñîÑ¿óÏà; Two different grain sizes are also found in the S-doped sample. However, the difference between these two sizes is less than that in the N-doped sample, which may be due to the reason that the phase compositions in the S-doped sample is different from that of N-doped; The grain size in the N-S co-doped sample is the littlest among all samples. It is about 15 nm and it is compatible with the theoretical one (refer to Tab.5-1) |
2Â¥2009-09-25 07:39:24
czlj
ͳæ (СÓÐÃûÆø)
- Ó¦Öú: 0 (Ó׶ùÔ°)
- ½ð±Ò: 1123.5
- Ìû×Ó: 69
- ÔÚÏß: 2.1Сʱ
- ³æºÅ: 837052
- ×¢²á: 2009-08-30
- רҵ: ±£ÃÜ
¡ï ¡ï ¡ï ¡ï
·çÓê182(½ð±Ò+4,VIP+0): 9-26 08:58
·çÓê182(½ð±Ò+4,VIP+0): 9-26 08:58
| Figure 5-2 shows the TEM images of TiO2 samples doped with different non-metallic elements. One can see from this figure that highly uniform grain size around 200 nm in diameter can be obtained in the pure TiO2 sample; Two grain sizes can be found in the N-doped sample. With the aids of XRD analyse, the larger grain sizes are the rutile phases, while the smaller are anatase ones; Two different grain sizes are found in the S-doped sample as well. However, the difference between these two sizes is less evident than that in the N-doped ones, which may be due to the different phases in the S-doped sample; The grain size in the N-S co-doped sample is the smallest, about 15 nm in diameter, which is consistent with the calculated one (see Tab.5-1). |
3Â¥2009-09-25 10:37:45
wangjianna
½ð³æ (ÕýʽдÊÖ)
- ·ÒëEPI: 8
- Ó¦Öú: 0 (Ó׶ùÔ°)
- ½ð±Ò: 606.5
- É¢½ð: 994
- ºì»¨: 2
- ɳ·¢: 2
- Ìû×Ó: 450
- ÔÚÏß: 163.5Сʱ
- ³æºÅ: 840920
- ×¢²á: 2009-09-05
- ÐÔ±ð: MM
- רҵ: ÓлúºÏ³É
¡ï ¡ï ¡ï ¡ï
·çÓê182(½ð±Ò+4,VIP+0): 9-26 08:58
·çÓê182(½ð±Ò+4,VIP+0): 9-26 08:58
| The TEM images of TiO2 samples doped with different non-metallic elements are shown in Fig. 5-2. it can be conclided that the prepared TiO2 sample has the uniform grading, about a diameter of 20 nm. in N-doped sample there are two different grain sizes with the bigger one the rutile phases, while the smalleranatase ones by analysis of XRD. THERE ARE ALSO TWO DIFFERENT SIZES OF grain in S-doped sample However, the difference between these two sizes is less evident than that in the N-doped ones, which may be due to the different phases in the S-doped sample;The grain size in the N-S co-doped sample is the smallest, about 15 nm in diameter, which is consistent with the calculated one (see Tab.5-1). |
4Â¥2009-09-25 15:27:38
