| ²é¿´: 188 | »Ø¸´: 2 | ||
| ¡¾½±Àø¡¿ ±¾Ìû±»ÆÀ¼Û1´Î£¬×÷ÕßwolfliuÔö¼Ó½ð±Ò 1 ¸ö | ||
| µ±Ç°Ö÷ÌâÒѾ´æµµ¡£ | ||
wolfliuľ³æ (ÖøÃûдÊÖ)
|
[×ÊÔ´]
A Tunable Electrochromic Fabry-Perot Filter for Adaptive Optics Applications
|
|
|
A Tunable Electrochromic Fabry-Perot Filter for Adaptive Optics Applications Daniel R. Kammler Neutron Generator Design Science and Engineering Department William G. Yelton, Jason C. Verley, Photonic Microsystems Technology Department William C. Sweatt Applied Photonic Microsystems Department Edwin J. Heller, Jonathan D. Blaich MicroDevice Technologies Department Andrea Ambrosini Chemical and Biological Systems Department Sandia National Laboratories P.O. Box 5800 Albuquerque, NM 87185 Abstract: The potential for electrochromic (EC) materials to be incorporated into a Fabry-Perot (FP) filter to allow modest amounts of tuning was evaluated by both experimental methods and modeling. A combination of chemical vapor deposition (CVD), physical vapor deposition (PVD), and electrochemical methods was used to produce an ECFP film stack consisting of an EC WO3/Ta2O5/NiOxHy film stack (with indium-tin-oxide electrodes) sandwiched between two Si3N4/SiO2 dielectric reflector stacks. A process to produce a NiOxHy charge storage layer that freed the EC stack from dependence on atmospheric humidity and allowed construction of this complex EC-FP stack was developed. The refractive index (n) and extinction coefficient (k) for each layer in the EC-FP film stack was measured between 300 and 1700 nm. A prototype EC-FP filter was produced that had a transmission at 500 nm of 36%, and a FWHM of 10 nm. A general modeling approach that takes into account the desired pass band location, pass band width, required transmission and EC optical constants in order to estimate the maximum tuning from an EC-FP filter was developed. Modeling shows that minor thickness changes in the prototype stack developed in this project should yield a filter with a transmission at 600 nm of 33% and a FWHM of 9.6nm, which could be tuned to 598 nm with a FWHM of 12.1 nm and a transmission of 16%. Additional modeling shows that if the EC WO3 absorption centers were optimized, then a shift from 600 nm to 598 nm could be made with a FWHM of 11.3 nm and a transmission of 20%. If (at 600 nm) the FWHM is decreased to 1 nm and transmission maintained at a reasonable level (e.g. 30%), only fractions of a nm of tuning would be possible with the film stack considered in this study. These tradeoffs may improve at other wavelengths or with EC materials different than those considered here. Finally, based on our limited investigation and material set, the severe absorption associated with the refractive index change suggests that incorporating EC materials into phase correcting spatial light modulators (SLMS) would allow for only negligible phase correction before transmission losses became too severe. However, we would like to emphasize that other EC materials may allow sufficient phase correction with limited absorption, which could make this approach attractive. [ Last edited by luo.henry on 2008-4-26 at 12:20 ] |
»Ø¸´´ËÂ¥» ²ÂÄãϲ»¶
²ÄÁÏ¿¼Ñе÷¼Á
ÒѾÓÐ29È˻ظ´
-
297¹¤¿Æ£¬Çóµ÷¼Á?
ÒѾÓÐ10È˻ظ´
-
211±¾¿Æ²ÄÁÏ»¯¹¤Çóµ÷¼Á
ÒѾÓÐ19È˻ظ´
-
0831Ò»ÂÖµ÷¼Áʧ°ÜÇóÖú
ÒѾÓÐ10È˻ظ´
-
²ÄÁÏÏà¹Øרҵ344Çóµ÷¼ÁË«·Ç¹¤¿ÆѧУ»ò¿ÎÌâ×é
ÒѾÓÐ9È˻ظ´
-
Çóµ÷¼Á£¬985²ÄÁÏÓ뻯¹¤348·Ö
ÒѾÓÐ13È˻ظ´
-
085600²ÄÁÏÓ뻯¹¤349·ÖÇóµ÷¼Á
ÒѾÓÐ8È˻ظ´
-
Ò»Ö¾Ô¸ÖÐÄÏ´óѧ 0855 »úе 286 Çóµ÷¼Á
ÒѾÓÐ9È˻ظ´
-
Ò»Ö¾Ô¸085502£¬267·ÖÇóµ÷¼Á
ÒѾÓÐ15È˻ظ´
-
Ò»Ö¾Ô¸Õã´óÉúÎï325·ÖÇóµ÷¼Á
ÒѾÓÐ9È˻ظ´
wolfliu
ľ³æ (ÖøÃûдÊÖ)
- Ó¦Öú: 0 (Ó׶ùÔ°)
- ¹ó±ö: 0.3
- ½ð±Ò: 2146.1
- Ìû×Ó: 1201
- ÔÚÏß: 34.7Сʱ
- ³æºÅ: 340984
2Â¥2007-06-25 10:09:55
