鈮酸鋰晶體之光扇效應與應用

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劉榮平(Jung-Ping Liu) 查詢紙本館藏

畢業系所

光電科學與工程學系

論文名稱

鈮酸鋰晶體之光扇效應與應用
(The fanning effect and its application of lithium niobate crystal)

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摘要(中)

鈮酸鋰晶體是一種被廣泛使用於全像光儲存的光折變材料。然而由於光折變非線性效應，因此鈮酸鋰晶體在照光時很容易產生光致散射現象，也就是所謂的光扇效
應。光扇現象對於大部分的全像儲存術來說，都是一種很嚴重的雜訊來源，也因此瞭解鈮酸鋰晶體中的光扇現象是一件非常有意義且重要的工作。本論文乃基於此動機，從全像術的概念以及光折變晶體光學出發，探討光折變鈮酸鋰晶體在各種實驗條件下的光扇效應特性以及其應用。
在現象研究方面，我們探討了不同晶體擺向以及將晶體浸入不同溶液時，扇射效應的不同。此外我們也探討了不同照光光束直徑、不同照光偏振態和不同光強對鈮酸
鋰晶體中光扇效應的影響。我們發現在同調光照射、晶體光軸垂直光路的情況下，在鈮酸鋰晶體中總是會產生光扇效應。此外，這一部份的工作也可以幫助我們瞭解光扇效應的特性，並對我們後續要抑制或應用光扇效應時有所助益。
在光扇效應的應用研究方面，我們提出利用光扇效應在光折變鈮酸鋰晶體中以同調光單光束記錄影像資料。據我所知這種記錄法在過去從未有人提出過。除此此外，
我們還提出利用同調光單光束記錄法在晶體中記錄灰階影像的方法，並證實了用同調光單光束記錄法也可以進行多功儲存。我們也把同調光單光束記錄法應用在動態擾動介質中的單向成像。我們提出的架構是所有動態擾動介質中的單向成像術中，最簡單的，也是唯一一種可以接受任何偏振態光的方法。最後，我們發現雖然非同調光（白光）在晶體中不會產生任何光扇效應，但仍然可以在光折變鈮酸鋰晶體中記錄邊緣強化的影像資料。據我們所知，在過去從未有人能單以極弱的白光在光折變晶體中產生折射率變化，甚至是記錄影像。我們也對這個現象提出了一個符合實驗的理論模型。

摘要(英)

Lithium niobate is one of the widely used photorefractive materials in the field of holography and optical signal processing. However, there is always the effect of light-induced scattering, the “fanning effect”, in lithium niobate crystal under light illumination. The fanning effect is due to the nonlinear photorefractive effect, and it will reduce the signal-to-noise ratio of the storage system. Therefore it is an important issue to investigate the fanning effect in lithium niobate crystal. Based on this idea, in this thesis I discussed the phenomenological characteristics of fanning effect in lithium niobate crystal in different configurations. I also proposed some applications using fanning effect. In studying the characteristics of fanning effect, we investigated the fanning
effect in different crystal orientations, liquids in which the crystal is immersed, light
polarization states, light spot sizes, and light intensities. We found that when the crystal is x-cut, fanning effect always occurs regardless of the polarization state is ordinary or extraordinary. On the other hand, different immersing liquids or light spot sizes do not change the phenomenon of fanning effect. In applying fanning effect, we proposed a novel method to record images in lithium niobate using only object beam. The recording is due to fanning effect, and it can be analyzed using the model of fanning hologram. Using this recording
method, we accomplished gray-level pattern multiplexing. We further demonstrated one-way imaging through dynamic turbid media using this recording method. Our method is, to our knowledge, the simplest one-way imaging method, and it is also the only one that can work on any polarization state of light. Finally, although
incoherent light never induces fanning light, we found it can also induce variation of refractive index of lithium niobate crystal. We also investigated its mechanism, and suggested some applications using the incoherent one beam recording method.

關鍵字(中)

★ 鈮酸鋰
★ 光折變晶體
★ 單光束儲存
★ 光扇效應

關鍵字(英)

★ LiNbO3
★ lithium niobate
★ photorefractive crystal
★ fanning effect
★ one-beam recording

論文目次

摘要 I
Abstract II
致謝辭 III
目錄 IV
第一章 1
1 緒論 1
1-1 全像術 2
1-2 光折變鈮酸鋰晶體的基本性質 6
1-3 光伏效應 11
1-4 參考資料 13
第二章 17
2 能帶傳播模型以及光折變效應 17
2-1 能帶傳播模型 18
2-2 週期性光照下的穩態解 20
2-3 週期性折射率變化 25
2-4 二波混合 27
2-5 參考資料 31
第三章 34
3 鈮酸鋰晶體中的光扇效應 34
3-1 光扇效應模型 34
3-2 鈮酸鋰晶體中的光扇效應 38
3-3 結論 52
3-4 參考資料 54
第四章 58
4 單光束儲存與應用 58
4-1 單光束儲存 59
4-2 單光束儲存之理論模型 63
4-3 灰階圖案之單光束多工儲存 71
4-4 擾動介質中的單光束單向顯像術 77
IV
4-5 參考資料 82
第五章 85
5 非同調光之單光束儲存 85
5-1 鈮酸鋰晶體白光單光束儲存 85
5-2 非週期性光照下Kukhtarev方程式的穩態解 91
5-3 結論 97
5-4 參考資料 97
第六章 99
6 總結 99
附錄一 101
附錄二 106

參考文獻

（第一章，第二章以後之參考資料請參閱論文）
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指導教授

游漢輝(Hon-Fai Yau)

審核日期

2005-5-23

推文