平衡偵測雙頻率外差干涉極化儀在磁致旋光效應及醣類變旋動力學之精密量測

以作者查詢圖書館館藏

、以作者查詢臺灣博碩士

、以作者查詢全國書目

、勘誤回報

、線上人數：28

、訪客IP：3.145.81.252

姓名

林主恩(Chu-En Lin) 查詢紙本館藏

畢業系所

光電科學與工程學系

論文名稱

平衡偵測雙頻率外差干涉極化儀在磁致旋光效應及醣類變旋動力學之精密量測
(Applications of balanced detection two-frequency heterodyne paired polarized polarimeter on magnetochiral effect and mutarotation kinetics measurement)

相關論文

★ 半導體雷射控制頻率	★ 比較全反射受挫法與反射式干涉光譜法在生物感測上之應用
★ 193nm深紫外光學薄膜之研究	★ 雙頻雷射共光程外差干涉橢圓儀
★ 超晶格結構之硬膜研究	★ 交錯傾斜微結構薄膜在深紫外光區之研究
★ 膜堆光學導納量測儀	★ 紅外光學薄膜之研究
★ 成對表面電漿波生物感知器應用在去氧核糖核酸及微型核糖核酸雜交反應檢測	★ 成對表面電漿波生物感測器之研究及其在生醫上的應用
★ 影像式外差干涉術之建立	★ 探討硫化鎘緩衝層之離子擴散處理對CIGS薄膜元件效率影響
★ 以反應性射頻磁控濺鍍搭配HMDSO電漿聚合鍍製氧化矽摻碳薄膜阻障層之研究	★ 掃描式白光干涉儀應用在量測薄膜之光學常數
★ 量子點窄帶濾光片	★ 以量測反射係術探測光學薄膜之特性

檔案

[Endnote RIS 格式]

[Bibtex 格式]

[相關文章]

[文章引用]

[完整記錄]

[館藏目錄]

[檢視]

[下載]

本電子論文使用權限為同意立即開放。
已達開放權限電子全文僅授權使用者為學術研究之目的，進行個人非營利性質之檢索、閱讀、列印。
請遵守中華民國著作權法之相關規定，切勿任意重製、散佈、改作、轉貼、播送，以免觸法。

摘要(中)

本文是利用平衡偵測雙頻率外差干涉極化儀，量測一般物質的磁致旋光效應(magnetochiral effect)以及醣類的變旋(mutarotation)現象，利用這個光學架構，可以成為研究基礎物理及化學的平台。在本文中，利用平衡偵測雙頻率外差干涉極化儀，測量固態及氣態物質的磁致旋光角度及Verdet常數，所量測的物質分別為Bi12SiO20 (BSO)晶體及空氣。我們量測出BSO晶體的磁致旋光角度1.8×10-5(rad) 以及，Verdet常數5.27×10-5(rad/mT mm) ；在量測空氣磁致旋光效應的實驗中，平衡偵測雙頻率外差干涉極化儀僅以單光程的架構，即可量測出空氣的磁致旋光角度5.2×10-6(rad) 及Verdet常數1.3×10-6(rad/mT m)。在量測空氣磁致旋光效應實驗中，利用平衡偵測雙頻率外差干涉極化儀，在量測磁致旋光角度的解析度，最高可以達到1.74×10-7(rad) 。如果平衡偵測雙頻率外差干涉極化儀在搭配上穿透係數為0.1、精細度為150的Fabry-Perot共振腔，量測微小旋光角度，經計算後，此光學系統在量測磁致旋光角度的解析度可高達 1.9×10-10(rad)。
在量測醣類變旋現象時，在光學架構上，我們提出了等振幅平衡偵測雙頻率外差干涉極化儀，它可以消除因為Zeeman氦氖雷射兩個正交的偏振光P和S波振幅不相等所帶來的誤差。在量測葡萄糖變旋現象的實驗中，光學架構在量測旋光角度靈敏度可以達到 8.3×10-5 (deg/cm)。針對變旋現象的動力學而言，我們求出了葡萄糖變旋現象的動力學係數：總變旋常數為 k=7.67×10-5 sec-1 、順向變旋常數 k1=2.76×10-5 sec-1和反向變旋常數k2=4.91×10-5 sec-1。除此以外，我們也量測到D-葡萄糖在632.8nm的量測光、溶於pH值為7的三次水時，α- 和β- D-葡萄糖的比旋光度(rotatory power)分別為105(deg(g/L)-1 dm-1) 及12(deg(g/L)-1 dm-1) 。
綜上所述，由於平衡偵測雙頻率外差干涉極化儀及等振幅平衡偵測雙頻率外差干涉極化儀，有著光學結構簡單、高靈敏度、高偵測效率、高訊雜比、低共同相位雜訊(common phase noise)和即時量測等特性。顯示了平衡偵測雙頻率外差干涉極化儀在基礎物理和生物化學上應用的潛力。

摘要(英)

In this article, balanced detection two-frequency heterodyne paired polarized polarimeter(BDTHP) is used to measure magnetochiral effect of Bi12SiO20 (BSO) crystal and ambient air. The Faraday rotation angle and Verdet constant of BSO crystal are 1.8×10-5(rad) and 5.27×10-5(rad/mT mm) respectively; the Faraday rotation angle and Verdet constant of ambient air are demonstrated as 5.2×10-6(rad) and 1.3×10-6(rad/mT m) respectively. In the experiment, measuring the magnetochiral effect of ambient air, the sensitivity of BDTHP is up to 1.74×10-7(rad) . If we applied a Fabry-Perot cavity with finesse F=150 and transmission coefficient K=0.1 in the balanced detection two-frequency heterodyne paired polarized polarimeter, the sensitivity of Faraday rotation angle detection will be up to 1.9×10-10(rad) . Moreover, the equal-amplitude balanced detection two-frequency heterodyne paired polarized polarimeter(EBDTHP) is proposed for measuring the mutarotation of D-glucose. The EBDTHP has the ability to degrade the error from the non-equal amplitudes of P and S waves of Zeeman He-Ne Laser. The total, forward and reversed mutarotation rate constant are k=7.67×10-5 sec-1, k1=2.76×10-5 sec-1, and k2=4.91×10-5 sec-1 respectively. The sensitivity of optical the rotation angle measurement in EBTHP was achieved with the value of 8.3×10-5 (deg/cm). The specific rotation angles of α-D-glucose 105(deg(g/L)-1 dm-1) and β-D-glucose 12(deg(g/L)-1 dm-1) are also measured by EBTHP. In summary, BTHP and EBTHP not only are capable of measuring the small optical rotation angle but also have the potential to be a research platform for biology and chemistry applications.

關鍵字(中)

★ 變旋
★ 極化儀
★ 磁致旋光

關鍵字(英)

★ mutarotation
★ magnetochiral
★ polarimetry

論文目次

中文摘要 i
英文摘要 iii
致謝 v
圖目錄 xi
表目錄 xiv
符號說明 xv
名詞縮寫表 xvii
第一章緒論 1
參考資料 5
第二章平衡偵測雙頻率外差干涉極化儀的實驗概觀 8
2.1 產生雙頻雷射的技術及方法 8
2.2 Zeeman氦氖雷射 13
2.3 光偵測系統 14
2.4 電子訊號擷取系統 17
2.5 量測磁致旋光的磁場線圈系統 19
參考資料 21
第三章平衡偵測雙頻率外差干涉極化儀原理概述 23
3.1 共光程外差干涉極化儀原理 23
3.2 等振幅外差干涉光源 26
參考資料 30
第四章平衡偵測雙頻率外差干涉極化儀在量測磁致旋光效應的量測與應用 32
4.1 磁光效應及磁致旋光效應簡介 32
4.2 磁致旋光效應及研究歷程 35
4.3 量測Bi12SiO20 (BSO)晶體的磁致旋光效應 41
實驗架構及方法計算 41
實驗結果 50
光學系統靈敏度分析 52
4.4 量測空氣的磁致旋光效應 55
實驗架構及方法計算 55
實驗結果 60
光學系統靈敏度分析 63
4.5 結論 65
參考資料 69
第五章等振幅平衡偵測雙頻率外差干涉極化儀在量測醣類
變旋現象的應用 73
5.1 醣類變旋(mutarotation)現象及研究歷程 73
5.2 醣類變旋的理論及機制 77
醣類的分類與同分異構物(isomer) 77
異頭物 80
5.3 實驗架構及方法計算 86
5.4 醣類變旋動力學理論計算 90
5.5 實驗結果 94
葡萄糖變旋現象的量測及動力學常數計算 94
葡萄糖在波長632.8nm時的比旋光度之量測 96
光學系統靈敏度分析 98
5.6 結論 100
參考資料 106
第六章未來展望 111
參考資料 113
發表文章 116

參考文獻

第一章
[1] C. Chou, K. H. Chiang, K. Y. Liao, Y. F. Chang, and C. E. Lin “Polarized photon-pairs heterodyne polarimetry for ultrasensitive optical activity detection of a chiral medium” J. Phys. Chem. B., 111, pp.9919-9922 (2007)
[2] C. C. Tsai, H. C. Wei, C. H. Hsieh, J. S. Wu, C. E. Lin, and C. Chou “Linear birefringence parameters determination of a multi-order wave plate via phase detection at large oblique incidence angles” Opt. Commun., 281, pp.3036-3041(2008)
[3] M. H. Chiu, J. Y. Lee, and D. C. Su “Refractive-index measurement based on the effects of total internal reflection and the uses of heterodyne interferometry” Appl. Opt., 36, pp.2936-2939 (1997)
[4] C. J. Yu, C. E. Lin, H. K. Teng, C. C. Tsai, and C. Chou “Daul-frequency paired polarization phase shifting ellipsometer” Opt. Commun. 282, pp.1516-1520 (2009)
[5] C. Chou, H. M. Tsai, K. Y. Liao, L. D. Chou, and P. H Huang “Optical activity measurement by use of a balanced detector optical heterodyne interferometer” Appl. Opt., 45, pp.3733-3739 (2006)
[6] G. P. Agrawal “Fiber-optic communication systems” (Wiley, New York) p. 239 (1997)
[7] C. Chou, C. W. Lyu, and L. C. Peng “Polarized differential-phase laser scanning microscope” Appl. Opt., 40, pp.95-99 (2001)
[8] Y. Le Grand and A. Le Floch “Measurement of small optical activities using the helicoidal waves” Opt. Lett., 17, pp.360-362 (1992)
[9] C. J. Yu, C. E. Lin, L. C. Su, and C. Chou “Heterodyne linear polarization modulation ellipsometer” Jpn. J. Appl. Phys., pp. 032403-1-032403-4 (2009)
[10] N. A. Campbell, J. B. Reece, L. G. Mitchell, and M. R. Taylor “Biology concepts and connections” (Addison Wesley, San Francisco, CA) pp.90-97 (2003)
[11] R. K. Murry, D. K. Granner, P. A. Mayes, and V. W. Rodwell “Harper’s Biochemistry 24th ed” (Prentice-Hall International Inc. London) p.137 (1996)
[12] A. M. Skelley, and R. A. Mathies “Rapid on-column analysis of glucosamine and its mutarotation by microchip capillary electrophoresis” J. Chromatogr. A., 1132, pp.304-309 (2006)
[13] C. E. Lin, C. J. Yu, Y. C. Li, C. C. Tsai, and C. Chou “High sensitivity two-frequency paired polarized interferometer in Faraday rotation angle measurement of ambient air with single-traveling configuration” J. Appl. Phys., 104, pp.033101-1-033101-5 (2008)
第二章
[1] S. Zhang, and T. Bosch “Orthogonally polarized lasers and their applications” Optics and Photonic News, 38, pp.39-43 (2007)
[2] P. Dirksen, J. V. D. Werf, and W. Bardoel “Novel two-frequency laser” Prec. Eng., 17, pp.114-116 (1995)
[3] D. C. Su, M. H. Chiu, and C. D. Chen “A heterodyne interferometer using an electro-optic modulator for measuring small displacements” J. Optics, 27, pp.19-23 (1996)
[4] E. Collett “Polarized light” (Marcel Dekker, New York) pp. 347-349 (1993)
[5] A. Yariv and P. Yeh “Optical Wave in Crystal” (John Wiley & Sons, Inc., New Jersey) pp.329-331 (2003)
[6] E. Hetch “Optics” (Addison Wesley Longman Inc., San Francisco), pp.368-370 (2002)
[7] Agilent 34401A 萬用電表使用者手冊
[8] 林正道、胡錦標編著雷射光電系統設計及應用全華科技圖書股份有限公司 pp.7-15 (1995)
[9] SR844 RF Lock-in Amplifier Operating manual and programming reference
[10] 惠汝生編著自動量測系統-LabVIEW全華科技圖書股份有限公司 chap.1 (1995)
[11] PHYWE公司提供的使用手冊
第三章
[1] E. Hetch “Optics” (Addison Wesley Longman Inc., San Francisco), pp.368-370 (2002)
[2] A. Yariv and P. Yeh “Optical Wave in Crystal” (John Wiley & Sons, Inc., New Jersey) pp.329-331 (2003)
[3] C. E. Lin, J. G. Chang, L. D. Chou, C. J. Yu, C. C. Lee, and C. Chou “Two-Frequency Paired Polarization Interferomet for Faraday Rotation Angle Detection” (accepted to Jpn. J. Appl. Phys.)
[4] J. Dyson “Interferometry as a measurement tool” (Machinery Publishing, Brighton) pp.148-150 (1970)
[5] M. Francon “Optical interferometry” (Elsevier, San Diego, CA) p.148(2003)
[6] C. E. Lin, C. J. Yu, Y. C. Li, C. C. Tsai, and C. Chou “High sensitivitytwo-frequency paired polarized interferometer in Faraday rotation angle measurement of ambient air with single-traveling configuration” J. Appl. Phys., 104, pp.033101-1-033101-5 (2008)
[7] C. Chou, K. H. Chiang, K. Y. Liao, Y. F. Chang, and C. E. Lin “Polarized photon-pairs heterodyne polarimetry for ultrasensitive optical activity detection of a chiral medium” J. Phys. Chem. B., 111, pp.9919-9922 (2007)
[8] C. J. Yu, C. E. Lin, L. P. Yu, and C. Chou “Paired circularly polarized heterodyne ellipsometer” Appl. Opt., 48, pp.758-764 (2009)
第四章
[1] D. Jiles “Introduction to magnetism and magnetic materials” (Chapman & Hall, London) P.57 (1991)
[2] L. Que, Jr. “Physical methods in bioinorganic chemistry：spectroscopy and magnetism” (University Science Books, Sausalito, CA) p.233 (2000)
[3] O. Brevet-Philibert, R. Brunetton, and J. Monin “Measuring the Verdet constant: a simple, high precision, automatic device” J. Phys. E: Sci. Instrum., 21, 647-649 (1988)
[4] D. Lacoste, B. A. van Tiggelen, G. L. J. A. Rikken, and A. Sparenberg “Optics of a Faraday-active Mie sphere” J. Opt. Am. Soc. A, 15, pp.1636-1642 (1998)
[5] K. Cho, S. P. Bush, D. L. Mazzoni, and C. C. Davis “Linear magnetic birefringence measurement of Faraday materials” Phys. Rev. B, 43, pp.965-970 (1991)
[6] A. Yariv and P. Yeh “Optical Wave in Crystal” (John Wiley & Sons, Inc., New Jersey) p.103 (2003)
[7] J. Wilson, and J. Hawkes “Optoelectronics: an introduction” (Prentice Hall Inc., Upper Saddle River, NJ) pp.110-112 (1998)
[8] F. L. Pedrotti, and S. J. L. S. Pedrotti “Introduction of optics” (Prentice Hall Inc., Upper Saddle River, NJ) pp.553-555 (1993)
[9] E. Hetch “Optics” (Addison Wesley Longman Inc., San Francisco), pp.368-370 (2002)
[10] J. A. Ferrari, A. Dubra, A. Arnaud, and D. Perciante “Current sensor using heterodyne detection” Appl. Opt., 38, pp.2808-2811 (1999)
[11] M. Inoue, K. Arai, T. Fujii, and M. Abe “Magneto-optical properties of one-dimensional photonic crystalscomposed of magnetic and dielectric layers” J.Appl. Phys., 83, pp.6768-6770 (1998)
[12] Marvin J. Webber “CRC Handbook of laser science and technology” (CRC Press Inc., Salem, MA) pp.367-377 (1995)
[13] W. A. Shurcliff, and S. S. Ballard “Polarized light” (Harvard Univ. Press, Cambridge, MA) p.119 (1962)
[14] C. E. Lin, C. J. Yu, Y. C. Li, C. C. Tsai, and C. Chou “High sensitivity two-frequency paired polarized interferometer in Faraday rotation angle measurement of ambient air with single-traveling configuration” J. Appl. Phys., 104, pp.033101-1-033101-5 (2008)
[15] G. R. Fowles “Introduction of modern optics, 2nd ed” (Dover Pubns, Mineola, New York) p.p.189-192 (1989)
[16] J. L. Flores, and J. A. Ferrari “Verdet constant dispersion measurement using polarization-stepping techniques” Appl. Opt., 47, pp.4396-4399 (2008)
[17] A. Jain, J. Kumar, F. Zhou, L. Li, and T. Sukant “A Simple experiment for determining Verdet constants using alternated current magnetic fields” Am. J. Phys., 67, pp.714-717 (1999)
[18] T. Yoshino, T, Hashimoto, M. Nara, and K. Kurosawa “Common path Heterodyne optical fiber sensors” J. lightwave technol., 10, pp.503-513 (1992)
[19] K. Muro, K. Sato, and Y. Takubo “Cavity-enhanced detection system with an optically-feedbacked diode laser for Faraday effect measurement” Jpn. J. Appl. Phys., 40, pp.L802-L804 (2001)
[20] T. Muller, K. B. Wiberg, and P. H. Vaccaro “Cavity Ring-Down Polarimetry (CRDP): A New Scheme for Probing Circular Birefringence and Circular Dichroism in the Gas Phase” J. Phys. Chem. A, 104, pp.5959-5968 (2000)
[21] R. Englen, G. Berden, E. van den Berg, and G. Meijer “Polarization dependent cavity ring down spectroscopy” J. Chem. Phys., 107, pp.4458-4467 (1997)
[22] Y. Le Grand and A. Le Floch “Measurement of small optical activities using the helicoidal waves” Opt. Lett., 17, pp.360-362 (1992)
[23] Y. Le Grand, M. Medjaou, A. Le Floch, and R. Le Naour “Measurement of small rotations by eigenvector flips in a quasi-iostropic Fabry-Perot” Appl. Phys. Lett., 51, pp.1574-1576 (1987)
[24] D. Jacob, M. Vallet, F. Bretenaker, A. Le Floch, and R. Le Naour “Small Faraday rotation with a Fabry-Perot cavity” Appl. Phys. Lett., 66, pp.3546-3548 (1995)
[25] J. S. Wu, W. T. Ni, and S. J. Chen “Building a 3.5m protype interferometer for the Q & A vacuum birefringence experiment and high precision ellipsometry” Class. Quantum Grav., 21, pp.S1259-S1263 (2004)
[26] C. E. Lin, J. G. Chang, L. D. Chou, C. J. Yu, C. C. Lee, and C. Chou “Two-Frequency Paired Polarization Interferomet for Faraday Rotation Angle Detection” (accepted to Jpn. J. Appl. Phys.)
[27] C. Chou, H. M. Tsai, K. Y. Liao, L. D. Chou, and P. H. Haung “Optical activity measurement by use of a balanced detector optical heterodyne interferometer” Appl. Opt., 45, pp.3733-3739 (2006)
[28] M. A. Heald, and J. B. Marion “Classical Electromagnetic Radiation 3rd ed” (Saunders College Publishing, Orlando, Florida) p.18 (1995)
第五章
[1] Lowry, T. W. “Optical Rotation Power” (Dover, New York) pp.271 (1964)
[2] C. S. Hudson “A review of discovers on the mutarotation of the sugers” J. Am. Chem. Soc., 32, pp.889-894 (1910)
[3] J. N. Broensted, and E. A. Guggenheim “Acid and basic catalysis of mutarotation” J. Am. Chem. Soc., 49, pp.2554-2584 (1927)
[4] N. Le Barc’H, J. M. Grossel, P. Looten, and M. Mathlouthi “Kinetic study of the mutarotation of D-glucose in concentrated aqueous solution by gas-liquid chromatography” Food Chem., 74, pp.119-124 (2001)
[5] C. C. Sweeley, R. Bentley, M. Makita, and W. W. Wells “Gas-liquid chromatography of trimethylsiyl derivatives of sugers and related substances” J. Am. Chem. Soc., 85, pp.2497-2500 (1963)
[6] R. Bentley, and N. Botlock “A gas chromatographic method analysis of anomeric carbohydrates and for determination of mutarotation coefficients” Anal. Biochem., 20, pp.312-320 (1967)
[7] K.-S. Ryu, C. Kim, C. Park, and B. S. Choi “NMR Analysis of Enzyme-catalyzed and Free-Equilibrium Mutarotation Kinetics of Monosaccharides” J. Am. Chem. Soc., 124, pp.9180-9181 (2004)
[8] J. L. Copa-patino, Y. zhang, B. Padmaperuma, P. Broda, and M. L. Sinnott “Polarimetry and 13C n.m.r. show that the hydrolyses of β-D-glucopyranosyl fluoride by β(1→3)-glucanases from Phanerochaete chrysosporium and Sporotrichum dimorphosporum have opposite stereochemistries” Biochem. J., 293, pp.591-594 (1993)
[9] A. G. Shostenko, S. Truszkowski, A. Bukhal’skii, and A. A. Churkin “Radiolysis of α-D-glucose and β-D-glucose anomers” High Energy Chem., 40, pp.203-205 (2006)
[10] E. M. Purcell “Electricity and magnetism 2nd ed.” (McGraw-Hill, Massachusetts) pp.470-471 (1985)
[11] J. C. Kendrew, and E. A. Moelwyn-Hughes “The kinetics of muarotation in solution” Proceedings of the Royal Society of London. Series A, Mathematical and Physical Sciences, 176, pp. 352-367 (1940)
[12] M. Waki, H. Abe, and M. Inouye “Translation of mutarotation into induced circular dichroism signals through helix inversion of host polymers” Angew. Chem. Int. Ed., 46, pp.3059-3061 (2007)
[13] A. M. Skelly, and R. A. Mathies “Rapid on-column analysis of glucosamine and its mutarotation by microchip capillary electrophorsis” J. Chromatogr. A, 1132, pp.304-309 (2006)
[14] C. Chou, K. H. Chiang, K. Y. Liao, Y. F. Chang, and C. E. Lin “Polarized photon-pairs heterodyne polarimetry for ultrasensitive optical activity detection of a chiral medium” J. Phys. Chem. B., 111, pp.9919-9922 (2007)
[15] M. A. Kabayama, and D. Patterson “The thermodynamics of mutarotation of some sugers II. Theoretical considerations” Can. J. Chem., 36, pp.563-573 (1958)
[16] B. V. Grande, H. Kallevik, F. O. Libnau, and O. M. Kvalheim “Resolution of infrared spectra and kinetic analysis of mutarotation of D-mannose in water” Chemometrics Intell. Lab. Syst., 45, pp.7-21 (1999)
[17] J. A. Beebe, A. Arabshahi, J. G. Clifton, D. Ringe, G. A. Petsko, and P. A. Fery “Galactose mutarotase: pH dependence of enzymatic mutarotation” Biochemistry, 42, pp.4414-4420 (2003)
[18] F. H. Westheimer “Amino acid catalysis of the mutarotation of glucose” J. Org. Chem., 26, pp.431-441 (1937)
[19] S. I. F. S. Martins, and A. J. S. van Boekel “Kinetics of the glucose/glycine Maillard reaction pathways: influences of pH and reactant initial concentrations” Food Chem., 92, pp.437-448 (2005)
[20] R. U. Lemieux, L. Anderson, and A. H. Conner “The mutarotation of 2-deoxy-β-d-erythro-pentose (“2-deoxy-β-d-ribose”) : Conformations, kinetics, and equilibria” Carbohydr. Res., 20, pp.59-72 (1971)
[21] N. M. Ballash, and E. B. Robertson “The mutarotation of glucose in dimethylsulfoxide and water mixtures” Can. J. Chem., 51, pp. 556-564 (1973)
[22] R. K. Murry, D. K. Granner, P. A. Mayes, and V. W. Rodwell “Harper’s Biochemistry 24th ed” (Prentice-Hall International Inc. London) p.137 (1996)
[23] S.Yamabe, and T. Ishikawa “Theoretical study of mutarotation of glucose” J. Org. Chem., 64, pp.4519-5424 (1999)
[24] A. M. Silva, E. C. da Silvab, and C. O. da Silva “A theoretical study of glucose mutarotation in aqueous solution” Carbohydr. Res., 341, pp.1029-1040 (2006)
[25] C. J. Yu, C. E. Lin, H. K. Teng, C. C. Tsai, and C. Chou “Dual-frequency paired polarization phase shifting ellipsometer” Opt. Commun., 282, pp.1516-1520(2009)
[26] R. J. McNichols, and G. L. Coté “Optical glucose sensing in biological fluids: an overview” J. Biomed. Opt., 5, pp.5-16 (2000)
第六章
[1] H. Kling, H. Geschka, and W. Hüttner “The temperature dependence of the cotton-mouton effect of ethane, ethene and ethyne ” Chem. Phys. Lett., 96, pp.631-635 (1983)
[2] L. Que, Jr. “Physical methods in bioinorganic chemistry：spectroscopy and magnetism” (University Science Books, Sausalito, CA) p.233 (2000)
[3] S. Kahl, and A. M. Grishin “Ehanced Faraday rotation in all-garnet magneto-optical photon crystal” Appl. Phys. Lett., 84, pp.1438-1440 (2004)
[4] M. Inoue, and K. Arai “Magneto-optical properties of one-dimensional photonic crystals composed of magnetic and dielectric layers” J. Appl. Phys., 83, pp.6768-6770 (1998)
[5] C. Koerdt, G. L. J. A. Rikken, and E. P. Petrov “Faraday effect of photonic crystals” Appl. Phys. Lett., 82, pp.1538-1540 (2003)
[6] V. Domenici, C. A. Veracini, K. Fodor-Csorba, G. Prampolini, I. Cacell, A. Lebar, and B. Zalar “Banana-Shaped Molecules Peculiarly Oriented in a Magnetic Field: 2H NMR Spectroscopy and Quantum Mechanical Calculations” ChemPhysChem, 8, pp.2321-2330 (2007)
[7] R. B. Meyer “Effect of electric and magnetic fields on the structure of cholesteric liquid crystal” Appl. Phys. Lett., 12, pp.281-282 (1968)
[8] S. Linden, C. Enkrich, M. Wegener, J. Zhou, T. Koschny, and C. M. Soukoulis “Magnetic response of metamaterials at 100 Terahertz” Science, 306, pp.1351-1353 (2004)
[9] Z. Haung, J. Xue, Y. Hou, J. Chu, and D. H. Zhang “Optical magnetic response from parallel plate metamaterials” Phys. Rev. B, pp.193105-1-193105-4 (2006)
[10] K.-S. Ryu, C. Kim, C. Park, and B. S. Choi “NMR Analysis of Enzyme-catalyzed and Free-Equilibrium Mutarotation Kinetics of Monosaccharides” J. Am. Chem. Soc., 124, pp.9180-9181 (2004)
[11] C. R. MacKenzie, T. hirama, S. Deng, D. R. Bundle, S. A. Narang, and N. M. Young “Analysis by surface plasmon resonance of the influence of valence on the ligand binding affinity and kinetics of an anti-carbohydrate antibody” J. Bio. Chem., 271, pp.1527-1533 (1996)
[12] W. Kaminsky “Experimental and phenomenological aspects of circular birefringence and related properties in transparent crystal” Rep. Prog. Phys., 63, pp.1575-1640 (2000)
[13] J. A. Borgia, N. B. Malkar, H. U. Abbasi, and G. B. Fields “Difficulties encountered during glycopeptides syntheses” J. Bio, Tech., 12, pp. 44-68 (2001)
[14] C. Li, J. B. McCarthy, L. T. Furcht, and G. B. Fields “An all –D amino acid peptide model of α1(IV) 531-543 binds the α3β1 integrin” J. Biol. Chem., 36, pp.15404-15410 (1998)
[15] C. E. Lin, J. G. Chang, L. D. Chou, C. J. Yu, C. C. Lee, and C. Chou “Two-Frequency Paired Polarization Interferomet for Faraday Rotation Angle Detection” (accepted to Jpn. J. Appl. Phys.)

指導教授

李正中、周晟
(Cheng-Chung Lee、Chien Chou)

審核日期

2009-10-19

推文