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研究生: 盧姿妤
Lu, Tzu-Yu
論文名稱: 以超快時間解析光裂解光譜研究具烷基橋之電子供體-受體陽離子電荷轉移及構型緩解動力學
Studies of Ultrafast Photofragmentation Spectroscopy of Charge Transfer and Conformational Relaxation Dynamics in Electron Donor-Acceptor Cations with Alkyl Bridges
指導教授: 鄭博元
Cheng, Po-Yuan
口試委員: 曾建銘
Tseng, Chien-Ming
李以仁
Lee, I-Ren
學位類別: 碩士
Master
系所名稱: 理學院 - 化學系
Department of Chemistry
論文出版年: 2024
畢業學年度: 112
語文別: 中文
論文頁數: 184
中文關鍵詞: 飛秒脈衝雷射飛行時間質譜儀光游離-光裂解共振增益多光子游離電荷轉移氣相電子供體-受體分子系統
外文關鍵詞: femtosecond pulsed laser, time-of-flight mass spectrometer, photoionization-photofragmentation, resonance-enhanced multiphoton ionization, charge transfer, gas phase, electron donor-acceptor molecular system
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    • 我們利用飛秒激發-探測光游離光裂解結合飛行時間質譜儀測量離子損耗瞬時訊號研究MNMA (methyl[(1,2,3,4-tetrahydronaphthalen-2-yl)methyl]amine)與MPBA (methyl(4-phenylbutyl)amine) 陽離子之電荷轉移及構型緩解動力學行為。另外,我們也測量預期不發生電荷轉移的PPAL (3-phenylpropyl alcohol)陽離子以支持對MNMA與MPBA陽離子電荷轉移指認的正確性。我們首先利用波長266 nm之激發脈衝雷射以1+1共振增益多光子游離方式將分子由中性S0 state經苯環端局部游離至陽離子D1/D2 state,隨後再緩解至陽離子D0 state。在緩解過程中,我們使用波長範圍480~1500 nm之探測脈衝雷射將陽離子激發至更高能態,使陽離子裂解產生離子碎片而造成母陽離子的損耗,並測量激發與探測脈衝隨延遲時間變化之離子損耗瞬時訊號,及兩陽離子於特定延遲時間下的離子損耗率,以獲取時間解析光裂解光譜。我們接著以連續動力學模型擬合MNMA與MPBA陽離子在各探測波長的離子損耗瞬時訊號,可得到三個不同的時間常數(time constant, τ)。兩陽離子之時間常數τ1約在100~200 fs,τ2及τ3分別約10~26 ps及370~600 ps。而我們擬合出的PPAL陽離子時間常數τ1約1~2 ps,此擬合結果的數量級有明顯不同,且在PPAL的離子損耗瞬時訊號中無法測量到瞬間生成與極快速衰退的尖峰訊號,可支持我們所研究的MNMA與MPBA陽離子的緩解動力學過程包含電荷轉移行為。藉由陽離子時間解析光裂解光譜配合理論計算結果,我們指認時間常數τ1為陽離子D1/D2 state電荷轉移緩解至D0 state的過程,τ2與τ3指認為陽離子在庫侖作用力影響下緩解至較穩定構型分佈的過程,而時間常數τ2及τ3相差至少一個數量級的事實暗示了構型緩解可能經過兩個有顯著差異的能障。

    We utilized femtosecond pump-probe photoionization-photofragmentation in combination with time-of-flight mass spectrometry to measure the ion depletion transient signals to study the charge transfer (CT) and conformational relaxation dynamics of MNMA (methyl[(1,2,3,4-tetrahydronaphthalen-2-yl)methyl]amine) and MPBA (methyl(4-phenylbutyl)amine) cation. We also measured PPAL (3-phenylpropyl alcohol) cation, which is expected not to undergo CT, to support the validity of our assignment to CT signal in MNMA and MPBA cations. Firstly, we used a 266 nm excitation laser pulse to ionize the molecules from the neutral S0 state to the cationic D1/D2 state via 1+1 resonance-enhanced multiphoton ionization (REMPI). Subsequently, the D1/D2 state decay to the cationic D0 state. During the relaxation process, we used probe pulse lasers with wavelengths ranging from 480 to 1500 nm to excite the cations to higher energy states, causing ion fragmentation and resulting in the depletion of parent ions. We measured the ion depletion transient signals as a function of the pump-probe delay time as well as the cation depletion yield at specific delay times to obtain time-resolved photofragmentation spectra. Furthermore, we fitted the ion depletion transient signals of MNMA and MPBA cations at various probe wavelengths by using a consecutive kinetic model, yielding three different time constants (τ). For the two cations, the time constant τ1 is around 100-200 fs, τ2 is about 10-26 ps, and τ3 is approximately 370-600 ps. τ1 for PPAL cations was found to be around 1-2 ps, which is an order longer than those of MNMA and MPBA. Moreover, no fast rise and decay "peak signals" could be observed in the ion depletion transients of PPAL. This supports that the relaxation dynamics associated with τ1 of MNMA and MPBA cations is related to charge transfer. By combining the time-resolved photofragmentation spectra with theoretical calculations, we identified the time constant τ1 as the charge transfer relaxation process from the cationic D1/D2 state to the D0 state, and τ2 and τ3 as the relaxation processes to more stable conformation distributions driven by Coulombic interactions. The fact that τ2 and τ3 differ by at least one order of magnitude suggests that the conformational relaxation may involve two significantly different energy barriers.

    總目錄 摘要 I Abstract II 致謝 III 總目錄 IV 第一章 緒論 1 1.1 引文 1 1.2 文獻探討 3 1.3 研究動機 7 第二章 實驗系統與技術 12 2.1 飛秒激發-探測脈衝雷射技術 12 2.2 光子游離機制 14 2.3 激發-探測光譜機制 14 2.3.1 激發-探測光激發-光游離 15 2.3.2 激發-探測光游離-光裂解 15 2.4 飛秒脈衝雷射系統 16 2.4.1 振盪器系統 17 2.4.2 脈衝能量放大器 23 2.5 波長調變裝置 31 2.5.1 激發脈衝:非線性光學混頻區 31 2.5.2 探測脈衝:波長調變器TOPAS 32 2.6 分子束系統 35 2.6.1 超音速分子束系統 36 2.6.2 分子束進樣系統 39 2.6.3 分子束系統架設 40 2.7 飛行時間質譜儀 43 2.8 實驗光路架設 46 2.9 訊號擷取系統 49 2.10 儀器響應函數 51 2.11 藥品來源 52 第三章 MNMA實驗結果 53 3.1 MNMA分子質譜分析 53 3.1.1 MNMA分子光游離質譜 53 3.1.2 MNMA母離子及碎片離子訊號對激發脈衝能量之依存性 55 3.2 激發-探測光游離-光裂解實驗 57 3.2.1 激發與探測脈衝能量比例對離子瞬時訊號時間行為影響之探討 57 3.2.2 MNMA陽離子損耗訊號驗證 60 3.2.3 離子損耗率測量 63 3.2.4 離子損耗率與雷射脈衝能量相依性 65 3.3 離子損耗率與不同探測脈衝波長之能量條件 68 3.3.1 不同探測波長脈衝能量換算 68 3.3.2 離子損耗率對不同探測波長脈衝能量相關性 70 3.4 MNMA陽離子損耗瞬時訊號 76 3.4.1 短時間與極短時間尺度MNMA離子損耗瞬時訊號 77 3.4.2 中時間與長時間尺度MNMA離子損耗瞬時訊號 80 3.5 MNMA離子損耗瞬時訊號之連續動力學模型擬合 85 3.6 超快時間解析MNMA陽離子光裂解光譜 94 第四章 MPBA分子與PPAL分子實驗結果 102 4.1 MPBA分子質譜分析 102 4.1.1 MPBA分子光游離質譜 102 4.1.2 MPBA母離子及碎片離子訊號對激發脈衝能量之依存性 104 4.2 MPBA離子損耗瞬時訊號 106 4.2.1 MPBA 陽離子各時間尺度損耗瞬時訊號 106 4.2.2 MPBA離子損耗瞬時訊號之連續動力學模型擬合 110 4.3 超快時間解析MPBA陽離子光裂解光譜 114 4.4 無電荷轉移PPAL離子對照組實驗 117 4.4.1 PPAL分子之光游離質譜 118 4.4.2 超快時間解析PPAL陽離子光裂解光譜 119 4.4.3 PPAL分子之光游離-光裂解離子損耗瞬時訊號 120 4.4.4 PPAL離子損耗瞬時訊號之連續動力學模型擬合 123 第五章 理論計算與結果討論 128 5.1 MNMA分子計算結果與討論 128 5.1.1 MNMA 中性S0 state 128 5.1.2 MNMA 陽離子D0 state 135 5.2 MPBA分子計算結果與討論 141 5.2.1 MPBA 中性S0 state 141 5.2.2 MPBA 陽離子D0 state 148 第六章 結論 154 參考文獻 157 附錄 160 附錄I MNMA分子以連續動力學模型擬合結果 160 附錄II MNMA分子在中性S0 state各構型結構圖 168 附錄III MNMA分子在中性S0 state計算結果 170 附錄IV MNMA陽離子在D0 state各構型結構圖 174 附錄V MNMA分子在陽離子D0 state計算結果 175 附錄VI MPBA分子在中性S0 state各構型結構圖 176 附錄VII MPBA分子在中性S0 state分子計算結果 177 附錄VIII MPBA陽離子在D0 state各構型結構圖 184

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