研究業績リスト
132. |
Record-Breaking Far-Red Silicon Quantum Dots LEDs Enabled by Solvent Engineering: Toward Superseding Perovskite Quantum Dots Li Wang, Yuto Wada, Honoka Ueda, Temmaru Hirota, Kota Sumida, Yuito Oba, Ken-ichi Saitow Small Science 5, 2400647 (2025). | 131. |
世界初、水素の高効率製造法!高温・巨大施設での製法が、室温・実験室でも可能に 齋藤健一 Ceramics Japan,印刷中(2025) |
130. |
高効率発光するシリコン量子ドットの開発 -合成・光物性・塗布型LED- 齋藤健一 量子ドット技術の最前線,エヌティーエス, 印刷中(2025). |
129. |
Room-temperature thermochemical water splitting: efficient mechanocatalytic hydrogen production
T. Yamamoto, S. Ashida, N. Inubuse, S. Shimizu, Y. Miura, T. Mizutani, K. Saitow J. Mater. Chem. A, 12, 30906-30918 (2024) | 128. |
Ligand Stabilities and Reactivities of Green Photoluminescent Silicon Quantum Dots: Positive Aging in Solution
N. Jingu, K. Sumida, T. Hayakawa, T. Ono, K. Saitow Chem. Mater 36, 10, 5077–5091 (2024) | 127. |
高発光シリコン量子ドット蛍光体 -合成法の開発と塗布型LEDの開発- 齋藤健一 次世代蛍光体材料の開発 (Invited article) シーエムシー出版 pp 37-50. (2024). |
126. |
もみ殻を原料にした量子ドットLED 齋藤健一 アグリバイオ (Invited article) 8, 421-423 (2024). |
125. |
シリコン量子ドット前駆体、シリコン量子ドット、シリコン量子ドットLEDの製造 齋藤健一 クリーンテクノロジー (Invited article) 34(5),66-73 (2024). |
124. |
1D, 2D, and 3D Mapping of Plasmon and Mie Resonances: A Review of Field Enhancement Imaging Based on Electron or Photon Spectromicroscopy
K. Saitow J. Phys. Chem. C (Invited article) ,128, 13, 5367–5393(2024) | 123. |
シリコン量子ドットの合成とLEDへの利用 齋藤健一 粉体技術 (Invited article) 165, 25-32 (2024). |
122. |
Bright Silicon Quantum Dot Synthesis and LED Design: Insights into Size–Ligand–Property Relationships from Slow- and Fast-band Engineering K. Saitow Bull. Chem. Soc. Jpn (Invited article) , 97, uoad002 (2024). Inside Coverに掲載されました!(クリックで表示) |
121. |
Cost-Effective Ultra-Bright Silicon Quantum Dots and Highly Efficient LEDs from Low-Carbon Hydrogen Silsesquioxane Polymer H. Ueda, K. Saitow ACS. Appl. Mater. Interfaces,16,1,985-997 (2024) | 120. |
Mechanochemically Tailored Silicon Particles for Efficient H2 Production: Entropy and Enthalpy Engineering T. Mizutani, H. Ohta, T. Ueda, T. Kashiwagi, T. Fukuda, T. Shiobara, K. Saitow ACS Sustainable Chem. Eng. ,11,32,11769-11780 (2023) | 119. |
Large-Area Plasmon Mapping via an Optical Technique: Silver Nanohole Array and Nano-Sawtooth Structures M. Sakamoto, K. Saitow J. Phys. Chem. C ,127,27,13105-13111(2023) Cover Pictureに掲載されました!(クリックで表示) |
118. |
Lanthanide and Actinide Ion Complexes Containing Organic Ligands Investigated by Surface-Enhanced Infrared Absorption Spectroscopy S. Hirata, R. Kusaka, S. Meiji, S. Tamekuni, K. Okudera, S. Hamada, C. Sakamoto, T. Honda, K. Matsushita, S. Muramatsu, T. Ebata, D. Kajiya, K. Saitow, T. Ikeda, T. Hirao, T. Haino, M. Watanabe, Y. Inokuchi Inorg. Chem. ,62, 1, 474-486(2023). Cover Pictureに掲載されました!(クリックで表示) |
117. |
Near-Room-Temperature Synthesis of Alkoxysilanes and H2 via Mechanochemical Ball Milling Y. Miura, T Kashiwagi, T. Fukuda, A. Shichiri, T. Shiobara, K. Saitow ACS Sustainable Chem. Eng., 10, 49, 16159-16168 (2022). Cover Pictureに掲載されました!(クリックで表示) |
116. |
Stability of Silicon Quantum Dots Against Solar Light/Hot Water: RGB Foldable Films and Ligand Engineering K. Fujimoto, T. Hayakawa, Y. Xu, N. Jingu, K. Saitow ACS Sustainable Chem. Eng., 10, 44, 14451-14463 (2022). |
115. |
Cellulose Templating for π-Conjugated Polymer Orientation: An In Situ Time-Resolved Spectroscopy Exploration T. Sakata, T. Hirota, K. Saitow ACS Appl. Polym. Mater., 4, 11, 8166-8179 (2022). Cover Pictureに掲載されました!(クリックで表示) |
114. |
もみ殻を原料にした量子ドットLEDの開発 齋藤健一 NEW GLASS Vol 37, No2 (2022). |
113. |
Ligand Effects on Photoluminescence and Electroluminescence of Silicon Quantum Dots for Light-Emitting Diodes Y. Xu, S. Terada, Y. Xin, H. Ueda, and K. Saitow ACS Appl. Nano Mater., 5, 7787−7797 (2022). Cover Pictureに掲載されました!(クリックで表示) |
112. |
Fast, Economical, and Reproducible Sensing from a 2D Si Wire Array: Accurate Characterization by Single Wire Spectroscopy Masanori Sakamoto and Ken-ichi Saitow Anal. Chem., 18, 6672–6680 (2022). Cover Pictureに掲載されました!(クリックで表示) |
111. |
Orange–Red Si Quantum Dot LEDs from Recycled Rice Husks S. Terada, H. Ueda, T. Ono, K. Saitow ACS Sustainable Chem. Eng., 10, 1765–1776 (2022). Cover Pictureに掲載されました!(クリックで表示) |
110. |
Cellulose-Templated Stable Foldable Oriented Films with Polarized RGB Luminescence M. Takamatsu, T. Sakata, D. Kajiya, K. Saitow Chem. Mater., 34, 1052–1064 (2022). Cover Pictureに掲載されました!(クリックで表示) |
109. |
4D Microspectroscopy Explores Orientation and Aggregations in π-Conjugated Polymer Films Prepared by Brush Printing T. Sakata, K. Saitow J. Phys. Chem. Lett, 13, 653–660 (2022). Cover Pictureに掲載されました!(クリックで表示) |
108. |
Designing Efficient Si Quantum Dots and LEDs by Quantifying Ligand Effects T. Ono, Y. Xu, T. Sakata, K. Saitow ACS Appl. Mater. Interfaces, 14, 1373–1388 (2022). |
107. |
半導体ナノ構造による光の増強とその可視化: もみ殻, 酸化チタン, 2D-TMDCsまで 齋藤健一 日本化学会 低次元光機能材料研究会 ニュースレター第25号, 6-8 (2021). | 106. |
破壊から創造する化学-メカノケミストリーの著しい進展 三浦結衣,齋藤健一 化学 76(8), 70-71, 2021. | 105. |
光の強度を2,000倍に増強する酸化チタンの開発 齋藤健一 クリーンエネルギー 30, 16-20, 2021. 日本工業出版 |
104. |
Large Field Enhancement of Nanocoral Structures on Porous Si Synthesized from Rice Husks M. Sakamoto, S. Terada, T. Mizutani, K. Saitow ACS. Appl. Mater. Interfaces, 13, 1105–1113 (2021). Cover Pictureに掲載されました!(クリックで表示) |
103. |
Mechanochemical Synthesis of Red-Light-Active Green TiO2 Photocatalysis with disorder: Defect-Rich, with Polymorphs, and No Metal Loading Y. Wang, K. Saitow Chem. Mater., 32, 9190-9200 (2020). |
102. |
Cost-Effective Synthesis of Silicon Quantum Dots S. Terada, Y. Xin, K. Saitow Chem. Mater., 32, 8382-8392 (2020). |
101. |
Nanogap-Rich TiO2 Film for 2000-Fold Field Enhancement with High Reproductivity K. Hanatani, K. Yoshihara, M. Sakamoto, K. Saitow J.Phys. Chem. Lett., 11, 8799-8809 (2020). Cover Pictureに掲載されました!(クリックで表示) |
100. |
Brush-printing Creates Polarized Green Fluorescence: 3D Orientation Mapping and stochastic Analysis of Conductive Polymer film T. Sakata, D. Kajiya, K. Saitow ACS Appl. Mater. Interfaces, 12, 46598-46608 (2020). Cover Pictureに掲載されました!(クリックで表示) |
99. |
超臨界流体の構造・機能から量子ドットLEDへ 齋藤健一 (Invited article) 応用物理, 89, 13-19 (2020). |
98. |
1% Defect Enriches MoS2 Quantum Dot: Catalysis and Blue Luminescence J. Tang, M. Sakamoto, H. Ohta, K. Saitow Nanoscale, 12, 4352-4358 (2020). Backside coverに掲載されました!(クリックで表示) |
97. |
Spectral Visualization of Near Infrared Enhancement in 2D Layered WS2 M. Sakamoto, K. Hanatani, K. Saitow ACS Appl. Electron. Mater, 2, 437-446 (2020). |
96. |
Size-selected Submicron Gold Spheres: Controlled Assembly onto Metal, Carbon, and Plastic Substrates K. Saitow, Y. Okamoto, H. Suemori ACS Omega, 4, 14307-14311 (2019). |
95. |
Performance of Si/PEDOT:PSS solar cell controlled by dipole moment of additives T. Sakata, N. Ikeda, T. Koganezawa, D. Kajiya, K. Saitow J. Phys. Chem. C, 123, 20130-20135 (2019). Cover Pictureに掲載されました!(クリックで表示) |
94. |
酸化チタンによる巨大な光散乱 -500倍の増強効果- 齋藤健一,坂本全教,吉原久未 FCレポート, 37, 86-90 (2019). |
93. |
Si Nanocrystal Solution Stable for One Year D. Kajiya and K. Saitow RSC Adv., 8, 41299 (2018). |
92. |
Ultrapure Films of Polythiophene Derivatives are Born on a Substrate by Liquid Flow D. Kajiya and K. Saitow ACS Appl. Energy Mater., 1, 6881 (2018). |
91. |
Field enhancement of MoS2: visualization of enhancement and effect of the number of layers M. Sakamoto, K. Saitow Nanoscale, 10, 22215 (2018). Backside coverに掲載されました!(クリックで表示) |
90. |
Extraordinary field enhancement of TiO2 porous layer up to 500-fold K. Yoshihara, H. Tamamitsu, M. Sakamoto, M. Arakawa and K. Saitow Advanced Optical Materials, 6, 1800462 (2018). |
89. |
Mechano-synthesized orange TiO2 shows significant photocatalysis under visible light K. Saitow, Y. Wang and S. Takahashi Scientific Reports, 8, 15549 (2018). |
88. |
Comparison of picosecond and nanosecond lasers for the synthesis of TiN sub-micrometer spherical particles by pulsed laser melting in liquid S. Sakaki, K. Saitow, M. Sakamoto, H. Wada, Z. Swiatkowska-Warkocka, Y. Ishikawa and N. Koshizaki Appl. Phys. Express, 11, 035001 (2018). |
87. |
量子ドットLED,「ディスプレイ・照明・バイオ応用から太陽電池まで 量子ドット材料の技術と応用展開」 齋藤健一 情報機構, pp147-162 (2017) |
86. |
Uniaxial Orientation of P3HT Film Prepared by Soft Friction Transfer Method M. Imanishi, D. Kajiya, T. Koganezawa, K. Saitow Scientific Reports, 7, 5141 (2017). |
85. |
Solvent dependence of laser-synthesized blue-emitting Si nanoparticles: size, quantum yield, and aging performance Y. Xin, T. Kitasako, M. Maeda, and K. Saitow, Chemical Physics Letters, 674, 90-97 (2017). |
84. |
Synthesis of size-controlled luminescent Si nanocrystals from (HSiO1.5)n polymers Y. Xin, R. Wakimoto, and K. Saitow Chemistry Letters, 46, 699-702 (2017). |
83. |
超臨界状態を利用したレーザによるナノ粒子合成と光電変換デバイスへの応用 齋藤健一(Invited review) レーザ加工学会誌,24, 24 (2017). |
82. |
Significant difference in the attractive energies of ethane and ethanol in supercritical CO2 D. Kajiya and K. Saitow The Journal of Supercritical Fluids, 120, 328-334 (2017). |
81. |
Enhancement of Out-of-plane Mobilities of Three Poly(3-alkylthiophene)s and Associated Mechanism D. Kajiya, T. Koganezawa, K. Saitow J. Phys. Chem. C, 120, 23351-23357 (2016) |
80. |
Performance of Si/PEDOT:PSS hybrid solar cell controlled by PEDOT:PSS film nanostructure N. Ikeda, T. Koganezawa, D. Kajiya and K. Saitow J. Phys. Chem. C, 120, 19043-19048 (2016) |
79. |
Enhancements of Out-of-plane Mobility in P3HT Film: Face-on Orientation Produced by Rubbing Daisuke Kajiya, Tomoyuki Koganezawa, Ken-ichi Saitow SPring-8/SACLA Research Frontiers 2015, 116-117 (2016). |
78. |
レーザー照射によるナノ粒子生成:光電変換デバイスへの活用 齋藤健一 (Invited review) Colloid and Interface Communication,41, 15-17 (2016). |
77. |
Solvation of Esters and Ketones in Supercritical CO2 D. Kajiya, M. Imanishi, K. Saitow J. Phys. Chem. B, 120, 785-792 (2016). |
76. |
Enhancement of out-of-plane mobility in P3HT film: Face-on orientation produced by rubbing D. Kajiya, T. Koganezawa, and K. Saitow J. Phys. Chem. C, 119, pp 7987-7995 (2015). |
75. |
Hole mobility enhancement of MEH-PPV film by heat treatment at Tg D. Kajiya, T. Koganezawa, K. Saitow AIP Adv., 5, 127130/1-127130/7 (2015). |
74. |
分子を並べた有機太陽電池 加治屋大介 化学, 70, 59-60 (2015). |
73. |
Si-Nanocrystal/P3HT Hybrid Film with 50- and 12Fold enhancement of hole mobility and density:films prepared by successive drop casting D. Kajiya and K. Saitow Nanoscale 7, 15780-15788 (2015). |
72. |
“溶液の乾燥で分子を並べる” 加治屋大介,齋藤健一 化学と工業, 68(7), p613 (2015). |
71. |
White-blue electroluminescence from a Si quantum dot hybrid LED Y. Xin, K. Nishio, and K. Saitow Applied Physics Letters, 106, 201102 (2015). |
70. |
超臨界流体の局所構造とナノ物質生成 齋藤健一(invited article) 高圧力の科学と技術, 25, 215-224 (2015). |
69. |
Enhancement of out-of-plane mobility in P3HT film by rubbing: aggregation and planarity enhanced with low regioregularity D. Kajiya, S. Ozawa, T. Koganezawa, and K. Saitow The Journal of Physical Chemistry C, 119, 7987-7995 (2015). |
68. |
メカノケミカル法によるTiO2微粒子の作製と光触媒能の著しい増加 齋藤健一(invited article) クリーンテクノロジー, 25(5), 58-63 (2015). |
67. |
Enhancement of fluorescence intensity by silicon particles and its size effect K. Saitow, H. Suemori, and H. Tamamitsu Chemical Communications 50, 1137 - 1140 (2014). |
66. |
Local enhancement effect in the photoluminescence intensity of Si quantum dots: single Medusa-type particles investigated by in situ microscope spectrometer H. Tamamitsu and K. Saitow Chemical Physics Letters 591, 37-42 (2014). |
65. |
Si quantum dots with a high absorption coefficient: analysis based on both intensive and extensive variables T. Kikasako and K. Saitow Applied Physics Letters 103, 151912 (2013). |
64. |
One-pot facile synthesis of concentrated Si nanoparticles solution H. Sun, S. Miyazaki, H. Tamamitsu, and K. Saitow Chemical Communications 49, 10302-10304 (2013). |
63. |
Investigation of attractive and repulsive interactions associated with ketones in supercritical CO2, based on Raman spectroscopy and theoretical calculations D. Kajiya and K. Saitow The Journal of Chemical Physics 139, 054509 (2013). |
62. |
130-fold Enhancement of TiO2 Photocatalytic Activities by Ball Milling K. Saitow and T. Wakamiya Applied Physics Letters 103, 031916 (2013). |
61. |
Fractal of Gold Nanoparticle Controlled by Ambient Dielectricity: Synthesis by Laser Ablation as a Function of Permittivity K. Saitow, Y. Okamoto, and Y. F. Yano The Journal of Physical Chemistry C 116, 17252-17258 (2012). |
60. |
In situ Multipurpose Time-resolved Spectrometer for Monitoring Nanoparticle Generation in a High-pressure Fluid. S. Wei and K. Saitow Review of Scientific Instruments 83, 073110(8page) (2012). |
59. |
White-Light-Emitting Silicon Nanocrystal Generated by Pulsed Laser Ablation in supercritical Fluid:Investigation of Spectral Components as a Function of Excitation Wavelengths and Aging Time S. Wei, T. Yamamura, D. Kajiya, and K. Saitow The Journal of Physical Chemistry C 116, 3928-3934 (2012). |
58. |
Chapter 12, Nanoparticle Generation by Laser Ablation in Liquid and Supercritical Fluid Ken-ichi Saitow (Invited article) Laser Ablation in Liquid: Principles and Applications in the Preparation of Nanomaterials Pan Stanford publishing, Singapore, (2012). |
57. |
Significant Substitution Effect in Dipolar and Non-dipolar Supercritical Fluids D. Kajiya and K. Saitow The Journal of Chemical Physics 134, 234508 (2011). |
56. |
Phenyl Group Leads to Greater Attractive Energy than Chloro Group in Supercritical fluids: Site Selective Solvation Observed by Raman Spectroscopy D. Kajiya and K. Saitow The Journal of Physical Chemistry B 114, 16832-16837 (2010). |
55. |
光機能性ナノ粒子の創製 - 極限反応場でのレーザ生成法 - 齋藤健一 (Invited article) 化学工業 特集 未来社会を支える技術戦略 61, 615-621 (2010). |
54. |
超臨界流体中でのパルスレーザアブレーションによる光機能性ナノ構造体の創製 齋藤健一 (Invited article) プラズマ・核融合学会誌「超臨界流体プラズマの基礎と応用」 86, 328-332 (2010). |
53. |
Solute-solvent intermolecular interaction in supercritical Xe, SF6, CO2, and CHF3 investigated by Raman spectroscopy. |
52. |
超臨界流体中でのパルスレーザアブレーションによる機能性ナノ構造体の創製 |
51. |
光の三原色で発光するシリコンナノ結晶 |
50. |
フルカラーで発光するシリコンナノ結晶 |
49. |
Solvation Structures of cis- and trans-1,2-Dichloroethylene in Supercritical CO2 - |
48. |
Spectrum of Excess Partial Molar Absorptivity. I : Near Infrared Spectroscopic Study of Aqueous Acetonitrile and Acetone |
47. |
Effective Cooling Generates Efficient Emission: Blue, Green, and Red Light-emitting Si Nanocrystals |
46. |
Gold Nanospheres and Nanonecklaces Generated by Laser Ablation in Supercritical Fluid |
45. |
Difference of Solute-Solvent Interactions of cis- and trans-1,2-Dichloroethylene in Supercritical CO2 Investigated by Raman Spectroscopy |
44. |
Photodissociation of CH2I2 and subsequent electron transfer in solution K. Saitow, Y. Naitoh, K. Tominaga, and K. Yoshihara Chemistry - An Asian Journal 3, 696-709 (2008). |
43. |
並進・回転・振動運動から眺めた超臨界流体の局所構造 |
42. |
Development of polarized Raman spectrometer for supercritical fluids having high critical points |
41. |
Attractive and repulsive interactions among methanol molecules in supercritical state investigated by Raman spectroscopy and perturbed hard-sphere theory |
40. |
Silicon Nanoclusters Selectively Generated by Laser Ablation in Supercritical Fluid |
39. |
Attractive and repulsive interactions among methanol molecules in supercritical state investigated by Raman spectroscopy and perturbed hard-sphere theory |
38. |
Time Evolution of Density Fluctuation in Supercritical Region. I. Non-hydrogen Bonded Fluids Studied by Dynamic Light Scattering |
37. |
Time Evolution of Density Fluctuation in Supercritical Region: II. Comparison of Hydrogen- and Nonhydrogen-Bonded Fluids |
36. |
Attractive and Repulsive Intermolecular Interactions of a Polar molecule: Short-range Structure of Neat Supercritical CHF3 Investigated by Raman Spectroscopy |
35. |
Dynamics of Density Fluctuation of Supercritical Fluid Mapped on Phase Diagram |
34. |
Photo-triggered Supramolecular Synthesis of Discrete Hydrogen-bonded Self-assembly Composed of Azobenzene-appended Melamine and Barbiturate |
33. |
How are Hydrogen Bonds Perturbed in Aqueous NaClO4 Solution Depending on the Concentration: A near Infrared Study of Water |
32. |
Local Density Enhancement in Neat Supercritical Fluid due to Attractive Intermolecular Interaction |
31. |
Static Inhomogeneity of Supercritical Ethylene Studied by Small-Angle X-ray Scattering |
30. |
Correlation Time of Density Fluctuation for Supercritical Ethylene Studied by Dynamic Light Scattering K. Saitow, H. Ochiai, T. Kato, and K. Nishikawa The Journal of Chemical Physics 116, 4985-4992 (2002). |
29. |
フェムト秒領域でのヨウ素分子の回転異方性 ‐強光子場における新たな展開- |
28. |
Application of High Average-power THz Radiation to Measure Far Infrared Absorption Spectrum of Supercritical Fluid |
27. |
Nanosecond Photo-fusion of Microcrystals on a Polymer Film Observed with Time-resolved Ultramicroscopy K. Saitow, H. Banjo, N. Ichinose, S. Kawanishi, H. Masuhara, and H. Fukumura Journal of Photochemistry and Photobiology A 145, 159-164 (2001). |
26. |
ゆらぎから見た超臨界流体 |
25. |
Terahertz Absorption Spectra of Supercritical CHF3 to Investigate Local Structure through Rotational and Hindered Rotational Motions |
24. |
Spectroscopic Application of THz Radiation Generated by Ultrafast Pulses -Static Far Infrared Absorption Measurements in Condensed Phase- |
23. |
Terahertz Absorption Spectra of Supercritical Fluids |
22. |
THz Absorption Spectra of Supercritical Fluids and Rotational Dynamics Analyzed by Time Correlation Functions |
21. |
Short-range Inhomogeneity of Neat Supercritical CHF3 Studied by Terahertz Absorption and Spontaneous Raman Spectroscopies |
20. |
Supercritical Fluids Studied by Teraherz Absorption Spectroscopy |
19. |
Behavior of Fermi Dyad of Carbon Dioxide in Supercritical State and the Intermolecular Interaction |
18. |
Raman Spectral Changes of Neat CO2 across the Ridge of Density Fluctuation in Supercritical Region H. Nakayama, K. Saitow, M. Sakashita, K. Ishii and K. Nishikawa Chemical Physics Letters 320, 323-327 (2000). |
17. |
超短パルス発生 -フェムト秒からアト秒への突入- |
16. |
Study of Inhomogeneity of Supercritical Water by Small-angle X-ray Scattering |
15. |
Supercritical-Fluid Cell with Device of Variable Optical Path Length Giving Fringe-Free Terahertz Spectra |
14. |
Phase Baudary in Supercritical Region |
13. |
Effects of Hydrogen Bonding on Laser-Induced Transfer of 1-Pyrenebutyric Acid in Solid Polymers |
12. |
Photodissociation of CH2I2 and the Subsequent Electron Transfer in Its Cluster Formed in Solution |
11. |
The Solute Concentration Dependence of Charge Transfer Complex Formation via Photodissociation of CH2I2 in solution |
10. |
Formation of Benzene Dimer Cations in Neat Liquid Benzene |
09. |
Formation of Benzene Dimer Cations in Neat Liquid Benzene Studied by Femtosecond Transient Absorption Spectroscopy |
08. |
Solute Clusterization Induces Specific Reaction in Solution: An Ultrafast Spectroscopic Evidence |
07. |
Photo-induced Reactions of CH2I2 in Solution Studied by the Ultrafast Transient Absorption Spectroscopy |
06. |
Photochemical Hydrogen Abstraction in Benzophenone Single Crystal |
05. |
Photo-induced Reactions of CH2I2 in Solution Studied by the Ultrafast Transient Absorption Spectroscopy |
04. |
Ultrafast Dynamics of Photoexcited Trans1,3,5-Hexatrien in Solution by Femtosecond Transient Absorption Spectroscopy |
03. |
Formation of Benzene Dimer Cations in Neat Liquid Benzene Studied by Femtosecond Transient Absorption Spectroscopy |
02. |
Photochemical Hydrogen Abstraction in Benzophenone Single Crystal |
01. |
Triplet Exciton Abstracts Hydrogen from Diphenylmethane Doped in Benzophenone Crystal |