第63回 アイセムスセミナー / CeMI セミナーシリーズ 18: Charles Schmuttenmaer 教授、Juraj Darmo 教授
CeMI:Center for Meso-Bio Single-Molecule Imaging
Using Time-Resolved THz Spectroscopy to Study Carrier Dynamics in TiO2-based Nanomaterials
(Prof. Charles Schmuttenmaer)
Nanostructured TiO2 films are a promising low-cost, high-surface-area electrode material for solar cells and solar fuel production. TiO2 nanoparticles (NPs) have already proven successful as the photoanode in dye-sensitized solar cells (DSSCs). On the other hand, TiO2 nanotubes (NTs) offer the advantage of directed electron transport, and are expected to have higher electron mobility. However, to date, they have not outperformed the NPs.
Measuring the photoconductivity in these materials is a challenging problem because of the inherent difficulty of attaching wires to nanometer-sized objects. Furthermore, picosecond (ps) carrier dynamics play an important role in efficient charge separation and transport, but the low temporal resolution of traditional methods such as time-of-flight and intensity modulated photocurrent or photovoltage spectroscopy used to determine their photoconductivity precludes their use in studying sub-ps to ps dynamics.
Time-resolved THz spectroscopy (TRTS), on the other hand, is a non-contact electrical probe capable of measuring photoconductivity on a sub-ps to nanosecond (ns) timescale. In essence, materials with high conductivity strongly absorb THz radiation, while those with low conductivity do not. With THz spectroscopy, not only can the average time-dependent conductivity properties be measured, but also the complete frequency-dependent, complex-valued conductivity (i.e., real and imaginary compo¬nents), all on a sub-ps timescale, and without attaching any probe wires to the sample. The use of TRTS to study transient photoconductivity in nanocrystalline colloidal TiO2 NPs and TiO2 NTs will be discussed.
Terahertz time-domain spectroscopy of quantum cascade lasers
(Prof. Juraj Darmo)
Last five decades can be called as an era of the semiconductor laser. This device small by size, but big by performance become an inevitable part of the everyday life starting from the laser in the computer pointing device, through the lasers in the telecommunication systems, DVD players and finishing with lasers for solid-state lightning. The quantum cascade laser entered this stage in 1994 when the wavelength restriction of bulk semiconductor based laser was overcome using inter-subband transitions in the semiconductor heterostructure. Engineering of those transitions in the form of the quantum cascades (QC) has allowed reaching emission at the mid-infrared and later at the far-infrared wavelength. Major disadvantage of today´s QC laser is its low operation temperature. Therefore, current scientific effort is focused on the development of QCL with the high output power and higher operation temperature. Reaching these goals the detailed knowledge of processes in the QC laser is required. Recently, we have developed a technique to study such processes even in the lasing QCL devices.
A review of our recent work on the terahertz time-domain spectroscopy of QCL is presented with focus on the used technique itself and on the measurement of the gain and laser cavity loss. Different QC laser designs are compared with respect to the observed spectral gain bandwidth, at its dependence on the operation temperature. Such results help to identify problems of different schemes of the intersubband transition used for QC laser and enable to improve QC laser design.
| 講演者 演題 |
Charles Schmuttenmaer 教授 Department of Chemistry イェール大学 演題:Using Time-Resolved THz Spectroscopy to Study Carrier Dynamics in TiO2-based Nanomaterials Juraj Darmo 教授 Institute of Photonics ウィーン工科大学 演題:Terahertz time-domain spectroscopy of quantum cascade lasers |
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| 日時 | 2010年11月25日(木)14:00-16:00 |
| 場所 | 京都大学 アイセムス本館 2階(東一条北西角)セミナー室(A207) アクセスマップ |
| フライヤー |  PDF (140KB) |
| 主催 | 京都大学 物質-細胞統合システム拠点(iCeMS=アイセムス) |
| 連絡先 | 京都大学iCeMS 田中グループ tanaka-g@icems.kyoto-u.ac.jp |