We investigate the charge transport in nickel-titanium (Ni-Ti) alloy thin films using terahertz (THz) transmission
spectroscopy. Ni-Ti alloys have peculiar mechanical properties such as shape memory effects. Electrical conductivity
can be a good measure to characterize the alloy phase transitions, yet the carrier transport properties of this material are
relatively unexplored in the thin film regime. We grew 60-80-nm Ni-Ti alloy films of various Ti concentrations (0-
100%) on intrinsic Si substrates by Ar plasma sputtering. We carried out THz transmission spectroscopy of the samples
using broadband THz pulses. The broadband THz pulses were generated by optical rectification of femtosecond laser
pulses in a 1-mm ZnTe crystal. The light source was a 1-kHz Ti:sapphire amplifier producing 800-nm femtosecond
pulses (pulse energy, 1 mJ; pulse duration, 90 fs). The transmitted THz pulses were measured by either a L-He-cooled
Si:Bolometer (sensitive to time-averaged THz power) or by electro-optic (EO) sampling using a 1-mm ZnTe crystal.
Analyzing the power transmission data and the transmitted waveforms, we obtained the alloy resistivity as a function of
Ti concentration. Sharp changes in the resistivity were observed at the Ti fractions of 22%, 44% and 62%, indicating that
structural disorder is greatly enhanced when the alloy undergoes a phase transition.
We demonstrate THz imaging and time-domain spectroscopy of a single-layer graphene film. The large-area graphene
was grown by chemical vapor deposition on Cu-foil and subsequently transferred to a Si substrate. We took a
transmission image of the graphene/Si sample measured by a Si:bolometer (pixel size is 0.4-mm). The graphene film
(transmission: 36 - 41%) is clearly resolved against the background of the Si substrate (average transmission: 56.6%).
The strong THz absorption by the graphene layer indicates that THz carrier dynamics are dominated by intraband
transitions. A theoretical analysis based on the Fresnel coefficients for a metallic thin film shows that the local sheet
resistance varies across the sample from 420 to 590 Ohm, consistent with electron mobility ~ 3,000 cm2V-1s-1. We also
measured time-resolved THz waveforms through the Si substrate and the graphene/Si sample. The waveforms consist of
a series of single-cycle THz pulses: a directly transmitted pulse, then subsequent "echos" corresponding to multiple
reflections from the substrate. The amplitude difference between graphene/Si pulses and Si pulses becomes more
pronounced as the pulses undergo more reflections. From these measurements, we obtained spectrally flat transmission
spectra of the transmitted pulses and the average sheet resistance 480 Ohm, consistent with the results of the power
transmission measurement. The flat spectral responses indicate that the carrier scattering time in our graphene sample is
much shorter than the THz pulse duration.
Strong exciton-photon coupling in a high-Q microcavity leads to the formation of two new eigenstates, called excitonpolaritons.
We present the quantum dynamics of exciton-polaritons driven by strong few-cycle THz pulses. Our study
focuses on an intriguing question of how THz radiation interacts with the strongly coupled light-matter system. We
performed THz-pump and optical-probe experiments to answer the question: we observed the time-resolved optical
reflectivity of the lower and higher exciton-polariton (LEP and HEP) modes in a QW microcavity in the presence of
strong few-cycle THz pulses. In a previous study with a bare QW, a strong THz field tuned to the 1s-to-2p intraexciton
transition induced an excitonic Rabi splitting. Since THz radiation interacts only with the excitonic components of
exciton-polaritons and has no impact on cavity modes, it is an interesting question how THz radiation drives the excitonpolariton
states to higher energy states in the microcavity system. Our study shows that THz radiation resonantly drives
the exciton-polariton polarizations giving rise to LEP-to-2p or HEP-to-2p transitions. LEP-to-HEP transition is
forbidden because they have the same symmetry. Our experimental and theoretical investigations demonstrate that LEP,
HEP, and 2p-exciton states form a three-level Λ system in an optically excited QW microcavity.
The exciton binding energy in GaAs-based quantum-well (QW) structures is in the range of ~10 meV, which falls in the
THz regime. We have conducted a time-resolved study to observe the resonant interactions of strong narrowband THz
pulses with coherent excitons in QWs, where the THz radiation is tuned near the 1s-2p intraexciton transition and the
THz pulse duration (~3 ps) is comparable with the exciton dephasing time. The system of interest contains ten highquality
12-nm-wide GaAs QWs separated by 16-nm-wide Al 0.3Ga 0.7As barriers. The strong and narrowband THz pulses
were generated by two linearly-chirped and orthogonally-polarized optical pulses via type-II difference-frequency
generation in a 1-mm ZnTe crystal. The peak amplitude of the THz fields reached ~10 kV/cm. The strong THz fields
coupled the 1s and 2p exciton states, producing nonstationary dressed states. An ultrafast optical probe was employed to
observe the time-evolution of the dressed states of the 1s exciton level. The experimental observations show clear signs
of strong coupling between THz light and excitons and subsequent ultrafast dynamics of excitonic quantum coherence.
As a consequence, we demonstrate frequency conversion between optical and THz pulses induced by nonlinear
interactions of the THz pulses with excitons in semiconductor QWs.
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