132 research outputs found
THz Bursting Thresholds Measured at the Metrology Light Source
At the Metrology Light Source MLS [1] owned by the Physikalisch Technische Bundesanstalt PTB the bunch length can be varied by more than two orders of magnitude [2]. The bunch length manipulation is achieved by varying different machine parameters, such as RF voltage amplitude up to 500 kV and the momentum compaction factor amp; 945; over three orders of magnitude. The subject of this article is the measurement of THz bursting thresholds at the MLS for different bunch length
Sing to me, baby: Infants show neural tracking and rhythmic movements to live and dynamic maternal singing
Infant-directed singing has unique acoustic characteristics that may allow even very young infants to respond to the rhythms carried through the caregiver’s voice. The goal of this study was to examine neural and movement responses to live and dynamic maternal singing in 7-month-old infants and their relation to linguistic development. In total, 60 mother-infant dyads were observed during two singing conditions (playsong and lullaby). In Study 1 (n = 30), we measured infant EEG and used an encoding approach utilizing ridge regressions to measure neural tracking. In Study 2 (n =40), we coded infant rhythmic movements. In both studies, we assessed children’s vocabulary when they were 20 months old. In Study 1, we found above-threshold neural tracking of maternal singing, with superior tracking of lullabies than playsongs. We also found that the acoustic features of infant-directed singing modulated tracking. In Study 2, infants showed more rhythmic movement to playsongs than lullabies. Importantly, neural coordination (Study 1) and rhythmic movement (Study 2) to playsongs were positively related to infants’ expressive vocabulary at 20 months. These results highlight the importance of infants’ brain and movement coordination to their caregiver’s musical presentations, potentially as a function of musical variability
DEEP: A dual EEG pipeline for developmental hyperscanning studies
Cutting-edge hyperscanning methods led to a paradigm shift in social neuroscience. It allowed researchers to measure dynamic mutual alignment of neural processes between two or more individuals in naturalistic contexts. The ever-growing interest in hyperscanning research calls for the development of transparent and validated data analysis methods to further advance the field. We have developed and tested a dual electroencephalography (EEG) analysis pipeline, namely DEEP. Following the preprocessing of the data, DEEP allows users to calculate Phase Locking Values (PLVs) and cross-frequency PLVs as indices of inter-brain phase alignment of dyads as well as time-frequency responses and EEG power for each participant. The pipeline also includes scripts to control for spurious correlations. Our goal is to contribute to open and reproducible science practices by making DEEP publicly available together with an example mother-infant EEG hyperscanning dataset
DEEP: A dual EEG pipeline for developmental hyperscanning studies
Cutting-edge hyperscanning methods led to a paradigm shift in social neuroscience. It allowed researchers to measure dynamic mutual alignment of neural processes between two or more individuals in naturalistic contexts. The ever-growing interest in hyperscanning research calls for the development of transparent and validated data analysis methods to further advance the field. We have developed and tested a dual electroencephalography (EEG) analysis pipeline, namely DEEP. Following the preprocessing of the data, DEEP allows users to calculate Phase Locking Values (PLVs) and cross-frequency PLVs as indices of inter-brain phase alignment of dyads as well as time-frequency responses and EEG power for each participant. The pipeline also includes scripts to control for spurious correlations. Our goal is to contribute to open and reproducible science practices by making DEEP publicly available together with an example mother-infant EEG hyperscanning dataset
Coherent THz Measurements at the Metrology Light Source
The Metrology Light Source MLS [1] is the first storage ring optimized for THz generation [2]. It applies a bunch shortening mode, based on a flexible momentum compaction factor optics. The short bunches emit coherent THz radiation. We report on measured THz signals as a function of different machine parameters. Two type of measurements are presented in this paper. The first part presents THz bursting thresholds for a variety of ring parameters compared with theoretical predictions and similar results achieved at BESSY II. The second part discusses an example of a special machine tuning, where the coherent THz signal suddenly and unexpectedly vanishes. Some measurements are shown to demonstrate this effect, a physical explanation is missing
Compressed AFM-IR hyperspectral nanoimaging
Infrared (IR) hyperspectral imaging is a powerful approach in the field of materials and life sciences. However, for the extension to modern sub-diffraction nanoimaging it still remains a highly inefficient technique, as it acquires data via inherent sequential schemes. Here, we introduce the mathematical technique of low-rank matrix reconstruction to the sub-diffraction scheme of atomic force microscopy-based infrared spectroscopy (AFM-IR), for efficient hyperspectral IR nanoimaging. To demonstrate its application potential, we chose the trypanosomatid unicellular parasites Leishmania species as a realistic target of biological importance. The mid-IR spectral fingerprint window covering the spectral range from 1300 to 1900 cm−1 was chosen and a distance between the data points of 220 nm was used for nanoimaging of single parasites. The method of k-means cluster analysis was used for extracting the chemically distinct spatial locations. Subsequently, we randomly selected only 10% of an originally gathered data cube of 134 (x) × 50 (y) × 148 (spectral) AFM-IR measurements and completed the full data set by low-rank matrix reconstruction. This approach shows agreement in the cluster regions between full and reconstructed data cubes. Furthermore, we show that the results of the low-rank reconstruction are superior compared to alternative interpolation techniques in terms of error-metrics, cluster quality, and spectral interpretation for various subsampling ratios. We conclude that by using low-rank matrix reconstruction the data acquisition time can be reduced from more than 14 h to 1–2 h. These findings can significantly boost the practical applicability of hyperspectral nanoimaging in both academic and industrial settings involving nano- and bio-materials
Nanoscale plasmonic phenomena in CVD-grown MoS2 monolayer revealed by ultra- broadband synchrotron radiation based nano-FTIR spectroscopy and near-field microscopy
Nanoscale plasmonic phenomena observed in single and bi-layers of molybdenum
disulfide (MoS2) on silicon dioxide (SiO2) are reported. A scattering type
scanning near-field optical microscope (s-SNOM) with a broadband synchrotron
radiation (SR) infrared source was used. We also present complementary optical
mapping using tunable CO2-laser radiation. Specifically, there is a
correlation of the topography of well-defined MoS2 islands grown by chemical
vapor deposition, as determined by atomic force microscopy, with the infrared
(IR) signature of MoS2. The influence of MoS2 islands on the SiO2 phonon
resonance is discussed. The results reveal the plasmonic character of the MoS2
structures and their interaction with the SiO2 phonons leading to an
enhancement of the hybridized surface plasmon-phonon mode. A theoretical
analysis shows that, in the case of monolayer islands, the coupling of the
MoS2 optical plasmon mode to the SiO2 surface phonons does not affect the
infrared spectrum significantly. For two-layer MoS2, the coupling of the extra
inter-plane acoustic plasmon mode with the SiO2 surface transverse phonon
leads to a remarkable increase of the surface phonon peak at 794 cm−1. This is
in agreement with the experimental data. These results show the capability of
the s-SNOM technique to study local multiple excitations in complex non-
homogeneous structures
Non-thermal response of YBCO thin films to picosecond THz pulses
The photoresponse of YBa2Cu3O7-d thin film microbridges with thicknesses
between 15 and 50 nm was studied in the optical and terahertz frequency range.
The voltage transients in response to short radiation pulses were recorded in
real time with a resolution of a few tens of picoseconds. The bridges were
excited by either femtosecond pulses at a wavelength of 0.8 \mu m or broadband
(0.1 - 1.5 THz) picosecond pulses of coherent synchrotron radiation. The
transients in response to optical radiation are qualitatively well explained in
the framework of the two-temperature model with a fast component in the
picosecond range and a bolometric nanosecond component whose decay time depends
on the film thickness. The transients in the THz regime showed no bolometric
component and had amplitudes up to three orders of magnitude larger than the
two-temperature model predicts. Additionally THz-field dependent transients in
the absence of DC bias were observed. We attribute the response in the THz
regime to a rearrangement of vortices caused by high-frequency currents
Oropouche orthobunyavirus infection is mediated by the cellular host factor Lrp1
Oropouche orthobunyavirus (OROV
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