Your search keyword '"Xuan, Chuang"' showing total 4 results

1. Scanning SQUID microscope system for geological samples: system integration and initial evaluation.

Author

Oda, Hirokuni, Kawai, Jun, Miyamoto, Masakazu, Miyagi, Isoji, Sato, Masahiko, Noguchi, Atsushi, Yamamoto, Yuhji, Fujihira, Jun-ichi, Natsuhara, Nobuyoshi, Aramaki, Yoshiyasu, Masuda, Takashige, and Xuan, Chuang

Subjects

SQUID magnetometers, QUANTUM interference devices, GEOLOGICAL modeling, MAGNETIC shielding, MAGNETIC dipoles

Abstract

We have developed a high-resolution scanning superconducting quantum interference device (SQUID) microscope for imaging the magnetic field of geological samples at room temperature. In this paper, we provide details about the scanning SQUID microscope system, including the magnetically shielded box (MSB), the XYZ stage, data acquisition by the system, and initial evaluation of the system. The background noise in a two-layered PC permalloy MSB is approximately 40-50 pT. The long-term drift of the system is approximately ≥1 nT, which can be reduced by drift correction for each measurement line. The stroke of the XYZ stage is 100 mm × 100 mm with an accuracy of ~10 µm, which was confirmed by laser interferometry. A SQUID chip has a pick-up area of 200 μm × 200 μm with an inner hole of 30 μm × 30 μm. The sensitivity is 722.6 nT/V. The flux-locked loop has four gains, i.e., ×1, ×10, ×100, and ×500. An analog-to-digital converter allows analog voltage input in the range of about ±7.5 V in 0.6-mV steps. The maximum dynamic range is approximately ±5400 nT, and the minimum digitizable magnetic field is ~0.9 pT. The sensor-to-sample distance is measured with a precision line current, which gives the minimum of ~200 µm. Considering the size of pick-up coil, sensor-to-sample distance, and the accuracy of XYZ stage, spacial resolution of the system is ~200 µm. We developed the software used to measure the sensor-to-sample distance with line scan data, and the software to acquire data and control the XYZ stage for scanning. We also demonstrate the registration of the magnetic image relative to the optical image by using a pair of point sources placed on the corners of a sample holder outside of a thin section placed in the middle of the sample holder. Considering the minimum noise estimate of the current system, the theoretical detection limit of a single magnetic dipole is ~1 × 10 Am. The new instrument is a powerful tool that could be used in various applications in paleomagnetism such as ultrafine-scale magnetostratigraphy and single-crystal paleomagnetism. [ABSTRACT FROM AUTHOR]

Published

2016

2. Toward robust deconvolution of pass-through paleomagnetic measurements: new tool to estimate magnetometer sensor response and laser interferometry of sample positioning accuracy.

Author

Oda, Hirokuni, Xuan, Chuang, and Yamamoto, Yuhji

Subjects

*PALEOMAGNETISM, *MAGNETOMETERS, *LASER interferometry, *MAGNETIC properties of rocks, *DECONVOLUTION (Mathematics), *MAGNETIZATION

Abstract

Pass-through superconducting rock magnetometers (SRM) offer rapid and high-precision remanence measurements for continuous samples that are essential for modern paleomagnetism studies. However, continuous SRM measurements are inevitably smoothed and distorted due to the convolution effect of SRM sensor response. Deconvolution is necessary to restore accurate magnetization from pass-through SRM data, and robust deconvolution requires reliable estimate of SRM sensor response as well as understanding of uncertainties associated with the SRM measurement system. In this paper, we use the SRM at Kochi Core Center (KCC), Japan, as an example to introduce new tool and procedure for accurate and efficient estimate of SRM sensor response. To quantify uncertainties associated with the SRM measurement due to track positioning errors and test their effects on deconvolution, we employed laser interferometry for precise monitoring of track positions both with and without placing a u-channel sample on the SRM tray. The acquired KCC SRM sensor response shows significant cross-term of Z-axis magnetization on the X-axis pick-up coil and full widths of ~46-54 mm at half-maximum response for the three pick-up coils, which are significantly narrower than those (~73-80 mm) for the liquid He-free SRM at Oregon State University. Laser interferometry measurements on the KCC SRM tracking system indicate positioning uncertainties of ~0.1-0.2 and ~0.5 mm for tracking with and without u-channel sample on the tray, respectively. Positioning errors appear to have reproducible components of up to ~0.5 mm possibly due to patterns or damages on tray surface or rope used for the tracking system. Deconvolution of 50,000 simulated measurement data with realistic error introduced based on the position uncertainties indicates that although the SRM tracking system has recognizable positioning uncertainties, they do not significantly debilitate the use of deconvolution to accurately restore high-resolution signal. The simulated 'excursion' event associated with a significant magnetization intensity drop was clearly recovered in the deconvolved measurements with a maximum error of ~3° in inclination. [ABSTRACT FROM AUTHOR]

Published

2016

3. UDECON: deconvolution optimization software for restoring high-resolution records from pass-through paleomagnetic measurements.

Author

Xuan, Chuang and Oda, Hirokuni

Published

2015

4. Special issue "Recent advances in geo-, paleo- and rock-magnetism".

Author

Tarduno, John A., Oda, Hirokuni, Yamamoto, Yuhji, Xuan, Chuang, Lascu, Ioan, and Fukuma, Koji

Subjects

MAGNETIC declination, SUBMARINE geology, GEOLOGICAL time scales, REMANENCE, MAGNETIC anomalies, GEOMAGNETISM

Abstract

An introduction is presented in which the editor discusses the development in the field of rock magnetism, Geomagnetism and Paleomagnetism.

Published

2019