Ding-Yin Tan scite author profile

TianQin is a planned space-based gravitational wave (GW) observatory consisting of three Earth-orbiting satellites with an orbital radius of about $10^5 \, {\rm km}$. The satellites will form an equilateral triangle constellation the plane of which is nearly perpendicular to the ecliptic plane. TianQin aims to detect GWs between $10^{-4} \, {\rm Hz}$ and $1 \, {\rm Hz}$ that can be generated by a wide variety of important astrophysical and cosmological sources, including the inspiral of Galactic ultra-compact binaries, the inspiral of stellar-mass black hole binaries, extreme mass ratio inspirals, the merger of massive black hole binaries, and possibly the energetic processes in the very early universe and exotic sources such as cosmic strings. In order to start science operations around 2035, a roadmap called the 0123 plan is being used to bring the key technologies of TianQin to maturity, supported by the construction of a series of research facilities on the ground. Two major projects of the 0123 plan are being carried out. In this process, the team has created a new-generation $17 \, {\rm cm}$ single-body hollow corner-cube retro-reflector which was launched with the QueQiao satellite on 21 May 2018; a new laser-ranging station equipped with a $1.2 \, {\rm m}$ telescope has been constructed and the station has successfully ranged to all five retro-reflectors on the Moon; and the TianQin-1 experimental satellite was launched on 20 December 2019—the first-round result shows that the satellite has exceeded all of its mission requirements.

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The first round result from the TianQin-1 satellite

Luo

Bai

Cai

et al. 2020

Class. Quantum Grav.

106

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Research and Development of Electrostatic Accelerometers for Space Science Missions at HUST

Bai

et al. 2017

Sensors

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High-precision electrostatic accelerometers have achieved remarkable success in satellite Earth gravity field recovery missions. Ultralow-noise inertial sensors play important roles in space gravitational wave detection missions such as the Laser Interferometer Space Antenna (LISA) mission, and key technologies have been verified in the LISA Pathfinder mission. Meanwhile, at Huazhong University of Science and Technology (HUST, China), a space accelerometer and inertial sensor based on capacitive sensors and the electrostatic control technique have also been studied and developed independently for more than 16 years. In this paper, we review the operational principle, application, and requirements of the electrostatic accelerometer and inertial sensor in different space missions. The development and progress of a space electrostatic accelerometer at HUST, including ground investigation and space verification are presented.

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Inside rod induced horizontal capillary emptying

et al. 2021

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Measurements of temporal and spatial variation of surface potential using a torsion pendulum and a scanning conducting probe

Yin

Bai

et al. 2014

Phys. Rev. D

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An electrostatic-controlled torsion pendulum combined with a scanning conducting probe is used to measure the temporal and spatial variations of the surface potential on test mass. The apparatus can work in static and scanning modes. Temporal variation of the surface potential can be measured with the static mode, and its voltage variation with a level of 15 μV=Hz 1=2 at 0.03 Hz has been achieved for a 5 × 5 mm 2 area. The spatial distribution of the surface potential can be measured with the scanning mode, and the surface potential distribution can be obtained at a level of 330 μV at 0.125 mm spatial resolution. The experimental results tell us that the apparatus provide a new way to investigate the charge distribution and its variation, which is very useful in helping to understand the physical mechanism of the surface charge distribution of an actual object.

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Ding-Yin Tan

The TianQin project: Current progress on science and technology

The first round result from the TianQin-1 satellite

Research and Development of Electrostatic Accelerometers for Space Science Missions at HUST

Inside rod induced horizontal capillary emptying

Measurements of temporal and spatial variation of surface potential using a torsion pendulum and a scanning conducting probe

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