Your search keyword '"Zi T. -G."' showing total 2 results

1. The TianQin project: Current progress on science and technology

Author

Mei, J, Bai, Y, Bao, J, Barausse, E, Cai, L, Canuto, E, Cao, B, Chen, W, Chen, Y, Ding, Y, Duan, H, Fan, H, Feng, W, Fu, H, Gao, Q, Gao, T, Gong, Y, Gou, X, Gu, C, Gu, D, He, Z, Hendry, M, Hong, W, Hu, X, Hu, Y, Huang, S, Huang, X, Jiang, Q, Jiang, Y, Jiang, Z, Jin, H, Korol, V, Li, H, Li, M, Li, P, Li, R, Li, Y, Li, Z, Liang, Y, Liang, Z, Liao, F, Liu, Q, Liu, S, Liu, Y, Liu, L, Liu, P, Liu, X, Lu, X, Lu, Y, Lu, Z, Luo, Y, Luo, Z, Milyukov, V, Ming, M, Pi, X, Qin, C, Qu, S, Sesana, A, Shao, C, Shi, C, Su, W, Tan, D, Tan, Y, Tan, Z, Tu, L, Wang, B, Wang, C, Wang, F, Wang, G, Wang, H, Wang, J, Wang, L, Wang, P, Wang, X, Wang, Y, Wei, R, Wu, S, Xiao, C, Xu, X, Xue, C, Yang, F, Yang, L, Yang, M, Yang, S, Ye, B, Yeh, H, Yu, S, Zhai, D, Zhang, C, Zhang, H, Zhang, J, Zhang, L, Zhang, X, Zhou, H, Zhou, M, Zhou, Z, Zhu, D, Zi, T, Luo, J, Mei J., Bai Y. -Z., Bao J., Barausse E., Cai L., Canuto E., Cao B., Chen W. -M., Chen Y., DIng Y. -W., Duan H. -Z., Fan H., Feng W. -F., Fu H., Gao Q., Gao T., Gong Y., Gou X., Gu C. -Z., Gu D. -F., He Z. -Q., Hendry M., Hong W., Hu X. -C., Hu Y. -M., Hu Y., Huang S. -J., Huang X. -Q., Jiang Q., Jiang Y. -Z., Jiang Y., Jiang Z., Jin H. -M., Korol V., Li H. -Y., Li M., Li P., Li R., Li Y., Li Z., Li Z. -X., Liang Y. -R., Liang Z. -C., Liao F. -J., Liu Q., Liu S., Liu Y. -C., Liu L., Liu P. -B., Liu X., Liu Y., Lu X. -F., Lu Y., Lu Z. -H., Luo Y., Luo Z. -C., Milyukov V., Ming M., Pi X., Qin C., Qu S. -B., Sesana A., Shao C., Shi C., Su W., Tan D. -Y., Tan Y., Tan Z., Tu L. -C., Wang B., Wang C. -R., Wang F., Wang G. -F., Wang H., Wang J., Wang L., Wang P., Wang X., Wang Y., Wang Y. -F., Wei R., Wu S. -C., Xiao C. -Y., Xu X. -S., Xue C., Yang F. -C., Yang L., Yang M. -L., Yang S. -Q., Ye B., Yeh H. -C., Yu S., Zhai D., Zhang C., Zhang H., Zhang J. -D., Zhang J., Zhang L., Zhang X., Zhou H., Zhou M. -Y., Zhou Z. -B., Zhu D. -D., Zi T. -G., Luo J., Mei, J, Bai, Y, Bao, J, Barausse, E, Cai, L, Canuto, E, Cao, B, Chen, W, Chen, Y, Ding, Y, Duan, H, Fan, H, Feng, W, Fu, H, Gao, Q, Gao, T, Gong, Y, Gou, X, Gu, C, Gu, D, He, Z, Hendry, M, Hong, W, Hu, X, Hu, Y, Huang, S, Huang, X, Jiang, Q, Jiang, Y, Jiang, Z, Jin, H, Korol, V, Li, H, Li, M, Li, P, Li, R, Li, Y, Li, Z, Liang, Y, Liang, Z, Liao, F, Liu, Q, Liu, S, Liu, Y, Liu, L, Liu, P, Liu, X, Lu, X, Lu, Y, Lu, Z, Luo, Y, Luo, Z, Milyukov, V, Ming, M, Pi, X, Qin, C, Qu, S, Sesana, A, Shao, C, Shi, C, Su, W, Tan, D, Tan, Y, Tan, Z, Tu, L, Wang, B, Wang, C, Wang, F, Wang, G, Wang, H, Wang, J, Wang, L, Wang, P, Wang, X, Wang, Y, Wei, R, Wu, S, Xiao, C, Xu, X, Xue, C, Yang, F, Yang, L, Yang, M, Yang, S, Ye, B, Yeh, H, Yu, S, Zhai, D, Zhang, C, Zhang, H, Zhang, J, Zhang, L, Zhang, X, Zhou, H, Zhou, M, Zhou, Z, Zhu, D, Zi, T, Luo, J, Mei J., Bai Y. -Z., Bao J., Barausse E., Cai L., Canuto E., Cao B., Chen W. -M., Chen Y., DIng Y. -W., Duan H. -Z., Fan H., Feng W. -F., Fu H., Gao Q., Gao T., Gong Y., Gou X., Gu C. -Z., Gu D. -F., He Z. -Q., Hendry M., Hong W., Hu X. -C., Hu Y. -M., Hu Y., Huang S. -J., Huang X. -Q., Jiang Q., Jiang Y. -Z., Jiang Y., Jiang Z., Jin H. -M., Korol V., Li H. -Y., Li M., Li P., Li R., Li Y., Li Z., Li Z. -X., Liang Y. -R., Liang Z. -C., Liao F. -J., Liu Q., Liu S., Liu Y. -C., Liu L., Liu P. -B., Liu X., Liu Y., Lu X. -F., Lu Y., Lu Z. -H., Luo Y., Luo Z. -C., Milyukov V., Ming M., Pi X., Qin C., Qu S. -B., Sesana A., Shao C., Shi C., Su W., Tan D. -Y., Tan Y., Tan Z., Tu L. -C., Wang B., Wang C. -R., Wang F., Wang G. -F., Wang H., Wang J., Wang L., Wang P., Wang X., Wang Y., Wang Y. -F., Wei R., Wu S. -C., Xiao C. -Y., Xu X. -S., Xue C., Yang F. -C., Yang L., Yang M. -L., Yang S. -Q., Ye B., Yeh H. -C., Yu S., Zhai D., Zhang C., Zhang H., Zhang J. -D., Zhang J., Zhang L., Zhang X., Zhou H., Zhou M. -Y., Zhou Z. -B., Zhu D. -D., Zi T. -G., and Luo J.

Abstract

TianQin is a planned space-based gravitational wave (GW) observatory consisting of three Earth-orbiting satellites with an orbital radius of about $10^5 , { m km}$. 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 $10^{-4} , { m Hz}$ and $1 , { m Hz}$ 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 $17 , { m cm}$ 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 $1.2 , { m m}$ 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.

Published

2021

2. Science with the TianQin observatory: Preliminary result on extreme-mass-ratio inspirals

Author

Fan, H, Hu, Y, Barausse, E, Sesana, A, Zhang, J, Zhang, X, Zi, T, Mei, J, Fan H. -M., Hu Y. -M., Barausse E., Sesana A., Zhang J. -D., Zhang X., Zi T. -G., Mei J., Fan, H, Hu, Y, Barausse, E, Sesana, A, Zhang, J, Zhang, X, Zi, T, Mei, J, Fan H. -M., Hu Y. -M., Barausse E., Sesana A., Zhang J. -D., Zhang X., Zi T. -G., and Mei J.

Abstract

Systems consisting of a massive black hole and a stellar-origin compact object (CO), known as extreme-mass-ratio inspirals (EMRIs), are of great significance for space-based gravitational-wave detectors, as they will allow for testing gravitational theories in the strong field regime, and for checking the validity of the black hole no-hair theorem. In this work, we present a calculation of the EMRI rate and parameter estimation capabilities of the TianQin observatory, for various astrophysical models for these sources. We find that TianQin can observe EMRIs involving COs with a mass of 10 M up to redshift ∼2. We also find that detections could reach tens or hundreds per year in the most optimistic astrophysical scenarios. Intrinsic parameters are expected to be recovered to within fractional errors of ∼10-6, while typical errors on the luminosity distance and sky localization are 10% and 10 deg2, respectively. TianQin observation of EMRIs can also constrain possible deviations from the Kerr quadrupole moment to within fractional errors ∼10-4. We also find that a network of multiple detectors would allow for improvements in both detection rates (by a factor ∼1.5-3) and in parameter estimation precision (20-fold improvement for the sky localization and fivefold improvement for the other parameters).

Published

2020