代表论著:
1. Haiyang Zhang, Wenjing Liu, Bo Gao*, et al. A high-stability quasi-spherical resonator in SPRIGT for microwave frequency measurements at low temperatures. Science Bulletin. 2019, 64(5), 286-288.
2. YanYan Chen, Haiyang Zhang, Yaonan Song, Pan Changzhao, Bo Gao*, et al. Thermal response characteristics of a SPRIGT primary thermometry system. Cryogenics. 2019, 97, 1-6
3. Patrick M C Rourke, Christof Gaiser, Bo Gao, et al. Refractive-index gas thermometry. Metrologia 2019; 56, 032001.
4. Dongxu Han, Bo Gao*, Hui Chen, et al. Ultra-stable pressure is realized for Chinese Single Pressure Refractive Index Gas Thermometry in the range 30 kPa to 90 kPa. Science Bulletin. 2018; 63(12), 1601-1603.
5. B. Gao*, C. Pan, L. Pitre, et al. Chinese SPRIGT realizes high temperature stability in the range of 5-25 K. Science Bulletin 2018; 63(12), 733-734.
6. B. Gao*, C. Pan, Y. Chen, et al. Realization of an ultra-high precision temperature control in a cryogen-free cryostat. Review of Scientific Instruments 2018; 89, 104901.
7. Haiyang Zhang, Bo Gao*, Wei Wu, et al. Helmholtz free energy equation of state for propane and R134a binary mixture, International Journal of Refrigeration, 2018, 89: 1–10.
8. Haiyang Zhang, Bo Gao*, Huiya Li, et al. Saturated liquid density equation for pure refrigerants including CFCs, HCFCs, HFCs, HCs, HFOs, HFEs, PFAs and ISs based on the scaling law and the law of rectilinear diameter, International Journal of Refrigeration, 2018, 87: 65–77.
9. Haiyang Zhang, Huiya Li, Bo Gao*, et al. Gaseous densities of 2,3,3,3-tetrafluoroprop-1-ene (R1234yf) and isobutane (R600a) binary system: Measurements and a preliminary Helmholtz equation of state, International Journal of Refrigeration, 2018, 95: 28-37.
10. B. Gao*, L. Pitre, E.C. Luo, et al. Feasibility of primary thermometry using refractive index measurements at a single pressure. Measurement 2017; 103, 258-262.
获奖及荣誉:
1. 国际计量技术联合会:Gyorgy Striker Junior Paper Award;
2. 国际计量科学计划“Implementing the New Kelvin II”:2018年度、2019年度亮点工作;
3. 国际计量局下属计量期刊metrologia:2017年度亮点工作;
4. 亚洲科学院:“杰出青年女科学家”中国代表。 作者: danjuan 时间: 2020-5-21 09:05
微波谐振测频技术是一种测量迅速且灵敏很高的探测技术,被广泛用于温度测量、压力测量、氦临界现象研究等高精度测量领域。但微波谐振频率测量易受到多物理场和外界因素影响,尤其在低温下,参考时间标准、微波发射功率和谐振腔温度稳定性等复杂因素制约了微波谐振频率测量精度的提高,进而限制了该方法在上述领域的应用。