NIST Authors in **Bold**

Author(s): | E May; Laurent Pitre; J B. Mehl; Michael R. Moldover; James W. Schmidt; |
---|---|

Title: | Quasi-Spherical Cavity Resonators for Metrology Based on the Relative Dielectric Permittivity of Gases |

Published: | October 01, 2004 |

Abstract: | We evaluate a quasi-spherical, copper, microwave cavity resonator for accurately measuring the relative dielectric permittivity {epsilon_{r}(p,T)} of helium and argon. In a simple, crude approximation the cavity s shape is a triaxial ellipsoid with axes of length {a}, 1.001{a} and 1.005{a}, with {a} = 5 cm. The unequal axes of the quasi-sphere separated the triply-degenerate microwave resonance frequencies of a sphere {fTM11, fTM12,... fTM11, fTM12,...}into three non-overlapping, easily measured, frequencies. The frequency splittings are consistent with the cavity s shape, as determined from dimensional measurements. We deduced epsilon of ε_{r}(p,T) of helium and of argon at 289 K and up to 7 MPa from the resonance frequencies {fsigma,en,} the resonance half-widths {gen,sigma} , and the compressibility of copper. Simultaneous measurements of epsilon of ε_{r}(p,T) with the quasi-spherical resonator and a cross capacitor agreed within 1x10-6 for helium, and for argon they differed by an average of only 1.4(multiplied by}10^{-6}. This small difference is within the stated uncertainty of the capacitance measurements. For helium, the resonator results for {epsilon _{r}(p,T)} were reproducible over intervals of days with a standard uncertainty of 0.2×10^-6^, consistent with a temperature irreproducibility of 5 mK. We demonstrate that several properties of quasi-spherical cavity resonators make them well suited to {epsilon _{r}(p,T)} determinations. Ultimately, a quasi-spherical resonator may improve dielectric constant gas thermometry and realize a proposed pressure standard based on {epsilon _{r}(p,T)}. |

Citation: | Review of Scientific Instruments |

Volume: | 75 |

Issue: | No. 10 |

Keywords: | argon;dielectric constant;helium;metrology;microwave resonator;permittivity;pressure;resonator;temperature |

Research Areas: |