Yongchao Ma, Nanjia Li, Weibo Liu, Kang Ma, Wei Zhao, Songling Huang, Shisong Li
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A Compact Magnet System for the Tsinghua Tabletop Kibble Balance
Although the so-called magnetic geometrical factor, $Bl$, of a Kibble balance
does not appear in the Kibble equations, it offers the precision link between
electrical and mechanical quantities and furthers a quasi-quantum traceability
path for mass metrology. This feature makes the magnet system, supplying the
$Bl$ in Kibble equations, play a core role in Kibble balances. Following the
open-hardware idea, we report here on the design, manufacture, assembly,
optimization, and finally performance of a compact magnet system for the
Tsinghua tabletop Kibble balance. Notably, the magnet system showcased in this
study facilitates a straightforward upper levitation of splitting through a
streamlined mechanism guide, substantially enhancing the ease of open and close
operations. Experimental tests show the realized magnet systems can yield a
high $Bl$ value (e.g., 400 Tm for a bifilar coil and 800 Tm for a single coil
with a wire gauge of 0.2 mm) meanwhile a low volume/weight (40 kg) thanks to
the uniformity improvement of magnetic profiles. Furthermore, important
parameters related to systematic effects, such as the current effect, are
checked, aiming for a final mass-realization accuracy at the $10^{-8}$ level.
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