Towards Quantitative Characterisation of the Small Force Transducer Used in Nanoindentation Instruments ()
ABSTRACT
Quantitative characterization of the mechanical properties of materials
in micro-/nano-scale using depth-sensing indentation technique demands high performance
of nanoindentation instruments in use. In this paper, the efforts to calibrate
the capacitive force transducer of a commercial nanoindentation instrument are presented,
where the quasi-static characteristic of the force transducer has been calibrated
by a precise compensation balance with a resolution of ~1 nN. To investigate the
dynamic response of the transducer, an electrostatic MEMS (Micro-Electro-Mechanical
System) based on nano-force transfer standard with nano-Newton (10-9 Newton)
resolution and a bandwidth up to 6 kHz have been employed. Preliminary
experimental results indicate that 1) the force transducer under calibration has a
probing force uncertainty less than 300 nN (1σ) in the calibration range of 1 mN; 2) the transient duration
at contact points amounts to 10 seconds; 3) the overshoot of
engagement is pre-load dependent.
Share and Cite:
Z. Li and U. Brand, "Towards Quantitative Characterisation of the Small Force Transducer Used in Nanoindentation Instruments,"
Modern Instrumentation, Vol. 2 No. 4, 2013, pp. 61-67. doi:
10.4236/mi.2013.24009.