Probing magnetic susceptibility of a microsized ferromagnet
is
a long-standing problem in condensed matter physics. Among various
measuring methods for magnetic susceptibility including vibrating
sample magnetometry and superconducting quantum interference device
magnetometry, almost all require large-scale bulk samples or thick
films. However, the quantitative measurement for magnetic susceptibility
on a microscale nanoflake is a great challenge. Here, we demonstrate
a new analysis method to quantitatively evaluate the magnetic susceptibility
of a microscale ferromagnetic nanoflake. Based on the Arrott plot
of magnetization isotherms obtained from anomalous Hall resistance,
we achieve an in situ evaluation of the value of magnetic susceptibility
of a microscale ferromagnetic Fe5GeTe2 nanoflake,
identification of the out-of-plane and in-plane magnetization, and
investigation of the magnetic anisotropy transition with quantifying
critical exponents. Our method reveals critical information on magnetic
phase transition in microscale ferromagnetic materials, providing
deep insight into spin dynamics of correlated electron systems.