Observational studies based on satellite data have shown that mature tropical cyclones (TCs) often experience secondary eyewall formation (SEF) during their lifetime. This brings concerns for the essential role of intrinsic dynamics of a TC vortex in SEF. Among many proposed intrinsic dynamical mechanisms, of particular interest in this study is the role of unbalanced dynamics within and just above the boundary layer, a recently-presented dynamical pathway to SEF. A modified version of WRF-EnKF is used to answer two key questions about the SEF problem: 1) what is the impact of the amount of data assimilation that is involved in the operational parameter of the axisymmetric tangential wind profile on simulating SEF in Typhoon Sinlaku (2008), and 2) what is the role of unbalanced dynamics associated with boundary layer processes presented in numerical experiments with higher horizontal resolution (1.67 km). In the first part of this study, wind profiles based on C-130 flight observations were assimilated into the model within a time window of 5-6 hours around the observing time. This experiment, with a reduced data amount of assimilated wind profiles, is unable to reproduce the secondary eyewall structure of Sinlaku, while intensification of the inner eyewall is reasonably captured. This result infers that the outer eyewall appears more sensitive to the reduced amount of assimilated wind profiles when coarser model resolution of 5 km is adopted. The optimal data assimilation amount of the TC wind profiles to be able to simulate SEF remains an interesting issue to be further investigated. In the second part, numerical data carried out in the part one study are used to provide the initial condition for two data-denial experiments with higher model resolution (1.67 km). The two experiments are run from 03 UTC and 15 UTC 10 September, named EXP1003-4D and EXP1015-4D, respectively. Compared with the 5-km-resolution experiment, the two simulations present more details of the evolved TC vortex. The asymmetry of vortex is more distinct and active; for instance, the inner eyewall ring has a polygonal structure of potential vorticity, quite different from the 5-km simulation. This suggests that the asymmetric dynamics needs to be further addressed for the SEF problem, particularly in model simulations with high resolution. The structure of the outer eyewall the high-resolution simulation (EXP1015-4D) is robust, and supergradient forces develop and establish a secondary maximum over the radii where SEF occurs, supporting the recently-proposed unbalanced pathway to SEF. The result of EXP1015-4D also implies that even though the amount of assimilated data is limited, given adequately fine model resolution, the model dynamics can capture the formation of the outer eyewall.