In the present work, we examine the distance and bias dependence of dissipative interaction using nc-AFM for artificially synthesized phlogopite ( a mica family), exfoliated into nanosheets (a thickness of 5–10 nm) and affixed on an iridium (Ir) coated silicon (Si) substrate. Figure 1a shows an nc-AFM topographic image, taken in a chamber filled with pure Ar gas at 1 atm, with a Au-coated Si cantilever (f=306.7 kHz,A= 27 nm, Olympus) overcoated with Ir using DC magnetron sputtering by ~12 nm to improve the electric conductivity of the tip. The force–distance curves acquired on the mica nanosheet and the substrate, which were numerically converted from the frequency shift–distance curves; when the tip approached the sample, first, attractive forces were found with decreasing tip-sample distance, followed by strong repulsive forces in the measured distance range. The hydrophilic mica nanosheet as well as Ir-coated Si substrate were probably covered with a thin water layer during the sample preparation in our lab environment. Thus, the attractive forces possibly corresponded to the interaction between the tip and the water layer covering sample surface. The simultaneously obtained dissipation curves show sharp increase at the distance of ~15 nm both on the mica nanosheet and the substrate; the larger dissipation was found on the mica nanosheet. Depend on the thickness of the mica nanosheet, dissipation may vary from a thin to a thick layer. The tip–sample system can be regarded as a capacitor under a bias voltage inducing the electrostatic force, where the interactions of short-range chemical forces and long-range van der Waals forces are also acting; furthermore, displacement current passes during the tip oscillation of nc-AFM operation. The mica nanosheet as dielectric probably increased the capacitance, which might increase the displacement current, resulted in larger Joule heating. We will discuss the bias dependence of the dissipation as well.