Illite-smectite mixed layers (I-S) occurring authigenically in diagenetic and hydrothermal environments reacts toward more illite-rich phases as temperature and potassium ion concentration increase. For that reason, I-S is often used as geothermometry and/or geochronometry at the field of hydrocarbons or ore minerals exploration. Generally, I-S shows X-ray powder diffraction (XRD) patterns of ultra-thin lamellar structures, which consist of restricted numbers of sillicate layers (normally, 5 ~ 15 layers) stacked in parallel to a-b planes. This ultra-thinness is known to decrease I-S expandability (%S) rather than theoretically expected one (short-stacking effect). We attempt here to quantify the short stacking effect of I-S using the difference of two types of expandability: one type is a maximum expandability (%SMax) of infinite stacks of fundamental particles (physically inseparable smallest units), and the other type is an expandability of finite particle stacks normally measured using X-ray powder diffraction (XRD) (%SXRD). Eleven I-S samples from the Geumseongsan volcanic complex, Uiseong, Gyeongbuk, have been analyzed for measuring %SXRD and average coherent scattering thickness (CST) after size separation under 1 μm. Average fundamental particle thickness (Nf) and %SMax have been determined from %SXRD and CST using inter-parameter relationships of I-S layer structures. The discrepancy between %SMax and %SXRD (Δ%S) suggests that the maximum short-stacking effect happens approximately at 20 %SXRD, of which point represents I-S layer structures consisting of ca. average 3-layered fundamental particles (Nf ≈ 3). As a result of inferring the %SXRD range of each Reichweite using the %SXRD vs. Nf diagram of Kang et al. (2002), we can confirms that the fundamental particle thickness is a determinant factor for I-S Reichweite, and also that the short-stacking effect shifts the %SXRD range of each Reichweite toward smaller %SXRD values than those that can be theoretically prospected using junction probability.