Whether a(b) 6.12 s, (c) 9.18 than a (d)monolayer exists on thestage, OnsetimagesI) Figure five. Chosen time-lapse evidence on whether a thin film bigger than a 20.14 s during on initial surface; the (stage USDC supply inconclusive evidence on (a) five.92 s, thin film larger s, and monolayer exists the the surface; the images are are USDC deliver inconclusive evidence on no matter whether a thin film bigger than a monolayer exists around the surface; the pictures of recorded SPRi SPRi nm. recorded employing employing at 680at 680 nm. are recorded applying SPRi at 680 nm.After Stage I, droplets grow and coalesce to come to be larger droplets. no drainage Immediately after Stage I, droplets develop and coalesce to turn out to be bigger droplets. AsAs no drainage Just after was I, droplets the and coalesce to turn out to be intuitive count on that drainage mechanismwas made ongrowcondensing surface, it islarger droplets. As nothethe longmechanism Stagedesigned on the condensing surface, it is intuitive to to count on that longmechanism was designed on thesteam not sustainable on around the to anticipate At stage longtermdropwise condensationof steam isis notsurface, it is intuitivegold surface. the stage II dropwise condensation of condensing sustainable the gold surface. that At II of term USDC, the results show thethe reflectance on the between droplets D-threo-PPMP Formula increases.stage II This ofterm dropwise condensationreflectance in the areaarea between droplets increases.inUSDC, the results show of steam will not be sustainable on the gold surface. At This of USDC, the reflectance the reflectance increases. This crease inthe benefits showindicates the the of the location in between dropletswater moleculeinincrease inside the reflectance indicates formation of a of a D-?Glucose ?6-?phosphate (disodium salt) web multilayer molecule film beformation multilayer water film crease within the reflectance and b show raw image a multilayer water molecule film between droplets. Figure 6a indicates theaformation ofand the corresponding processed imbetween droplets. Figure 6a,b show a raw image and also the corresponding processed image tween droplets. of USDC, respectively. raw image and Figure 6b represents that water age from Stage II Figure 6a and b show a The dark blue inthe corresponding processed imfrom Stage II of USDC, respectively. The dark blue in Figure 6b represents that water age from Stage II of USDC, respectively. The droplets varies among 3 nm. Because the droplets and thickness of thin-films betweendark blue in Figure 6b represents that water droplets and thickness of thin-films involving droplets varies between 3 nm. As the USDC droplets and thickness of thin-films films among droplets increases. three nm. As of USDC continues, the thickness of thin involving droplets varies among As our study the continues, the thickness of thin films among droplets increases. As our study of the USDC continues, the thickness of thin films in between droplets stages, we’ve study with the mechanism of dropwise condensation of steam is at its earlyincreases. As ournot conmechanism of dropwise condensation of steam is at its early stages, we’ve not conducted the mechanism of dropwise condensation of of thin at its early stages, we have not conducted any quantitative analysis on the effectsteam isfilms involving droplets around the heat any quantitative analysis analysis around the impact films in between droplets on the on the heat around the effect of thin of thin films involving heat transfer ducted any quantitative transfer prices. In our future perform, we will involve the measurement of droplets heat transfer on the rates. In for USD.