a total of 98 dew and 9 frost samples were collected at the University of Arkansas Agricultural Experiment Station, Fayetteville. The total water flux from dews and frosts per year was less than 2% of that from rains. Acid and nutrient fluxes were also much lower in dew. In the following series of ions the number in parentheses gives the percent of the yearly flux ofthe ion in dew compared to rain for the same time period: H + (0.06), Ca2 +(25), Mg2+(11), K + (21), Na + (4), NH • (10), CI' (4), NO• (5), and SO•' (5). In contrast, the concentration of the various ions in dew, except H +, is generally several times that in rain. Dew is primarily a Ca(HCO3) 2 and (NH4)2SO4 solution; whereas rain is primarily a NH4HSO 4 solution. The mean pH of dew is 6.37 compared to 4.99 for rain. The average acetate-formate concentration of dew in equivalents was (1) equal to about 53% of the nitrate-sulfate concentration in rain for April-June and (2) 10 times more concentrated than in rain for the year. The steps governing dew composition are indicated to be (1) formation on dry deposition solids (2) dissolution of the soluble portion of the dry deposition by dew water, and (3) sorption of gaseous NH 3, acetic, and formic acids into the dew solution. times more concentrated in dew. Median pH of dew was 6.5. Pierson et al. [1986, 1987] using a Teflon collector at a rural site in Pennsylvania, Allegheny Mountain, found dew chemistry similar to rain chemistry, but more dilute, except for H +. The average H + concentration corresponded to apH of 4.0(n=15). Other ionic fluxes in dew were only a few percent of those in rain. Using a Teflon collector at a Claremont, California, college campus, Pierson et al. [1988] found dew (n=5) acidity mostly derived from organic acids. The volume-weighted Pierson, W.R., Brachaczek, W.W., Jaspar, S.M., Cass, G.R., and Soloman, P.A., Dry deposition and dew chemistry in Claremont, California, during the 1985 nitrogen species methods comparison study, Atmo.