M. Alisa Mast Gregory A. Wetherbee 2016 <p><span>National Atmospheric Deposition Program (NADP)/National Trends Network precipitation type, snow-season duration, and annual timing of selected chemical wet-deposition maxima vary with latitude and longitude within a 35-year (1979–2013) data record for the contiguous United States and Alaska. From the NADP data collected within the region bounded by 35.6645°–48.782° north latitude and 124°–68° west longitude, similarities in latitudinal and longitudinal patterns of changing snow-season duration, fraction of annual precipitation recorded as snow, and the timing of chemical wet-deposition maxima, suggest that the chemical climate of the atmosphere is linked to physical changes in climate. Total annual precipitation depth has increased 4–6&nbsp;% while snow season duration has decreased from approximately 7 to 21&nbsp;days across most of the USA, except in higher elevation regions where it has increased by as much as 21&nbsp;days. Snow-season precipitation is increasingly comprised of snow, but annually total precipitation is increasingly comprised of liquid precipitation. Meanwhile, maximum ammonium deposition occurs as much as 27&nbsp;days earlier, and the maximum nitrate: sulfate concentration ratio in wet-deposition occurs approximately 10–21&nbsp;days earlier in the year. The maximum crustal (calcium&nbsp;+&nbsp;magnesium&nbsp;+&nbsp;potassium) cation deposition occurs 2–35&nbsp;days earlier in the year. The data suggest that these shifts in the timing of atmospheric wet deposition are linked to a warming climate, but the ecological consequences are uncertain.</span></p> application/pdf 10.1007/s00382-016-3017-7 en Springer-Verlag Climate-change signals in national atmospheric deposition program precipitation data article