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The History of Synoptic Meteorology in the Age of Numerical Weather Forecasting  

Kristine C. Harper

Despite some early attempts in the 19th century, national weather services did not regularly create forecasts for public consumption until the early 20th century, and many of those were based on a handful of surface observations of dubious quality. With the invention of the balloon-borne radiosonde in the 1930s, upper-air observations became more common, and knowledge of upper-level processes was melded into forecasting practice. World War II brought its own challenges and opportunities, expanding the number of trained meteorologists worldwide, establishing many new observing stations in tropical and high-latitude locations, and opening the possibility of using radar to identify short-range severe weather. But the big change was the development of digital electronic computers, and with them the opportunity to calculate the weather. The first efforts were marginal at best, but international teams in the United States and Sweden continued their efforts, and by the late 1950s, midatmospheric prognosis charts were being transmitted to forecast offices, which would prepare the final local forecasts. Unfortunately for the synoptic forecasters in the field offices, the new objective numerical weather prediction (NWP) products were not comparable to the old subjective forecast charts that they had used for years. The resulting push and pull between the atmospheric modelers and the synoptic meteorologists ultimately changed both groups: the atmospheric modelers used forecaster feedback to upgrade the models, and the synoptic meteorologists learned to use the objective forecasts. The anticipated improvements in weather forecasting, however, did not follow immediately. As the decades passed, computing power increased and the introduction of satellites with multiple specialized sensors, purpose-built weather radar, and other remote sensing devices increased the availability of ground and upper-air data. As a result, more variables and the physics that defined them were added to NWP models, and the resulting products changed the way synoptic meteorologists made their forecasts, even if they did not change their feel for the atmosphere. Those changes continued into the 21st century, fueling the desire for specialized forecasts from multiple interest groups and the public’s desire for accurate, up-to-the-minute weather forecasts that extend up to 2 weeks into the future.

Article

Air Pollution and Weather Interaction in East Asia  

Aijun Ding, Xin Huang, and Congbin Fu

Air pollution is one of the grand environmental challenges in developing countries, especially those with high population density like China. High concentrations of primary and secondary trace gases and particulate matter (PM) are frequently observed in the industrialized and urbanized regions, causing negative effects on the health of humans, plants, and the ecosystem. Meteorological conditions are among the most important factors influencing day-to-day air quality. Synoptic weather and boundary layer dynamics control the dispersion capacity and transport of air pollutants, while the main meteorological parameters, such as air temperature, radiation, and relative humidity, influence the chemical transformation of secondary air pollutants at the same time. Intense air pollution, especially high concentration of radiatively important aerosols, can substantially influence meteorological parameters, boundary layer dynamics, synoptic weather, and even regional climate through their strong radiative effects. As one of the main monsoon regions, with the most intense human activities in the world, East Asia is a region experiencing complex air pollution, with sources from anthropogenic fossil fuel combustion, biomass burning, dust storms, and biogenic emissions. A mixture of these different plumes can cause substantial two-way interactions and feedbacks in the formation of air pollutants under various weather conditions. Improving the understanding of such interactions needs more field measurements using integrated multiprocess measurement platforms, as well as more efforts in developing numerical models, especially for those with online coupled processes. All these efforts are very important for policymaking from the perspectives of environmental protection and mitigation of climate change.