For many, 2020 was a year of abrupt professional and personal change. For the aquatic sciences community, many were adapting to virtual formats for conducting and sharing science, while simultaneously learning to live in a socially distanced world. Understandably, the aquatic sciences community postponed or canceled most in‐person scientific meetings. Still, many scientific communities either transitioned annual meetings to a virtual format or inaugurated new virtual meetings. Fortunately, increased use of video conferencing platforms, networking and communication applications, and a general comfort with conducting science virtually helped bring the in‐person meeting experience to scientists worldwide. Yet, the transition to conducting science virtually revealed new barriers to participation whereas others were lowered. The combined lessons learned from organizing a meeting constitute a necessary knowledge base that will prove useful, as virtual conferences are likely to continue in some form. To concentrate and synthesize these experiences, we showcase how six scientific societies and communities planned, organized, and conducted virtual meetings in 2020. With this consolidated information in hand, we look forward to a future, where scientific meetings embrace a virtual component, so to as help make science more inclusive and global.
Lake and reservoir surface areas are an important proxy
for freshwater
availability. Advancements in machine learning (ML) techniques and
increased accessibility of remote sensing data products have enabled
the analysis of waterbody surface area dynamics on broad spatial scales.
However, interpreting the ML results remains a challenge. While ML
provides important tools for identifying patterns, the resultant models
do not include mechanisms. Thus, the “black-box” nature
of ML techniques often lacks ecological meaning. Using ML, we characterized
temporal patterns in lake and reservoir surface area change from 1984
to 2016 for 103,930 waterbodies in the contiguous United States. We
then employed knowledge-guided machine learning (KGML) to classify
all waterbodies into seven ecologically interpretable groups representing
distinct patterns of surface area change over time. Many waterbodies
were classified as having “no change” (43%), whereas
the remaining 57% of waterbodies fell into other groups representing
both linear and nonlinear patterns. This analysis demonstrates the
potential of KGML not only for identifying ecologically relevant patterns
of change across time but also for unraveling complex processes that
underpin those changes.
The surface urban heat island (SUHI) effect is among the major environmental issues encountered in urban regions. To better predict the dynamics of the SUHI and its impacts on extreme heat events, an accurate characterization of the surface energy balance in urban regions is needed. However, the ability to improve understanding of the surface energy balance is limited by the heterogeneity of surfaces in urban areas. This study aims to enhance the understanding of the urban surface energy budget through an innovation in the use of land surface temperature (LST) observations from remote sensing satellites. A LST database with 5–min temporal and 30–m spatial resolution is developed by spatial downscaling of the Geostationary Operational Environmental Satellites—R (GOES–R) series LST product over New York City (NYC). The new downscaling method, known as the Spatial Downscaling Method (SDM), benefits from the fine spatial resolution of Landsat–8 and high temporal resolution of GOES–R, and considers the temporal variation in LST for each land cover type separately. Preliminary results show that the SDM can reproduce the temporal and spatial variability of LST over NYC reasonably well and the downscaled LST has a spatial root mean square error (RMSE) of the order of 2 K as compared to the independent Landsat–8 observations. The SDM shows smaller RMSE of 1.93 K over the tree canopy land cover, whereas RMSE is 2.19 K for built–up areas. The overall results indicate that the SDM has potential to estimate LST at finer spatial and temporal scales over urban regions.
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