Cyber-Innovated Watershed Research at the Shale Hills Critical Zone Observatory. Yu, X., Duffy, C., Gil, Y., Leonard, L., Bhatt, G., & Thomas, E. Systems Journal, IEEE, PP(99):1–12, 2015.
Cyber-Innovated Watershed Research at the Shale Hills Critical Zone Observatory [link]Paper  doi  abstract   bibtex   
Cyberinfrastructure is enabling ever more integrative and transformative science. Technological advances in cyberinfrastructure have allowed deeper understanding of watershed hydrology by improved integration of data, information, and models. The synthesis of all sources of hydrologic variables (historical, real time, future scenarios, observed, and modeled) requires advanced data acquisition, data storage, data management, data integration, data mining, and data visualization. In this context, cyber-innovated hydrologic research was implemented to carry out watershed-based historical climate simulations at the Shale Hills Critical Zone Observatory. The simulations were based on the assimilation of data from a hydrologic monitoring network into a multiphysics hydrologic model (the Penn State Integrated Hydrology Model). We documented workflows for the model application and applied the model to short-time hyporheic exchange flow study and long-term climate scenario analysis. The effort reported herein demonstrates that advances in cyberscience allows innovative research that improves our ability to access and share data; to allow collective development of science hypotheses; and to support building models via team participation. We simplified communications between model developers and community scientists, software professionals, students, and decision makers, which in the long term will improve the utilization of hydrologic models for science and societal applications.
@article{yu_cyber-innovated_2015,
	title = {Cyber-{Innovated} {Watershed} {Research} at the {Shale} {Hills} {Critical} {Zone} {Observatory}},
	volume = {PP},
	issn = {1932-8184},
	url = {http://dx.doi.org/10.1109/JSYST.2015.2484219},
	doi = {10.1109/JSYST.2015.2484219},
	abstract = {Cyberinfrastructure is enabling ever more integrative and transformative science. Technological advances in cyberinfrastructure have allowed deeper understanding of watershed hydrology by improved integration of data, information, and models. The synthesis of all sources of hydrologic variables (historical, real time, future scenarios, observed, and modeled) requires advanced data acquisition, data storage, data management, data integration, data mining, and data visualization. In this context, cyber-innovated hydrologic research was implemented to carry out watershed-based historical climate simulations at the Shale Hills Critical Zone Observatory. The simulations were based on the assimilation of data from a hydrologic monitoring network into a multiphysics hydrologic model (the Penn State Integrated Hydrology Model). We documented workflows for the model application and applied the model to short-time hyporheic exchange flow study and long-term climate scenario analysis. The effort reported herein demonstrates that advances in cyberscience allows innovative research that improves our ability to access and share data; to allow collective development of science hypotheses; and to support building models via team participation. We simplified communications between model developers and community scientists, software professionals, students, and decision makers, which in the long term will improve the utilization of hydrologic models for science and societal applications.},
	number = {99},
	journal = {Systems Journal, IEEE},
	author = {Yu, X. and Duffy, C. and Gil, Y. and Leonard, L. and Bhatt, G. and Thomas, E.},
	year = {2015},
	keywords = {Analytical models, Biological system modeling, Critical zone observatories (CZOs), Data models, Data visualization, Hydrology, Observatories, Software, cyberinfrastructure, data analytics, penn state integrated hydrologic model (PIHM), shale hills, watershed, web services},
	pages = {1--12},
}

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