Search

Your search keyword '"Arritt, R.W."' showing total 12 results
Start Over Author "Arritt, R.W."
12 results on '"Arritt, R.W."'

1. High-Resolution Regional Climate Models: Meeting Ongoing Community and Scientific Needs

Author

Gutowski, W.J., Ullrich, P.A., Hall, A., Leung, L.R., O'Brien, T.A., Patricola, C.M., Arritt, R.W., Bukovsky, M.S., Calvin, K.V., Feng, Z., Jones, A.D., Kooperman, G.J., Monier, E., Pritchard, M.S., Pryor, S.C., Qian, Y., Rhoades, A.M., Roberts, A.F., Sakaguchi, K., Urban, N., and Zarzycki, C.

Subjects
Water resource management -- Analysis, Climate models -- Analysis, Urban heat islands -- Analysis, Business, Earth sciences
Abstract

Regional climate modeling addresses processes unresolved by global climate models (GCMs). The targeted regions are generally subcontinental, sometimes a few tens of kilometers--scales at which fine features such as mountains, [...]

Published
2020
Full Text
View/download PDF

2. Transferability intercomparison: an opportunity for new insight on the global water cycle and energy budget

Author

Takle, E.S., Roads, J., Rockel, B., Gutowski, W.J., Jr., Arritt, R.W., Meinke, I., Jones, C.G., and Zadra, A.

Subjects
Climate -- Models, Climate -- Comparative analysis, Hydrologic cycle -- Evaluation, Energy conservation -- United States, Energy conservation -- Evaluation, Business, Earth sciences
Abstract

A new approach, called transferability intercomparisons, is described for advancing both understanding and modeling of the global water cycle and energy budget. Under this approach, individual regional climate models perform simulations with all modeling parameters and parameterizations held constant over a specific period on several prescribed domains represent ing different climatic regions. The transferability framework goes beyond previous regional climate model intercomparisons to provide a global method for testing and improving model parameterizations by constraining the simulations within analyzed boundaries for several domains. Transferability intercomparisons expose the limits of our current regional modeling capacity by examining model accuracy on a wide range of climate conditions and realizations. Intercomparison of these individual model experiments provides a means for evaluating strengths and weaknesses of models outside their 'home domains' (domain of development and testing). Reference sites that are conducting coordinated measurements under the continental-scale experiments under the Global Energy and Water Cycle Experiment (GEWEX) Hydrometeorology Panel provide data for evaluation of model abilities to simulate specific features of the water and energy cycles. A systematic intercomparison across models and domains more clearly exposes collective biases in the modeling process. By isolating particular regions and processes, regional model transferability intercomparisons can more effectively explore the spatial and temporal heterogeneity of predictability. A general improvement of model ability to simulate diverse climates will provide more confidence that models used for future climate scenarios might be able to simulate conditions on a particular domain that are beyond the range of previously observed climates.

Published
2007

3. On the potential impact of daytime surface sensible heat flux on the dissipation of Martian cold air outbreaks

Author

Segal, M., Arritt, R.W., and Tillman, J.E.

Subjects
Mars (Planet) -- Atmosphere, Atmospheric temperature -- Research, Earth sciences, Science and technology
Abstract

The Martian daytime soil surface temperature is governed primarily by the net irradiance balance and surface soil heat flux. Thus the outbreak of a cold air mass generates increased sensible heat flux that is conducive to daytime dissipation of the cold air mass thermal characteristics. Conceptual and scaling evaluations of this dissipation are provided while comparison is made with similar situations on Earth. It is estimated that sensible heat flux contribution to the dissipation of the original thermal structure of the cold air could be three times larger than the corresponding situation on Earth. Illustrative numerical model simulations provide scaling of the potential impact on the dissipation of cold air masses for various combinations of background wind speed and latitudes.

Published
1997

4. Small lake daytime breezes: some observational and conceptual evaluations

Author

Segal, M., Leuthold, M., Arritt, R.W., Anderson, C., and Shen, J.

Subjects
Winds -- Research, Lakes -- Environmental aspects, Business, Earth sciences
Abstract

The diversity of small lakes' (size < 50 km) configurations, sizes, surrounding terrain, and land use combined with relative sparsity of observations complicates the observational evaluation of the lake breezes (LB) that are induced by these lakes. In the present article observational data obtained from available documents, data archives, and special projects were surveyed to suggest characterization of the LB features. The observational survey was complemented by conceptual evaluations. A preliminary generalization of the LB intensity and inland penetration in relation to the surrounding land use was inferred. The conceptual evaluation suggested that for a given lake width the prime factor affecting the LB intensity is the magnitude of the surface sensible heat flux over the surrounding land. Cooling related to the lake water temperature was indicated to have usually a secondary effect on the LB intensity for small lakes. Surface observations implied that the onshore penetration of the LB by the early afternoon hours is typically less than the characteristic width of the lake. Lower atmosphere observations indicated that the vertical extent of the LB may reach several hundred meters. Implications of the observed LB features in support of characterization of the real-world vegetation breeze are discussed.

Published
1997

5. Nonclassical mesoscale circulations caused by surface sensible heat-flux gradients

Author

Segal, M. and Arritt, R.W.

Subjects
Ocean-atmosphere interaction -- Research, Sea breeze -- Research, Business, Earth sciences
Abstract

Significant spatial heterogeneities of daytime surface sensible heat flux are common over land within mesoscale domains. Thermally induced circulations, similar to the sea/lake breeze [termed nonclassical mesoscale circulations (NCMCs)], are anticipated in these situations. Growing research interest in NCMCs has developed in the recent decade. In this article, general quantifications of NCMC characteristics are surveyed based on modeling and observational studies, along with further elaborations on specific NCMCs. The numerical modeling studies have indicated NCMCs with intensity comparable to the sea breeze in the ideal situations of sharp contrast between extended wet soil or crop and adjacent dry land areas. Similar results were obtained when contrasts of cloud with clear sky and snow with snow-free areas were considered. For less ideal contrasts, as well as for thermal contrasts generated by some other types of forcing, weaker NCMCs were simulated. The limited observational studies have suggested that, for some potential NCMC situations, noticeable horizontal thermal gradients are produced within the lower atmosphere. In general, however, pronounced NCMC flows have not been indicated with great certainty. in many of the potential NCMC situations, the small sizes of the areas in which sensible heat flux is modified compared with the surrounding areas suggest reduced intensity of circulations in the real world, particularly in the presence of an opposing background flow. Additionally, nonuniformity of the surface sensible heat fluxes in one or both of the contrasting surfaces is likely to be an important factor in reducing the real-world intensity of NCMCs. It is concluded that emphasis on observations is essential for further progress in quantification of real-world NCMCs.

Published
1992

6. Standardized research protocols enable transdisciplinary research of climate variation impacts in corn production systems

Author

Kladivko, E.J., Helmers, M.J., Abendroth, L.J., Herzmann, D., Lal, R., Castellano, M.J., Mueller, D.S., Sawyer, J.E., Anex, R.P., Arritt, R.W., Basso, B., Kellogg, W.K., Bonta, J.V., Bowling, L.C., Cruse, R.M., Fausey, N.R., Frankenberger, J.R., Gassman, P.W., Gassmann, A.J., Kling, C.L., Kravchenko, A., Lauer, J.G., Miguez, F.E., Nafziger, E.D., Nkongolo, N., O'Neal, M., Owens, L.B., Owens, P.R., Scharf, P., Shipitalo, M.J., Strock, J.S., and Villamil, M.B.

Abstract

The important questions about agriculture, climate, and sustainability have become increasingly complex and require a coordinated, multifaceted approach for developing new knowledge and understanding. A multistate, transdisciplinary project was begun in 2011 to study the potential for both mitigation and adaptation of corn-based cropping systems to climate variations. The team is measuring the baseline as well as change of the system's carbon (C), nitrogen (N), and water footprints, crop productivity, and pest pressure in response to existing and novel production practices. Nine states and 11 institutions are participating in the project, necessitating a well thought out approach to coordinating field data collection procedures at 35 research sites. In addition, the collected data must be brought together in a way that can be stored and used by persons not originally involved in the data collection, necessitating robust procedures for linking metadata with the data and clearly delineated rules for use and publication of data from the overall project. In order to improve the ability to compare data across sites and begin to make inferences about soil and cropping system responses to climate across the region, detailed research protocols were developed to standardize the types of measurements taken and the specific details such as depth, time, method, numbers of samples, and minimum data set required from each site. This process required significant time, debate, and commitment of all the investigators involved with field data collection and was also informed by the data needed to run the simulation models and life cycle analyses. Although individual research teams are collecting additional measurements beyond those stated in the standardized protocols, the written protocols are used by the team for the base measurements to be compared across the region. A centralized database was constructed to meet the needs of current researchers on this project as well as for future use for data synthesis and modeling for agricultural, ecosystem, and climate sciences.

Published
2014
Full Text
View/download PDF

7. Surface water quality and cropping systems sustainability under a changing climate in the Upper Mississippi River Basin

Author

Panagopoulos, Y., Gassman, P.W., Arritt, R.W., Herzmann, D.E., Campbell, T.D., Jha, M.K., Kling, C.L., Srinivasan, R., White, M., and Arnold, J.G.

Abstract

Agricultural nonpoint source pollution is the main source of nitrogen (N) and phosphorus (P) in the intensely row-cropped Upper Mississippi River Basin (UMRB) stream system and is considered the primary cause of the northern Gulf of Mexico hypoxic zone according to the US Environmental Protection Agency. A point of crucial importance in this region is therefore how intensive corn (Zea maysL.)-based cropping systems for food and fuel production can be sustainable and coexist with a healthy water environment, not only under existing climate conditions but also under a changed climate in the future. To address this issue, a UMRB integrated modeling system has been built with a greatly refined 12-digit subbasin structure based on the Soil and Water Assessment Tool (SWAT) water quality model, which is capable of estimating landscape and in-stream water and pollutant yields in response to a wide array of alternative cropping and/or management strategies and climatic conditions. The effects of the following four agricultural management scenarios on crop production and pollutant loads exported from the cropland of the UMRB to streams and rivers were evaluated: (1) expansion of continuous corn across the entire basin, (2) adoption of no-till on all corn and soybean (Glycine maxL.) fields in the region, (3) substitution of the traditional continuous corn and corn–soybean rotations with an extended five-year rotation consisting of corn, soybean, and three years of alfalfa (Medicago sativaL.), and (4) implementation of a winter cover crop within the baseline rotations. The effects of each management scenario were evaluated both for current climate and a projected midcentury (2046 to 2065) climate from a General Circulation Model (GCM). All four scenarios behaved similarly under the historical and future climate, generally resulting in reduced erosion and nutrient loadings to surface water bodies compared to the baseline agricultural management. Continuous corn was the only scenario which resulted in increased N pollution while no-till was the most environmentally effective and able to sustain production at almost the same levels. Rye (Secale cerealeL.) cover crop within the fallow period was also effective in reducing erosion and both sediment-bound and soluble forms of nutrients. The results indicated that alternative management practices could reduce sediment, N, and P exports from UMRB cropland by up to 50% without significantly affecting yields. Results for the climate change scenario showed that the effectiveness of the management scenarios was strongly linked to the reduced water availability predicted under the future climate, which assisted in mitigating pollutant transport, although with a small loss of production.

Published
2014
Full Text
View/download PDF

8. A Method for Simulating Effects of Quasi-Stationary Wave Anomalies on Regional Climate.

Author

Pan, Z., Segal, M., Arritt, R.W., Chen, T.-C., and Weng, S.-P.

Subjects
STANDING waves, DROUGHTS, FLOODS
Abstract

A combined observational and numerical modeling methodology was employed to examine the interaction of large-scale quasi-stationary waves with regional forcing in the drought of 1988 and flood of 1993 in the north-central United States. The study implements and tests a new lateral boundary condition closure approach enabling regional climate modeling sensitivity studies to account for anomalies external to the simulated domain. Thirty-day regional simulations of the continental United States using the MM5 regional model successfully reproduced the anomalous drought and flood conditions. In an additional set of simulations the observed large-scale quasi-stationary wave anomalies in the dynamic and thermodynamic fields were filtered out through adjustment of the observationally based lateral boundary conditions. In these filtered simulations the simulated meteorological fields over the drought/flood areas for both years tended toward those for normal years, suggesting that the proposed filtering technique can be used as a tool to test the regional response to external forcing. Comparisons of the control and filtered simulations illustrated the significant influence of large-scale anomalies on the strength and geographical distribution of the low-level jet and related impacts on rainfall in the central United States. [ABSTRACT FROM AUTHOR]

Published
1999
Full Text
View/download PDF

9. Some Observations of the Clearing of Cumulus Clouds Downwind from Snow-Covered Areas.

Author

Segal, M., Anderson, C., Arritt, R.W., Rabin, R.M., and Martin, D.W.

Subjects
CLOUDS, SATELLITE meteorology, CLIMATOLOGY
Abstract

Satellite images that illustrate the clearing of cumulus clouds downwind from snow-covered areas are presented. The cloud clearing resembles that occasionally observed with lakes during warm advection, supporting the suggestion that the thermal forcing associated with a uniform snow-covered area is comparable to that of a cold-water lake of similar size. Analysis of snow cover patterns in the central United States suggests that the climatological probability for situations conducive to the cloud clearing is at most once per month. [ABSTRACT FROM AUTHOR]

Published
1999
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results