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2,135 results on '"Weller, Robert A."'

51. Overflow waters in the western Irminger Sea modify deep sound speed structure and convergence zone propagation.

Author

Bhatt, EeShan C., Baggeroer, Arthur B., and Weller, Robert A.

Subjects
SPEED of sound, MERIDIONAL overturning circulation, DEPTH sounding, COMBINED sewer overflows, ATMOSPHERIC acoustics, SEWERAGE
Abstract

Deep sound speed structure in the western Irminger Sea is found to be highly dynamic in comparison to the adiabatic (uniform) sound speed gradient underpinning data assimilation and modeling efforts around the globe. A beamed source parabolic equation model is used to illustrate how the resulting non-uniform sound speed structure at 1 to 1.5 km in depth and sound speed inversion near the seafloor produce observable effects on acoustic signals between a shallow source and shallow vertical line array at convergence zone ranges. Beamforming analysis shows that a uniform sound speed gradient leads to "ideal" interference patterns that do not capture or represent modeled convergence zone properties, such as location, strength, and sharpness. Overall findings suggest that in situ information about sound speed below 1 km is necessary for low frequency, long-range propagation studies, particularly in areas of complex thermohaline circulation. [ABSTRACT FROM AUTHOR]

Published
2024
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57. Moorings

Author

Trask, Richard P., primary and Weller, Robert A., additional

Published
2019
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68. Effects of the Pandemic on Observing the Global Ocean

Author

Boyer, Tim, Zhang, Huai-min, O’brien, Kevin, Reagan, James, Diggs, Stephen, Freeman, Eric, Garcia, Hernan, Heslop, Emma, Hogan, Patrick, Huang, Boyin, Jiang, Li-qing, Kozyr, Alex, Liu, Chunying, Locarnini, Ricardo, Mishonov, Alexey V., Paver, Christopher, Wang, Zhankun, Zweng, Melissa, Alin, Simone, Barbero, Leticia, Barth, John A., Belbeoch, Mathieu, Cebrian, Just, Connell, Kenneth J., Cowley, Rebecca, Dukhovskoy, Dmitry, Galbraith, Nancy R., Goni, Gustavo, Katz, Fred, Kramp, Martin, Kumar, Arun, Legler, David M., Lumpkin, Rick, Mcmahon, Clive R., Pierrot, Denis, Plueddemann, Albert J., Smith, Emily A., Sutton, Adrienne, Turpin, Victor, Jiang, Long, Suneel, V., Wanninkhof, Rik, Weller, Robert A., Wong, Annie P. S., Boyer, Tim, Zhang, Huai-min, O’brien, Kevin, Reagan, James, Diggs, Stephen, Freeman, Eric, Garcia, Hernan, Heslop, Emma, Hogan, Patrick, Huang, Boyin, Jiang, Li-qing, Kozyr, Alex, Liu, Chunying, Locarnini, Ricardo, Mishonov, Alexey V., Paver, Christopher, Wang, Zhankun, Zweng, Melissa, Alin, Simone, Barbero, Leticia, Barth, John A., Belbeoch, Mathieu, Cebrian, Just, Connell, Kenneth J., Cowley, Rebecca, Dukhovskoy, Dmitry, Galbraith, Nancy R., Goni, Gustavo, Katz, Fred, Kramp, Martin, Kumar, Arun, Legler, David M., Lumpkin, Rick, Mcmahon, Clive R., Pierrot, Denis, Plueddemann, Albert J., Smith, Emily A., Sutton, Adrienne, Turpin, Victor, Jiang, Long, Suneel, V., Wanninkhof, Rik, Weller, Robert A., and Wong, Annie P. S.

Abstract

The years since 2000 have been a golden age in in situ ocean observing with the proliferation and organization of autonomous platforms such as surface drogued buoys and subsurface Argo profiling floats augmenting ship-based observations. Global time series of mean sea surface temperature and ocean heat content are routinely calculated based on data from these platforms, enhancing our understanding of the ocean’s role in Earth’s climate system. Individual measurements of meteorological, sea surface, and subsurface variables directly improve our understanding of the Earth system, weather forecasting, and climate projections. They also provide the data necessary for validating and calibrating satellite observations. Maintaining this ocean observing system has been a technological, logistical, and funding challenge. The global COVID-19 pandemic, which took hold in 2020, added strain to the maintenance of the observing system. A survey of the contributing components of the observing system illustrates the impacts of the pandemic from January 2020 through December 2021. The pandemic did not reduce the short-term geographic coverage (days to months) capabilities mainly due to the continuation of autonomous platform observations. In contrast, the pandemic caused critical loss to longer-term (years to decades) observations, greatly impairing the monitoring of such crucial variables as ocean carbon and the state of the deep ocean. So, while the observing system has held under the stress of the pandemic, work must be done to restore the interrupted replenishment of the autonomous components and plan for more resilient methods to support components of the system that rely on cruise-based measurements.

Published
2023
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70. ASIRI : An Ocean–Atmosphere Initiative for Bay of Bengal

Author

Wijesekera, Hemantha W., Shroyer, Emily, Tandon, Amit, Ravichandran, M., Sengupta, Debasis, Jinadasa, S. U. P., Fernando, Harindra J. S., Agrawal, Neeraj, Arulananthan, K., Bhat, G. S., Baumgartner, Mark, Buckley, Jared, Centurioni, Luca, Conry, Patrick, Farrar, J. Thomas, Gordon, Arnold L., Hormann, Verena, Jarosz, Ewa, Jensen, Tommy G., Johnston, Shaun, Lankhorst, Matthias, Lee, Craig M., Leo, Laura S., Lozovatsky, Iossif, Lucas, Andrew J., Mackinnon, Jennifer, Mahadevan, Amala, Nash, Jonathan, Omand, Melissa M., Pham, Hieu, Pinkel, Robert, Rainville, Luc, Ramachandran, Sanjiv, Rudnick, Daniel L., Sarkar, Sutanu, Send, Uwe, Sharma, Rashmi, Simmons, Harper, Stafford, Kathleen M., St. Laurent, Louis, Venayagamoorthy, Karan, Venkatesan, Ramasamy, Teague, William J., Wang, David W., Waterhouse, Amy F., Weller, Robert, and Whalen, Caitlin B.

Published
2016

71. Air-Sea Interaction in the Bay of Bengal

Author

Weller, Robert A., Farrar, J. Thomas, Buckley, Jared, Mathew, Simi, Venkatesan, R., Lekha, J. Sree, Chaudhuri, Dipanjan, Kumar, N. Suresh, and Kumar, B. Praveen

Published
2016

73. Hydrographic Observations at the Woods Hole Oceanographic Institution Hawaii Ocean Time-Series Site (WHOTS): 2019-2021, Data Report #16

Author

Carvalho Pacheco, Fernando, Santiago-Mandujano, Fernando, Potemra, James T., Plueddemann, Albert J., Weller, Robert A., Fitzgerald, Daniel, Galbraith, Nancy R., Potemra, James T., Plueddemann, Albert J., Weller, Robert A., Santiago-Mandujano, Fernando, Maloney, Kelsey, Rohrer, Tully, Tabata, Ryan, Howins, Noah, Harris, James, Upper Ocean Processes Group (UOP), Hawaii Ocean Time-series (HOT), University of Hawaiʻi at Mānoa, Woods Hole Oceanographic Institution, Ocean Observing and Monitoring Division, Climate Program Office, National Oceanic and Atmospheric Administration, U.S. Department of Commerce, and National Science Foundation

Subjects
HOT, timeseries, WHOTS Mooring, WHOTS-16 Data Report, FOS: Earth and related environmental sciences, physical oceanography, Oceanography, Hawaii Ocean Time-series, WHOTS, OceanSITES
Abstract

In 2003, Robert Weller (Woods Hole Oceanographic Institution [WHOI]), Albert Plueddemann (WHOI),and Roger Lukas (the University of Hawaii [UH]) proposed to establish a long-term surface mooring at the Hawaii Ocean Time-series (HOT) Station ALOHA (22°45'N, 158°W) to provide sustained, high-quality air-sea fluxes and the associated upper ocean response as a coordinated part of the HOT program, and as an element of the global array of ocean reference stations supported by the National Oceanic and Atmospheric Administration's (NOAA) Office of Climate Observation. The WHOTS-16 mooring was deployed on October 6, 2019, during an eight-day cruise (WHOTS-16 cruise) and was recovered on August 28, 2021, during an eight-day cruise (WHOTS-17 cruise). The cruises were aboard the NOAA Oscar Sette. The seventeenth mooring was deployed on August 26, 2021, during the WHOTS-17 cruise and was recovered on July 25, 2022. This report documents and describes the oceanographic observations made on the WHOTS-16 mooring for nearly one year and ten months and from shipboard measurements during the two cruises when the mooring was deployed and recovered. Sections II and III include a detailed description of the cruises and the mooring, respectively. Sampling and processing procedures of the hydrographic casts, thermosalinograph, and shipboard ADCP data collected during these cruises are described in Section IV . Section V includes the processing procedures for the data collected by the moored instruments: SeaCATs, MicroCATs, Moored ADCPs and VMCM. Plots of the resulting data and preliminary analysis are presented in Section VI., This publication is based upon observations from the WHOI-Hawaii Ocean Time-series Site (WHOTS) mooring, which is supported in part by the National Oceanic and Atmospheric Administration (NOAA) Global Ocean Monitoring and Observing (GOMO) Program through the Cooperative Institute for the North Atlantic Region (CINAR) under Cooperative Agreement NA14OAR4320158. NOAA CPO FundRef number 100007298 to the Woods Hole Oceanographic Institution, and by National Science Foundation grants OCE-0327513,OCE-0752606, OCE-0926766, OCE-1260164 and OCE-1756517 to the University of Hawaii for the Hawaii Ocean Time-series. This is SOEST contribution number 11592, {"references":["Plueddemann, A. J., Weller, R. A., Lukas, R., Lord, J., Bouchard,P. R., & M. Alexander Walsh. (2006). WHOI hawaii ocean timeseries station (WHOTS) : WHOTS-2 mooring turnaround cruise report. Woods Hole Oceanographic Institution. https://doi.org/10.1575/1912/1074","Whelan, S. P., Weller, R. A., Lukas, R., Bradley, F., Lord, J., Smith, J. C., Bahr, F. B., Lethaby, P., & Snyder, J. (2007). WHOI hawaii ocean timeseries station (WHOTS) : WHOTS-3 mooring turnaround cruise report (p. 103). Woods Hole Oceanographic Institution. https://doi.org/10.1575/1912/1825","Whelan, S. P., Plueddemann, A. J., Lukas, R., Lord, J., Lethaby, P., Smith, J. C., Bahr, F. B., Galbraith, N. R., & Sabine, C. L. (2008). WHOI hawaii ocean timeseries station (WHOTS): WHOTS-4 2007 mooring turnaround cruise report. Woods Hole Oceanographic Institution. https://doi.org/https://doi.org/10.1575/1912/2504","Whelan, S. P., Santiago-Mandujano, F., Bradley, F., Plueddemann, A. J., Ludovic Barista, Ryder, J. R., Lukas, R., Lethaby, P., Snyder, J., Sabine, C. L., Stanitski, D., Rapp, A. D., Fairall, C. W., Pezoa, S., Galbraith, N. R., Lord, J., & Bahr, F. B. (2010). WHOI hawaii ocean timeseries station (WHOTS): WHOTS-6 2009 mooring turnaround cruise report. Woods Hole Oceanographic Institution. https://doi.org/https://doi.org/10.1575/1912/3458","Santiago-Mandujano, F., Snyder, J., Natarov, S., Maloney, K., Howins, N., Hebert, G., & Lukas, R. (2019). UH contributions to WHOTS-15 cruise report. School of Ocean and Earth Science and Technology; University of Hawaii. http://www.soest.hawaii.edu/whots/proc_reports/WHOTS-15_CruiseRpt.pdf","Hasbrouck, E., Weller, R., Santiago-Mandujano, F., Blomquist, B., Maloney, K., Snyder, J., Clabaugh, A., Adams, S., Rosburg, K., King, A., Natarov, S., Howins, N., Hebert, G., & Lukas, R. (2019). WHOI hawaii ocean timeseries station (WHOTS) : WHOTS-14 2017 mooring turnaround cruise report (p. 112). Woods Hole Oceanographic Institution. https://doi.org/10.1575/1912/25262","Santiago-Mandujano, F., Fitzgerald, D., Maloney, K., Rohrer, T., Howins, N., Tabata, R., & Potemra, J. (2021). UH contributions to WHOTS-16 cruise report. School of Ocean and Earth Science and Technology, University of Hawaii. https://www.soest.hawaii.edu/whots/proc_reports/UH_Contributions_to_WHOTS16_Cruise_Report.pdf","Santiago-Mandujano, F., Fitzgerald, D., Maloney, K., Rohrer, T., Howins, N., Tabata, R., & Potemra, J. (2022). UH contributions to WHOTS-17 cruise report. School of Ocean and Earth Science and Technology, University of Hawaii. http://www.soest.hawaii.edu/whots/proc_reports/UH%20Contributions%20to%20WHOTS17_Cruise_Report.pdf","Hosom, D. S., Weller, R. A., Payne, R. E., & Prada, K. E. (1995). The IMET (improved meteorology) ship and buoy systems. Journal of Atmospheric and Oceanic Technology, 12(3), 527–540. https://doi.org/2.0.co;2>10.1175/1520-0426(1995)0122.0.co;2","Keir Colbo, & Weller, R. A. (2009). Accuracy of the IMET sensor package in the subtropics. Journal of Atmospheric and Oceanic Technology, 26(9), 1867–1890. https://doi.org/10.1175/2009JTECHO667.1","A. Birol Kara, Rochford, P. A., & Hurlburt, H. E. (2000). Mixed layer depth variability and barrier layer formation over the North Pacific Ocean. Journal of Geophysical Research: Oceans, 105(C7), 16783–16801. https://doi.org/10.1029/2000jc900071","Santiago-Mandujano, F., Lethaby, P., Lukas, R., Snyder, J., Weller, R. A., Plueddemann, A. J., Lord, J., Whelan, S., Bouchard, P., & Galbraith, N. (2007). Hydrographic observations at the woods hole oceanographic institution (WHOI) hawaii ocean timeseries (HOT) site (WHOTS): 2004-2006. School of Ocean and Earth Science and Technology, University of Hawaii. http://uop.whoi.edu/currentprojects/WHOTS/docs/UH_Whots_data_report_1.pdf","Tupas, L., Santiago-Mandujano, F., Hebel, D., Lukas, R., Karl, D., & Firing, E. (1993). Hawaii ocean time-series data report 4, 1992. In SOEST Technical Report 93-14 (p. 248). School of Ocean and Earth Science and Technology, University of Hawaii. https://hahana.soest.hawaii.edu/hot/reports/rep_y4.pdf","Fukieki, L., Santiago-Mandujano, F., Fernando Carvalho Pacheco, Fitzgerald, D., Fitzgerald, D., & White, A. (2021). Hawaii ocean time-series data report 31: 2019 (pp. 1–426). School of Ocean and Earth Science and Technology Publication #11424. https://hahana.soest.hawaii.edu/hot/reports/rep_y31.pdf","W. Brechner Owens, & Millard, R. C. (1985). A new algorithm for CTD oxygen calibration. Journal of Physical Oceanography, 15, 621–631. https://doi.org/2.0.CO;2>10.1175/1520-0485(1985)0152.0.CO;2","Tupas, L., Santiago-Mandujando, F., Hebel, D., Nosse, C., Fujieki, L., Firing, E., Lukas, R., Karl, D., Winn, C., Bidigare, R., Landry, M., & Lopez, M. (1996). Hawaii ocean time-series data report 8, 1996 (pp. 1–286). School of Ocean and Earth Science and Technology, University of Hawaii. https://hahana.soest.hawaii.edu/hot/reports/rep_y8.pdf","Howard Paul Freitag, McCarty, M. E., Nosse, C., Lukas, R., McPhaden, M. J., & Cronin, M. F. (1999). COARE Seacat data: Calibrations and quality control procedures. NOAA Technical Memorandum ERL PMEL-115. https://repository.library.noaa.gov/view/noaa/10999","Firing, E. (1991). Acoustic Doppler current profiling measurements and navigation. WOCE Hydrographic Operations and Methods. WOCE Operations Manual, WHP Office Report WHPO 91-1, WOCE Report No. 68/91; WOCE Hydrographic Programme. https://www.nodc.noaa.gov/archive/arc0013/0001873/1.1/data/1-data/publications/WOCE/ADCP.pdf","Teledyne RD Instruments. (2011). Acoustic doppler current profiler principles of operation a practical primer. In P/N 951-6069-00 (pp. 1–62). http://www.teledynemarine.com/Documents/Brand%20Support/RD%20INSTRUMENTS/Technical%20Resources/Manuals%20and%20Guides/General%20Interest/BBPRIME.pdf","Lukas, R., Santiago-Mandujano, F., Bingham, F., & Mantyla, A. (2001). Cold bottom water events observed in the Hawaii Ocean Time-series: implications for vertical mixing. Deep Sea Research Part I: Oceanographic Research Papers, 48(4), 995–1021. https://doi.org/https://doi.org/10.1016/S0967-0637(00)00078-9","Howe, B. M., Lukas, R., Duennebier, F., & Karl, D. (2011). ALOHA cabled observatory installation. 1–11. https://doi.org/10.23919/OCEANS.2011.6107301"]}

Published
2022
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82. Metaphor

Author

Seligman, Adam B., primary and Weller, Robert P., additional

Published
2018
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98. Religion in the Folded City: Origami and the Boundaries of the Chronotope.

Author

Weller, Robert P. and Wu, Keping

Subjects
*CHRONOTOPE, *ORIGAMI, *URBAN growth, *RELIGIOUS experience, *GEOGRAPHIC boundaries, *RELIGIONS
Abstract

In this article we rethink the chronotope approach by examining what happened to religious space-times in a Chinese urban development project that completely transformed what had once been five relatively rural townships. What happens to chronotopes when a place is so completely transformed? We focus on multiple chronotopic dimensions in the religious experience of those villagers whose families had long occupied this land, but who now live separated from their old neighbors, without their old livelihoods, having lost their old temples, and surrounded by new migrants who are generally wealthier and better educated. Building on recent anthropological work on chronotopes, coupled with insights taken from Maurice Merleau-Ponty and Gilles Deleuze, this article explores the complex interrelationships and workings of chronotopes through the idea of the fold. This approach reconsiders what the boundaries between chronotopes might look like—not necessarily straight lines that are difficult to cross, but more like the infinite inflections of curves as those curves intersect and interact with each other. Rather than thinking of chronotopes as structured wholes separated by clear boundaries—much as we also tend to think about "states," "cultures," or "ontologies"—folding allows us to reconceptualize the kinds of interactions that take place when one space-time touches another. We examine in particular three ways in which folding elucidates how chronotopic boundaries can work: they can make the distant near, separate inside from outside, and complicate the boundary by interdigitating. [ABSTRACT FROM AUTHOR]

Published
2023
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99. Effects of the Pandemic on Observing the Global Ocean

Author

Boyer, Tim, primary, Zhang, Huai-Min, additional, O’Brien, Kevin, additional, Reagan, James, additional, Diggs, Stephen, additional, Freeman, Eric, additional, Garcia, Hernan, additional, Heslop, Emma, additional, Hogan, Patrick, additional, Huang, Boyin, additional, Jiang, Li-Qing, additional, Kozyr, Alex, additional, Liu, Chunying, additional, Locarnini, Ricardo, additional, Mishonov, Alexey V., additional, Paver, Christopher, additional, Wang, Zhankun, additional, Zweng, Melissa, additional, Alin, Simone, additional, Barbero, Leticia, additional, Barth, John A., additional, Belbeoch, Mathieu, additional, Cebrian, Just, additional, Connell, Kenneth J., additional, Cowley, Rebecca, additional, Dukhovskoy, Dmitry, additional, Galbraith, Nancy R., additional, Goni, Gustavo, additional, Katz, Fred, additional, Kramp, Martin, additional, Kumar, Arun, additional, Legler, David M., additional, Lumpkin, Rick, additional, McMahon, Clive R., additional, Pierrot, Denis, additional, Plueddemann, Albert J., additional, Smith, Emily A., additional, Sutton, Adrienne, additional, Turpin, Victor, additional, Jiang, Long, additional, Suneel, V., additional, Wanninkhof, Rik, additional, Weller, Robert A., additional, and Wong, Annie P. S., additional

Published
2023
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