Your search keyword '"Kwok, Ron"' showing total 272 results

251. Improving Group Decision Making: A Fuzzy GSS Approach.

Author

Chi-Wai Kwok, Ron, Jian Ma, and Duanning Zhou

Subjects

*GROUP decision making, *ASSOCIATIONS, institutions, etc.

Abstract

Focuses on the problems in using group decision-making methods for use in organizations. Inability to satisfy decision makers' individual preference; Application of group support system to a group assessment task.

Published

2002

252. Water exchange between the subglacial Lake Vostok and the overlying ice sheet.

Author

Siegert, Martin J. and Kwok, Ron

Subjects

*LAKES, *SEA ice, *OCEAN circulation

Abstract

Presents an analysis of the ice-sheet structure of Lake Vostok in Antarctica. Subglacial melting and net ice loss in the north of the lake; Exchange of significant quantities of water between the base of the ice sheet and the lake waters; Net transfer of impurities from the influent basal ice to the lake water.

Published

2000

253. Arctic Snow Depth, Ice Thickness, and Volume From ICESat‐2 and CryoSat‐2: 2018–2021

Author

Kacimi, Sahra and Kwok, Ron

Abstract

Using ICESat‐2 and CryoSat‐2 freeboards, we examine the variability of monthly Arctic sea ice snow depth, thickness and volume between October 2018 and April 2021. For the 3 years, satellite‐derived estimates captured a decrease in mean April snow depth (∼2.50 cm) and ice thickness (∼0.28 m) equivalent to an ice volume loss of ∼12.5%. Results show greater thinning of multiyear ice with an end‐of‐season thickness in 2021 that is lower by ∼16.1% (0.50 m), with negligible changes over first‐year ice. For the period, sea ice thickness estimates using snow depth from climatology result in thicker ice (by up to ∼0.22 m) with a smaller decrease in multiyear ice thickness (∼0.38 m). An 18‐year satellite record, since the launch of ICESat, points to a loss of ∼6,000 km3or one‐third of the winter Arctic ice volume driven by decline in multiyear‐ice coverage in the multi‐decadal transition to a largely seasonal ice cover. Ice thickness and volume are critical variables for assessing the evolution and response of the polar sea ice cover to a warming climate. Retrieval of sea ice thickness from altimeter freeboards (i.e., the vertical height of the floating ice and snow above the local sea level) requires knowledge of loading due to snow. Until recently, snow depth has been prescribed with a climatology based on historical field records. Using freeboard differences from ICESat‐2 and CryoSat‐2, we are now able to derive snow depth estimates. In this paper we examine the differences between climatological and satellite‐derived snow depth as well as the retrieved ice thicknesses from the two altimeter missions. Their changes for three winters between 2018 and 2021 are documented. Derived ice volume estimates are placed within the context of an 18‐year satellite record. For 2018–2021, the decline in mean Arctic sea ice thickness of ∼0.28 m in spring is largely explained by ∼0.50 m thinning of multiyear iceSatellite‐derived snow depth estimates, when compared to climatology, provide a thinner Arctic ice thickness especially during the fallSatellite records since 2003 show a loss of one‐third of the winter sea ice volume driven by the decline in multiyear ice coverage For 2018–2021, the decline in mean Arctic sea ice thickness of ∼0.28 m in spring is largely explained by ∼0.50 m thinning of multiyear ice Satellite‐derived snow depth estimates, when compared to climatology, provide a thinner Arctic ice thickness especially during the fall Satellite records since 2003 show a loss of one‐third of the winter sea ice volume driven by the decline in multiyear ice coverage

Published

2022

254. Sea Surface Salinity as a Proxy for Arctic Ocean Freshwater Changes

Author

Fournier, Séverine, Lee, Tong, Wang, Xiaochun, Armitage, Thomas W. K., Wang, Ou, Fukumori, Ichiro, and Kwok, Ron

Abstract

The changing Arctic freshwater content and distribution have a significant implications for ocean circulation, climate, and water and biogeochemical cycles. The paucity of in situ salinity measurements in the Arctic Ocean has limited our ability to study Arctic‐Ocean freshwater variability. Although satellite‐derived sea surface height (SSH) and ocean bottom pressure (OBP) have been used together to infer depth‐integrated freshwater content changes, these measurements are limited in sampling and resolution. Motivated by the recent development of sea surface salinity (SSS) remote sensing, we explore the use of SSS as a proxy for Arctic freshwater changes. As a first step, here we conduct a proof‐of‐concept study by analyzing the output of an ocean‐ice state estimation product. We find that SSS variations are coherent with those of SSH‐minus‐OBP across the Arctic basin (with R~ −0.8) except for those in the center of the Beaufort Gyre and the region affected by the subpolar North Atlantic inflow. On Arctic shelves, the linear regression coefficient between SSS and SSH‐minus‐OBP is −0.3 pss/cm or larger in magnitude. The results suggest that SSS is a good proxy for Arctic freshwater changes, and satellite SSH‐minus‐OBP can be used to evaluate satellite SSS quality. Sea surface salinity (SSS) is found to be a good proxy for characterizing fresher changes in much of the Arctic OceanSatellite altimetry‐gravimetry measurements can help evaluate satellite SSS, alleviating the paucity of in situ salinity data for validationThe findings will benefit ongoing cal/val of satellite SSS in the Arctic and ongoing field programs in the Arctic

Published

2020

255. Arctic Sea Ice Volume Export Through Fram Strait From 1992 to 2014

Author

Spreen, Gunnar, Steur, Laura, Divine, Dmitry, Gerland, Sebastian, Hansen, Edmond, and Kwok, Ron

Abstract

The Fram Strait sea ice volume export 1992–2014 is derived by combining sea ice thickness from upward looking sonars (ULS) with satellite observations of sea ice drift and area. Fram Strait is the main gate for sea ice export from the Arctic. The average yearly sea ice export is 2,400 ± 640 km3. The mean and modal ULS ice thickness in Fram Strait decreased by 15% and 21% per decade, respectively, during 1990–2014. Combined with sea ice drift and area this leads to a decrease of the Arctic sea ice volume export of 27 ± 2% per decade between 1992 and 2014. Thus, for the given time period, changes in sea ice export do not drive the sea ice volume decrease in the Arctic Basin. However, for individual years like 2007 and 2012 the ice export likely has contributed to the loss of summer sea ice. Combined with PIOMAS model simulation we estimate that 14% of the total Arctic sea ice volume is exported every year through Fram Strait. This fraction of the total sea ice volume exported per year does not show a trend because the Arctic Basin ice volume is decreasing at a similar rate as the Fram Strait ice volume export. Compared to ice velocities from Acoustic Doppler Current Profiler (ADCP) the satellite ice drift shows good correspondence in variability but a negative bias. Ice volume transport estimates presented here thus should be considered a conservative estimate. We show, however, that the transport estimates are not sensitive to the exact flux gate location. A new, consistent, observation‐based time series of sea ice volume export through Fram Strait is derived for the years 1992 to 2014During that time period the sea ice volume export decreased by 54±4  km3month−1per decade or 27±2% per decadeThe percentage of total available Arctic sea ice volume exported per year stayed at a constant value of about 14%

Published

2020

256. Winter Arctic Sea Ice Thickness From ICESat‐2 Freeboards

Author

Petty, Alek A., Kurtz, Nathan T., Kwok, Ron, Markus, Thorsten, and Neumann, Thomas A.

Abstract

National Aeronautics and Space Administration's (NASA's) Ice, Cloud, and land Elevation Satellite‐2 (ICESat‐2) mission was launched in September 2018 with the primary goal of monitoring our rapidly changing polar regions. The sole instrument onboard, the Advanced Topographic Laser Altimeter System, is now providing routine, very high‐resolution, surface elevation data across the globe, including the Arctic and Southern oceans. In this study, we demonstrate our new processing chain for converting the along‐track ICESat‐2 sea ice freeboard product (ATL10) into sea ice thickness, focusing our initial efforts on the Arctic Ocean. For this conversion, we primarily make use of snow depth and density data from the NASA Eulerian Snow on Sea Ice Model. The coarse resolution (~100 km) snow data are redistributed onto the high‐resolution (approximately 30–100 m) ATL10 freeboards using relationships obtained from snow depth and freeboard data collected by NASA's Operation IceBridge mission. We present regional sea ice thickness distributions and highlight their seasonal evolution through our first winter season of data collection. We include ice thickness uncertainty estimates, while also acknowledging the limitations of these estimates. We generate a gridded monthly thickness product and compare this with various monthly sea ice thickness estimates obtained from European Space Agency's CryoSat‐2 satellite mission, with ICESat‐2 showing consistently lower thicknesses. Finally, we compare our February/March 2019 thickness estimates to ICESat February/March (19 February to 21 March) 2008 ice thickness estimates using the same input assumptions, which show an ~0.37 m or ~20% thinning across an inner Arctic Ocean domain in this 11‐year time period. NASA's ICESat‐2 mission was launched in September 2018 with the primary goal of monitoring our rapidly changing polar regions. The sole instrument onboard is a highly precise laser, which is now providing routine, very high‐resolution, surface height measurements across the globe, including over the Arctic and Southern oceans. In this study, we show new estimates of Arctic sea ice thickness from the first winter season of data collected by ICESat‐2. Sea ice thickness is calculated by combining the measured ICESat‐2 freeboards—the extension of sea ice above sea level—with a new snow on sea ice model. Our derived thicknesses are consistently lower than the thicknesses calculated from ESA's CryoSat‐2 data and the original ICESat mission, which ended in 2008. More work is needed to verify these new thickness estimates. We present new estimates of sea ice thickness derived from ICESat‐2 freeboards for the first Arctic winter season of data collectionWe highlight the regional and seasonal variability in the Arctic winter sea ice freeboard, snow depth, and thickness distributionsOur IS‐2 thickness estimates are consistently thinner than those estimated from CryoSat‐2 data using the same input assumptions

Published

2020

257. Snow in the changing sea-ice systems

Author

Webster, Melinda, Gerland, Sebastian, Holland, Marika, Hunke, Elizabeth, Kwok, Ron, Lecomte, Olivier, Massom, Robert, Perovich, Don, and Sturm, Matthew

Subjects

13. Climate action

Abstract

Snow is the most reflective, and also the most insulative, natural material on Earth. Consequently, it is an integral part of the sea-ice and climate systems. However, the spatial and temporal heterogeneities of snow pose challenges for observing, understanding and modelling those systems under anthropogenic warming. Here, we survey the snow–ice system, then provide recommendations for overcoming present challenges. These include: collecting process-oriented observations for model diagnostics and understanding snow–ice feedbacks, and improving our remote sensing capabilities of snow for monitoring large-scale changes in snow on sea ice. These efforts could be achieved through stronger coordination between the observational, remote sensing and modelling communities, and would pay dividends through distinct improvements in predictions of polar environments.

258. Snow in the changing sea-ice systems

Author

Webster, Melinda, Gerland, Sebastian, Holland, Marika, Hunke, Elizabeth, Kwok, Ron, Lecomte, Olivier, Massom, Robert, Perovich, Don, and Sturm, Matthew

Subjects

13. Climate action

Abstract

Snow is the most reflective, and also the most insulative, natural material on Earth. Consequently, it is an integral part of the sea-ice and climate systems. However, the spatial and temporal heterogeneities of snow pose challenges for observing, understanding and modelling those systems under anthropogenic warming. Here, we survey the snow–ice system, then provide recommendations for overcoming present challenges. These include: collecting process-oriented observations for model diagnostics and understanding snow–ice feedbacks, and improving our remote sensing capabilities of snow for monitoring large-scale changes in snow on sea ice. These efforts could be achieved through stronger coordination between the observational, remote sensing and modelling communities, and would pay dividends through distinct improvements in predictions of polar environments.

259. Evaluation of Sea Ice Kinematics and their Impact on Ice Thickness Distribution in the Arctic

Author

Maslowski, Wieslaw, Kwok, Ron, Meteorology, Physical Oceanography, Murnane, Mark, Maslowski, Wieslaw, Kwok, Ron, Meteorology, Physical Oceanography, Murnane, and Mark

Abstract

Sea ice area and thickness have been on the decline in the Arctic over the past several decades. Understanding the role of ice motion, deformation, and export is important to determining if the Arctic will continue toward seasonal ice coverage or if natural variability is capable of reversing this trend. We have analyzed sea ice model output and satellite data to advance the understanding of potentially critical physical processes and feedbacks in the region. In particular, comparisons of RGPS data and sea ice results from ice-ocean and fully coupled regional climate models have been made to evaluate model skill in representing ice kinematics. Both sea ice model configurations maintain a 1/12o (~9km) horizontal spacing and multiple thickness categories in each grid cell. Advanced model representation of sea ice deformations, combined with high spatial resolution, allow direct comparison with satellite data for resolving small-scale linear kinematic features, which contribute to changes in sea ice thickness distribution. These results offer an improved insight into what forces determine the survivability of sea ice in the Arctic., http://archive.org/details/evaluationofseic109456838, Lieutenant Commander, United States Navy

260. Mechanical calorimetry of large dimyristoylphosphatidylcholine vesicles in the phase transition region

Author

Evans, Evan, primary and Kwok, Ron, additional

Published

1982

261. Effect of anAutomatic Physical Activity Detection & Feedback System in PromotingExercise Compliance of a Virtual Trainer Project: A Randomized Control Trial: 315 Board #156 May 30 9:30 AM - 11:00 AM.

Author

Hui, Stanley Sai-chuen, Kwok, Ron Chi-wai, Tam, Eric Wai-cheung, Mak, Winnie Wing-sze, and Mo, Phoenix Kit-han

Subjects

*CONFERENCES & conventions, *MOTIVATION (Psychology), *SYSTEM integration, *RANDOMIZED controlled trials, *PHYSICAL activity

Published

2018

262. The evolution of outsourcing research: what is the next issue?

Author

Jae-Nam Lee, Huynh, M.Q., Kwok Ron Chi-wai, and Shih-Ming Pi

Published

2000

263. EMERGING TECHNOLOGIES AND APPROACHES FOR IN SITU, AUTONOMOUS: OBSERVING IN THE ARCTIC.

Author

Lee, Craig M., DeGrandpre, Michael, Guthrie, John, Hill, Victoria, Kwok, Ron, Morison, James, Cox, Christopher J., Singh, Hanumant, Stanton, Timothy P., and Wilkinson, Jeremy

Subjects

*TECHNOLOGICAL innovations, *CLIMATE change, *REMOTE sensing

Abstract

Understanding and predicting Arctic change and its impacts on global climate requires broad, sustained observations of the atmosphere-ice-ocean system, yet technological and logistical challenges severely restrict the temporal and spatial scope of observing efforts. Satellite remote sensing provides unprecedented, pan-Arctic measurements of the surface, but complementary in situ observations are required to complete the picture. Over the past few decades, a diverse range of autonomous platforms have been developed to make broad, sustained observations of the ice-free ocean, often with near-real-time data delivery. Though these technologies are well suited to the difficult environmental conditions and remote logistics that complicate Arctic observing, they face a suite of additional challenges, such as limited access to satellite services that make geolocation and communication possible. This paper reviews new platform and sensor developments, adaptations of mature technologies, and approaches for their use, placed within the framework of Arctic Ocean observing needs. [ABSTRACT FROM AUTHOR]

Published

2022

264. Effect of GSS on knowledge acquisition

Author

Kwok, Ron C.W and Khalifa, Mohamed

Published

1998

265. Comparing Coincident Elevation and Freeboard From IceBridge and Five Different CryoSat-2 Retrackers.

Author

Yi, Donghui, Kurtz, Nathan, Harbeck, Jeremy, Kwok, Ron, Hendricks, Stefan, and Ricker, Robert

Subjects

*SPACE-based radar, *SEA ice, *ATMOSPHERIC models, *REMOTE sensing by radar, *ARTIFICIAL satellites

Abstract

The airborne Operation IceBridge and spaceborne CryoSat-2 missions observe polar sea ice at different spatial and temporal scales as well as with different sensor suites. Comparison of data products from IceBridge and CryoSat-2 is complicated by the fact that they use different geophysical corrections: reference ellipsoid, geoid model, tide model, and atmospheric corrections to derive surface elevation and sea-ice freeboard. In this paper, we compare sea-ice surface elevation and freeboard using eight coincident CryoSat-2, Airborne Topographic Mapper (ATM), and Land, Vegetation, and Ice Sensor (LVIS) observations with direct IceBridge underflights of CryoSat-2 ground tracks. We apply identical geophysical corrections to CryoSat-2 and IceBridge data to eliminate elevation biases due to these differences and focus on differences due to retracker performance. The IceBridge ATM and LVIS elevation and freeboard and Snow Radar snow depth data sets are averaged to each CryoSat-2 footprint for comparison. With snow depth measurements, we are able to compare elevations and freeboards at the snow/ice interface for five different CryoSat-2 retrackers (ESA, GSFCv1, AWI, JPL, and GSFCv2) and IceBridge. The overall mean of freeboard differences between GSFCv2, ESA, AWI, JPL retrackers, and ATM are in agreement within 0.05 m. However, the five different CryoSat-2 retrackers show distinct differences in mean elevation over leads and over floes. This suggests that the physical interpretation of the different retrackers needs to be considered depending on usage, for example, elevations from CryoSat-2 retrackers need to be carefully calibrated before comparing with elevation from other satellites for long-term surface elevation trends. [ABSTRACT FROM AUTHOR]

Published

2019

266. The Ice, Cloud, and land Elevation Satellite-2 (ICESat-2): Science requirements, concept, and implementation.

Author

Markus, Thorsten, Neumann, Tom, Martino, Anthony, Abdalati, Waleed, Brunt, Kelly, Csatho, Beata, Farrell, Sinead, Fricker, Helen, Gardner, Alex, Harding, David, Jasinski, Michael, Kwok, Ron, Magruder, Lori, Lubin, Dan, Luthcke, Scott, Morison, James, Nelson, Ross, Neuenschwander, Amy, Palm, Stephen, and Popescu, Sorin

Subjects

*ICE clouds, *ALTIMETRY, *THICKNESS measurement, *SCIENTIFIC community, *METEOROLOGICAL observations

Abstract

The Ice, Cloud, and land Elevation Satellite (ICESat) mission used laser altimetry measurements to determine changes in elevations of glaciers and ice sheets, as well as sea ice thickness distribution. These measurements have provided important information on the response of the cryopshere (Earth's frozen surfaces) to changes in atmosphere and ocean condition. ICESat operated from 2003 to 2009 and provided repeat altimetry measurements not only to the cryosphere scientific community but also to the ocean, terrestrial and atmospheric scientific communities. The conclusive assessment of significant ongoing rapid changes in the Earth's ice cover, in part supported by ICESat observations, has strengthened the need for sustained, high accuracy, repeat observations similar to what was provided by the ICESat mission. Following recommendations from the National Research Council for an ICESat follow-on mission, the ICESat-2 mission is now under development for planned launch in 2018. The primary scientific aims of the ICESat-2 mission are to continue measurements of sea ice freeboard and ice sheet elevation to determine their changes at scales from outlet glaciers to the entire ice sheet, and from 10s of meters to the entire polar oceans for sea ice freeboard. ICESat carried a single beam profiling laser altimeter that produced ~ 70 m diameter footprints on the surface of the Earth at ~ 150 m along-track intervals. In contrast, ICESat-2 will operate with three pairs of beams, each pair separated by about 3 km cross-track with a pair spacing of 90 m. Each of the beams will have a nominal 17 m diameter footprint with an along-track sampling interval of 0.7 m. The differences in the ICESat-2 measurement concept are a result of overcoming some limitations associated with the approach used in the ICESat mission. The beam pair configuration of ICESat-2 allows for the determination of local cross-track slope, a significant factor in measuring elevation change for the outlet glaciers surrounding the Greenland and Antarctica coasts. The multiple beam pairs also provide improved spatial coverage. The dense spatial sampling eliminates along-track measurement gaps, and the small footprint diameter is especially useful for sea surface height measurements in the often narrow leads needed for sea ice freeboard and ice thickness retrievals. The ICESat-2 instrumentation concept uses a low energy 532 nm (green) laser in conjunction with single-photon sensitive detectors to measure range. Combining ICESat-2 data with altimetry data collected since the start of the ICESat mission in 2003, such as Operation IceBridge and ESA's CryoSat-2, will yield a 15 + year record of changes in ice sheet elevation and sea ice thickness. ICESat-2 will also provide information of mountain glacier and ice cap elevations changes, land and vegetation heights, inland water elevations, sea surface heights, and cloud layering and optical thickness. [ABSTRACT FROM AUTHOR]

Published

2017

267. Modeled Trends in Antarctic Sea Ice Thickness.

Author

Holland, Paul R., Bruneau, Nicolas, Enright, Clare, Losch, Martin, Kurtz, Nathan T., and Kwok, Ron

Subjects

*SEA ice drift, *CLIMATE change, *ATMOSPHERIC circulation, *WATER quality

Abstract

Unlike the rapid sea ice losses reported in the Arctic, satellite observations show an overall increase in Antarctic sea ice concentration over recent decades. However, observations of decadal trends in Antarctic ice thickness, and hence ice volume, do not currently exist. In this study a model of the Southern Ocean and its sea ice, forced by atmospheric reanalyses, is used to assess 1992-2010 trends in ice thickness and volume. The model successfully reproduces observations of mean ice concentration, thickness, and drift, and decadal trends in ice concentration and drift, imparting some confidence in the hindcasted trends in ice thickness. The model suggests that overall Antarctic sea ice volume has increased by approximately 30 km3 yr−1 (0.4% yr−1) as an equal result of areal expansion (20 × 103 km2 yr−1 or 0.2% yr−1) and thickening (1.5 mm yr−1 or 0.2% yr−1). This ice volume increase is an order of magnitude smaller than the Arctic decrease, and about half the size of the increased freshwater supply from the Antarctic Ice Sheet. Similarly to the observed ice concentration trends, the small overall increase in modeled ice volume is actually the residual of much larger opposing regional trends. Thickness changes near the ice edge follow observed concentration changes, with increasing concentration corresponding to increased thickness. Ice thickness increases are also found in the inner pack in the Amundsen and Weddell Seas, where the model suggests that observed ice-drift trends directed toward the coast have caused dynamical thickening in autumn and winter. Modeled changes are predominantly dynamic in origin in the Pacific sector and thermodynamic elsewhere. [ABSTRACT FROM AUTHOR]

Published

2014

268. Can learning be virtually boosted? An investigation of online social networking impacts

Author

Yu, Angela Yan, Tian, Stella Wen, Vogel, Douglas, and Chi-Wai Kwok, Ron

Subjects

*SOCIAL network research, *SOCIAL learning, *COLLEGE students, *ACADEMIC achievement, *SOCIAL acceptance

Abstract

Online social networking has deeply penetrated university campuses, influencing multiple aspects of student life. We investigate the impacts of individual online social networking engagement (e.g., on Facebook) from a pedagogical standpoint. Based on social learning theory, we argue that two socialization processes, social acceptance and acculturation, bridge individual online social networking engagement with three domains of social learning outcomes. Results from a survey accompanied by focus group discussions demonstrate the substantial impacts of university student online social networking engagement on social learning processes and outcomes. Online social networking not only directly influences university students’ learning outcomes, but also helps the students attain social acceptance from others and adapt to university culture, both of which play prominent roles in improving their learning outcomes. [Copyright &y& Elsevier]

Published

2010

269. Evaluation of Sea Ice Kinematics and their Impact on Ice Thickness Distribution in the Arctic

Author

Murnane, Mark, Maslowski, Wieslaw, Kwok, Ron, Meteorology, and Physical Oceanography

Subjects

Arctic Ocean, Sea Ice Variability, Astrophysics::Earth and Planetary Astrophysics, Sea Ice Thickness Distribution, Sea Ice Dynamics, Physics::Atmospheric and Oceanic Physics, Physics::Geophysics, Coupled Ice-Ocean Model

Abstract

Sea ice area and thickness have been on the decline in the Arctic over the past several decades. Understanding the role of ice motion, deformation, and export is important to determining if the Arctic will continue toward seasonal ice coverage or if natural variability is capable of reversing this trend. We have analyzed sea ice model output and satellite data to advance the understanding of potentially critical physical processes and feedbacks in the region. In particular, comparisons of RGPS data and sea ice results from ice-ocean and fully coupled regional climate models have been made to evaluate model skill in representing ice kinematics. Both sea ice model configurations maintain a 1/12o (~9km) horizontal spacing and multiple thickness categories in each grid cell. Advanced model representation of sea ice deformations, combined with high spatial resolution, allow direct comparison with satellite data for resolving small-scale linear kinematic features, which contribute to changes in sea ice thickness distribution. These results offer an improved insight into what forces determine the survivability of sea ice in the Arctic. http://archive.org/details/evaluationofseic109456838 Lieutenant Commander, United States Navy

Published

2012

270. Microwave Radiometry at Frequencies From 500 to 1400 MHz: An Emerging Technology for Earth Observations.

Author

Johnson JT, Jezek KC, Macelloni G, Brogioni M, Tsang L, Dinnat EP, Walker JP, Ye N, Misra S, Piepmeier JR, Bindlish R, LeVine DM, O'Neill PE, Kaleschke L, Andrews MJ, Yardim C, Aksoy M, Durand M, Chen CC, Demir O, Bringer A, Miller JZ, Brown ST, Kwok R, Lee T, Kerr Y, Entekhabi D, Peng J, Colliander A, Chan S, MacGregor JA, Medley B, DeRoo R, and Drinkwater M

Abstract

Microwave radiometry has provided valuable spaceborne observations of Earth's geophysical properties for decades. The recent SMOS, Aquarius, and SMAP satellites have demonstrated the value of measurements at 1400 MHz for observing surface soil moisture, sea surface salinity, sea ice thickness, soil freeze/thaw state, and other geophysical variables. However, the information obtained is limited by penetration through the subsurface at 1400 MHz and by a reduced sensitivity to surface salinity in cold or wind-roughened waters. Recent airborne experiments have shown the potential of brightness temperature measurements from 500-1400 MHz to address these limitations by enabling sensing of soil moisture and sea ice thickness to greater depths, sensing of temperature deep within ice sheets, improved sensing of sea salinity in cold waters, and enhanced sensitivity to soil moisture under vegetation canopies. However, the absence of significant spectrum reserved for passive microwave measurements in the 500-1400 MHz band requires both an opportunistic sensing strategy and systems for reducing the impact of radio-frequency interference. Here, we summarize the potential advantages and applications of 500-1400 MHz microwave radiometry for Earth observation and review recent experiments and demonstrations of these concepts. We also describe the remaining questions and challenges to be addressed in advancing to future spaceborne operation of this technology along with recommendations for future research activities.

Published

2021

271. Enhanced eddy activity in the Beaufort Gyre in response to sea ice loss.

Author

Armitage TWK, Manucharyan GE, Petty AA, Kwok R, and Thompson AF

Abstract

The Beaufort Gyre freshwater content has increased since the 1990s, potentially stabilizing in recent years. The mechanisms proposed to explain the stabilization involve either mesoscale eddy activity that opposes Ekman pumping or the reduction of Ekman pumping due to reduced sea ice-ocean surface stress. However, the relative importance of these mechanisms is unclear. Here, we present observational estimates of the Beaufort Gyre mechanical energy budget and show that energy dissipation and freshwater content stabilization by eddies increased in the late-2000s. The loss of sea ice and acceleration of ocean currents after 2007 resulted in enhanced mechanical energy input but without corresponding increases in potential energy storage. To balance the energy surplus, eddy dissipation and its role in gyre stabilization must have increased after 2007. Our results imply that declining Arctic sea ice will lead to an increasingly energetic Beaufort Gyre with eddies playing a greater role in its stabilization.

Published

2020

272. Changing Arctic Ocean freshwater pathways.

Author

Morison J, Kwok R, Peralta-Ferriz C, Alkire M, Rigor I, Andersen R, and Steele M

Subjects

Arctic Regions, Atmospheric Pressure, Canada, Climate, Ice Cover, Oceans and Seas, Salinity, Seawater analysis, Wind, Fresh Water analysis, Water Movements

Abstract

Freshening in the Canada basin of the Arctic Ocean began in the 1990s and continued to at least the end of 2008. By then, the Arctic Ocean might have gained four times as much fresh water as comprised the Great Salinity Anomaly of the 1970s, raising the spectre of slowing global ocean circulation. Freshening has been attributed to increased sea ice melting and contributions from runoff, but a leading explanation has been a strengthening of the Beaufort High--a characteristic peak in sea level atmospheric pressure--which tends to accelerate an anticyclonic (clockwise) wind pattern causing convergence of fresh surface water. Limited observations have made this explanation difficult to verify, and observations of increasing freshwater content under a weakened Beaufort High suggest that other factors must be affecting freshwater content. Here we use observations to show that during a time of record reductions in ice extent from 2005 to 2008, the dominant freshwater content changes were an increase in the Canada basin balanced by a decrease in the Eurasian basin. Observations are drawn from satellite data (sea surface height and ocean-bottom pressure) and in situ data. The freshwater changes were due to a cyclonic (anticlockwise) shift in the ocean pathway of Eurasian runoff forced by strengthening of the west-to-east Northern Hemisphere atmospheric circulation characterized by an increased Arctic Oscillation index. Our results confirm that runoff is an important influence on the Arctic Ocean and establish that the spatial and temporal manifestations of the runoff pathways are modulated by the Arctic Oscillation, rather than the strength of the wind-driven Beaufort Gyre circulation.

Published

2012