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        <h3>Momme Hell<span class="light_sub"> | ASP Postdoctural Fellow | NSF NCAR</span></h3>

        <h1></br></br></br></br></br>
            Air-Sea Interaction Across Scales</br> 
            <span class="light_sub">Winds | Waves | Sea Ice</span>
         </h1> 
        
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            <a href="#home">Home</a>
            <a href="pics/CV_mhell.pdf">CV</a>
            <a href="#research">Research</a>
            <a href="#publications">Publications</a>

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<section>
    <div class="bio">
        <img src="pics/230921_mHell.jpg" alt="Researcher Image">
        <h2>Momme C. Hell</h2>
        Postdoctoral Fellow in the Advanced Study Program <br>
        <p>
        NSF National Center for Atmospheric Research<br>
        CISL/CGD, Ocean Section<br>
        Boulder, CO<br>
        </span>


          <span class="adress">
          mhell @ ucar.edu<p>
          <a href="pics/CV_mhell.pdf" target=blank>Curriculum Vitae</a><p>

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    <div class="text">
<p>I joined NSF NCAR as a Postdoctoral Fellow in the ASP program in Fall 2023 to develop and implement and a fast and efficient wave model in coupled earth system models jointly between Computational and  
Information Systems Lab (<a href="https://www2.cisl.ucar.edu/" target=blank>CISL</a>) and the Climate & Global Dynamics (<a href="https://www.cgd.ucar.edu/" target=blank>CGD</a>) section. Before that I was Postdoctoral Research Associate in the Department for Earth, Environmental and Planetary Sciences (DEEPS) at Brown Univeristy (now visiting Research Scholar) with <a href="http://fox-kemper.com/" target=blank>Baylor Fox-Kemper</a> and <a href="http://www.chrv.at" target=blank>Chris Horvat</a>.</p>

<p>I graduated from <a href="https://scripps.ucsd.edu" target=blank>Scripps Institution of Oceanography (SIO)</a> in November 2020 in Physical Oceanography with my advisors <a href="http://meteora.ucsd.edu/miller/" target=blank >Arthur "Art" Miller</a>, <a href="http://pordlabs.ucsd.edu/sgille/" target=blank>Sarah Gille</a>, and <a href="https://bcornuelle.scrippsprofiles.ucsd.edu/" target=blank>Bruce Cornuelle</a>, and short postdoc with <a href="https://nicklutsko.github.io" target=blank >Nick Lutsko</a>.  Prior to that I studied at GEOMAR in Kiel (2009-2012) and ETH Zurich (2013-2015) Atmosphere, Ocean, and Climate working with Tapio Schneider, Noel Keenlyside and Mojib Latif.</p>

<p>My research focuses on processes that are related to large biases in climate models and the predictability of
mid-latitude weather. My topics spans from ocean surface waves to large-scale Rossby-waves and the atmospheric general
circulation. I currently focus on:</p>

        <h5>&#x2022; Stochastic air-sea fluxes</h5>
        <h5>&#x2022; Open-ocean surface wave modeling</h5>
        <h5>&#x2022; Sea ice-wave coupling</h5>
        <h5>&#x2022; Ocean remote sensing observations</h5>
        <h5>&#x2022; Climate dynamics and weather extremes</h5><p>
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<section id="research">
        <h2>Research Projects</h2><br>
</section>
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            <h2>Surface waves govern air-sea exchange</h2>
            <p>The sea state controls momentum transfer across the air-sea boundary and alters the surface stress, fluxes of CO2, and heat between the atmosphere and the ocean. I focus on how synoptic-scale variability influences Air-Sea exchange through waves or upper ocean turbulence. I combine simple models of surface wave generation with optimization methods to apply them to ensembles of wave observations.</p>
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            <h2>Swell generation under extra-tropical storms</h2>
            <p>Storms generate swell events that many like to surf. I study how the dynamics of the storm determine the generated swell. For that, I use idealized models, observations from wave buoys and remote sensing data, and non-linear optimization methods to understand the process of wave generation on the synoptic scale.</p>

            The key mechanism that leads to the generation of major swell events is trapping wave energy under the moving storm (figure on the left). To understand this, one has to think of wave energy propagation in the reference system of the moving storm. While the wave energy of a short wave travels slower and will be left behind, the wave energy of longer waves will keep up with the moving storm and be further enhanced.<br>

            This mechanism compresses the wave energy to a small area, appearing as a small, localized swell source in the open ocean. Stronger storms that move faster will generate larger swell events, while storms that propagate too fast are less efficient in creating strong swell events.<br>

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        <h2>Surface Winds</h2>
        always play a role for air-sea coupling. Surface winds force the ocean on synoptic scales, but they are also in
        constant
        feedback with the ocean. Surface temperature pattern can change the local winds, and current can change waves.
        Surface
        winds have to be seen as one aspect of the coupled air-sea boundary layer.
        
        In my research I focus on statistical representation of surface winds over the ocean. Remote sensing product,
        reanalysis
        data, and state-of-the-art high resolution models allow us to derive wind statistics that vary in space and
        time. A
        closer lock to these wind statistics show that their shape, i.e. the shape of their PDFs, is not gaussian and
        can be
        expressed as the superposition of empirical modes.
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        <h2>Leading modes of surface winds are driven by annular mode variability</h2>
        <p>
            The leading modes of the surface wind PDF are connected to large-scale drivers of in the atmosphere. For example, the statistics of winds in the mid-latitudes are driven by the momentum balance of the atmospheric column aloft. This provides new insight in how and where surface wind statistics and subsequent air-sea fluxes may change under global warming, as the global warming signal starts to emerge in the large-scale flow. That means we can use the leading mode of the scatterometer wind distribution (upper right panels) to infer the phase of the Annular Mode (black and blue line on the bottom). See more in the publication below</p>
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        <div class="image60" >
        <img src="pics/wavesinicesketch.png" alt="Research Example Image">
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        <h2>Waves in Sea Ice</h2> 
        We start to observe waves in sea ice. Waves can break up, disperse, or drift sea ice and alter air-sea heat fluxes within the sea ice. They play a major role in globally retreating sea ice, but the interaction needs to be better understood. In my work, I use satellite and in situ observations to better understand how waves surface waves behave in sea ice.

        Waves in the Marginal Ice Zone (MIZ) are a dominant source for the mechanical breaking of sea ice with potentially enormous consequences for the air-sea exchange in the MIZ. I study the impact of waves on sea ice through remote sensing and idealized models to better represent these processes in climate models.

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<section class="publications", id="publications">
    <h2>Publications</h2>

    <!-- Submitted Papers 
    <h3>Submitted Papers</h3>
            <span class="bib">
                <span class="bib-name">Hell, M. C.</span>, Armi, L., Atmospheric zonal flows and blocks from the perspective of Rossby-beta hydraulics. <i>submitted to QJRMS</i>.<p>
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    <!-- Accepted Papers -->
    <h3>Accepted Papers</h3>


            <span class="bib">
                <span class="bib-name">Hell, M. C.</span>, and Horvat, C. Directional Surface Wave Spectra And Sea Ice Structure
                from ICEsat-2 Altimeter,<i>The Cryosphere,</i>(accepted)<br>
                <a href="https://doi.org/10.5194/egusphere-2022-842">https://doi.org/10.5194/egusphere-2022-842</a>
                <p>
            </span>
            
            <span class="bib">
                Woollings, T., and Coauthors including <span class="bib-name">Hell, M.</span>, The role of Rossby waves in polar
                weather and climate. <i>Weather and Climate Dynamics Discussions</i>, (2022), 1–32,<br><a
                    href="https://doi.org/10.5194/wcd-2022-43">https://doi.org/10.5194/wcd-2022-43</a>
                <p>
            </span>

            <span class="bib">
                Lutsko, N. J., <span class="bib-name">Hell, M. C.</span> Moisture and the Persistence of Annular Modes (2021). <i>Journal of Atmospheric Science</i>.<br>
                <a href="https://doi.org/10.1175/JAS-D-21-0055.1">https://doi.org/10.1175/JAS-D-21-0055.1</a> <p>
            </span>

            <span class="bib">
                <span class="bib-name">Hell, M. C.</span>, Ayet, A, Chapron, B. (2021) Swell Generation under Extra-Tropical Storms. <i>Journal of Geophysical Research: Oceans</i>, 126, e2021JC017637, 2021.<br>
                <a href="https://doi.org/10.1029/2021JC017637">https://doi.org/10.1029/2021JC017637</a> [<a href="https://www.essoar.org/doi/abs/10.1002/essoar.10507273.1" target=blank>preprint</a>]<p>
            </span>

            <span class="bib">
                <span class="bib-name">Hell, M. C.</span>, Cornuelle, B. D., Gille, S. T., Lutsko, N. J., 2021: Time-Varying Empirical Probability Densities of Southern Ocean Surface Winds: Linking the Leading Mode to SAM and Quantifying Wind Product Differences. <i>Journal of Climate</i> <br><a href="https://doi.org/10.1175/JCLI-D-20-0629.1">https://doi.org/10.1175/JCLI-D-20-0629.1</a>.  [<a href="https://www.youtube.com/watch?v=qE3398GFsvY" target=blank>conference talk</a>]<p>
            </span>

            <span class="bib">
                <span class="bib-name">Hell, M. C.</span>, Gille, S. T., Cornuelle, B., Miller, A. J., Bromirski, P. D., & Crawford, A. D, 2020: Estimating Southern Ocean storm position with seismic observations. <i>Journal of Geophysical Research: Oceans</i>, 125, e2019JC015898.<br><a href="https://doi.org/10.1029/2019JC015898">https://doi.org/10.1029/2019JC015898</a> <p>
            </span>

            <span class="bib">
                <span class="bib-name">Hell, M.</span>, Schneider, T., Li, C.,2019: Atmospheric Circulation Response to Episodic Arctic Warming in an Idealized Model. Journal of Atmospheric Science,<a href="https://journals.ametsoc.org/doi/10.1175/JAS-D-19-0133.1">https://journals.ametsoc.org/doi/10.1175/JAS-D-19-0133.1</a> <p>
            </span>

            <span class="bib">
                <span class="bib-name">Hell, M. C.</span>, B. D. Cornuelle, S. T. Gille, A. J. Miller, and P. D. Bromirski, 2019: Identifying ocean swell generation events from Ross Ice Shelf seismic data. J. Atmos. Oceanic Technol.,<a href="https://doi.org/10.1175/JTECH-D-19-0093.1">https://doi.org/10.1175/JTECH-D-19-0093.1</a> <p>
            </span>

            <span class="bib">
                Villas Bôas, A. B., and <span class="bib-name">Coauthors</span>, 2019: Integrated Observations of Global Surface Winds, Currents, and Waves: Requirements and Challenges for the Next Decade. Front. Mar. Sci., 6, <a href="https://doi.org/10.3389/fmars.2019.00425">https://doi.org/10.3389/fmars.2019.00425</a>
            <p></span>

            <span class="bib">
                Cohen, J., and <span class="bib-name">Coauthors</span>, 2018: Arctic change and possible influence on mid-latitude climate and weather. US clivar Rep, N/A,<br><a href="https://doi.org/10.5065/D6TH8KGW">https://doi.org/10.5065/D6TH8KGW</a> <p>
            </span>

            <span class="bib">
                King, M.P., <span class="bib-name">Hell, M.</span> & Keenlyside, N. Investigation of the atmospheric mechanisms related to the autumn sea ice and winter circulation link in the Northern Hemisphere. Clim Dyn ,2016, 46: 1185. <a href="https://link.springer.com/article/10.1007/s00382-015-2639-5">https://doi.org/10.1007/s00382-015-2639-5</a> <p>
            </span>

    <h3>Theses</h3>
            <span class="bib"><span class="bib-name">Momme Hell</span>, 
            Einfluss der atlantischen Meeresoberflächentemperatur auf Niederschläge in Indien und dem Sahel im Kieler Klimamodell, Bachelor Thesis, University of Kiel, 2012, Advisors: Mojib Latif and Claus Boening<p></span>
            
            <span class="bib"><span class="bib-name">Momme Hell</span>, 
            High Arctic-Stratosphere-Feedback on Sub-Seasonal Scale, Master Thesis, Swiss Federal Institute of Technology in Zurich, 2015, Advisors: Tapio Schneider and Noel Keenlyside<p></span>
            
            <span class="bib"><span class="bib-name">Hell, M.</span>, Einfluss der atlantischen Meeresoberflächentemperatur auf Niederschläge in Indien und dem Sahel im Kieler Klimamodell, 2012, Bachelor Thesis, University of Kiel, Advisors: Mojib Latif and Claus Boening [<a href="https://oceanrep.geomar.de/id/eprint/19981/1/938677_Ba_MHell.pdf">PDF</a>]<p></span>

</section>
<section class="publications">
    <h2>Invited Talks & Presentations</h2>

    <h4>2023</h4>
    <span class="bib"><span class="bib-name">Hell, M. C.</span> and Chris Horvat. Learning surface wave spectra and sea ice structure from icesat-2 altimeter - an path to better wave attenuation parametrization in the marginal ice zone. ICESat-2 Science Team Meeting, La Jolla, CA, USA, 2023-10-03<br></span>

    <span class="bib"><span class="bib-name">Hell, M. C.</span> and Baylor Fox-Kemper. Bulk fluxes in earth system models and beyond - how converging scales may lead to diverging results. Workshop at the Lorenz Center: Atmosphere-ocean coupling at (sub)mesoscales, Leiden, Nederlands, 2023-09-26<br></span>

    <span class="bib"><span class="bib-name">Hell, M. C.</span>, Baylor Fox-Kemper, Bertrand Chapron, and Chris Horvat. Modeling and observing waves in sea ice. SASIP Annual Project meeting, Bergen, Norway, 2023-06-29<br></span>

    <span class="bib"><span class="bib-name">Hell, M. C.</span>. Southern ocean extreme wind statistics and their effect on resonant swell generation under storms. BCCR seminar, GFI, Bergen, Norway, 2023-06-26<br></span>
    
    <span class="bib"><span class="bib-name">Hell, M. C.</span>. When the ocean is not flat - Rough challenges of waves in sea-ice, models, and air-sea coupling. Woods Hole Oceanographic Institution, PO Seminar, 2023-05-03<br></span>
    
    <span class="bib"><span class="bib-name">Hell, M. C.</span>. Southern ocean extreme wind statistics and their effect on resonant swell generation under storms (virtual). MAXSS 2023 : Marine Atmosphere
        eXtreme Satellite Synergy workshop, Brest, France, 2023-04-04<br></span>
    
    <span class="bib"><span class="bib-name">Hell, M. C.</span> and Baylor Fox-Kemper. A particle-in-cell wave model for efficient sea-state and swell estimates in coupled models (virtual). CESM Ocean Model
        Winter Working Group meeting - Boulder, CO, USA, 2023-02-10<br></span>
    
    <span class="bib"><span class="bib-name">Hell, M. C.</span>, Alex Ayet, and B. Chapron. Swell generation under
        extra-tropical storms. AMS 2023 Session on Extreme Maritime Weather, Denver, 2023-01-10<br></span>
    
    <h4>2022</h4>
    <span class="bib"><span class="bib-name">Hell, M. C.</span>. Towards data-driven parameterizations with directional surface wave spectra from icesat-2 altimetry. IMSI Remote Sensing for Climate Analysis - Chicago, US, 2022-12-01<br></span>
    
    <span class="bib"><span class="bib-name">Hell, M. C.</span>. Southern ocean surface winds - how annular modes are linked to surface wave events and wind-driven mixing. NOAA Earth System Research Laboratories in Boulder, Colorado, 2022-11-02<br></span>
    
    <span class="bib"><span class="bib-name">Hell, M. C.</span> and Chris Horvat. Directional surface wave spectra and sea ice structure from ICESat-2 altimeter. SASIP Meeting 2022 - Grenoble, France, 2022-06-21<br></span>
    
    <span class="bib"><span class="bib-name">Hell, M. C.</span>. How annular modes are linked surface wave events and wind-driven mixing. Atmosphere Ocean Science Colloquium, NYU, New York, 2022-03-30<br></span>
    
    <span class="bib"><span class="bib-name">Hell, M. C.</span> and Chris Horvat. Directional surface wave spectra and sea-ice structure from ICESat-2 altimeter. ICESat-2 Science Team - Sea Ice Group, (virtual), 2022-03-17<br></span>
    
    <span class="bib"><span class="bib-name">Hell, M. C.</span> and Chris Horvart. Constraining frequency dependent wave attenuation in sea ice using ICESat-2 photon heights. Ocean Sciences Meeting, (virtual), 2022-02-24<br></span>
    
    <span class="bib"><span class="bib-name">Hell, M. C.</span>, Bruce D. Cornuelle, S. T. Gille, and Nicholas J. Lutsko. Time-varying empirical probability densities of Southern Ocean surface winds: Leading modes linked to SAM, the annual cycle, and product differences. PO Seminar, Woods Hole, MA, 2022-01-18<br></span>
    

    <h4>2021</h4>
    <span class="bib"><span class="bib-name">Hell, M. C.</span>, Alex Ayet, and B. Chapron. Swell generation under extra-tropical storms. MIT, virtual, 2021-10-06<br></span>
    
    <span class="bib"><span class="bib-name">Hell, M. C.</span> and Laurence Armi. Atmospheric zonal flows and blocks from the perspective of Rossby-beta hydraulics (talk). Atmospheric Blocking Virtual Workshop, (virtual), 2021-09-27<br></span>
    
    <span class="bib"><span class="bib-name">Hell, M. C.</span>, Bruce D. Cornuelle, and Sarah T Gille. Leading modes and biases of Southern Ocean Surface Wind from time-varying Distributions. SOCCOM Annual Meeting, (virtual), 2021-06<br></span>
    
    <span class="bib"><span class="bib-name">Hell, M. C.</span>, Bruce D. Cornuelle, S. T. Gille, and Nicholas J. Lutsko. Time-varying empirical probability densities of Southern Ocean surface winds: Leading modes linked to SAM, the annual cycle, and product differences. IOVWST Meeting, (virtual), 2021-02-24<br></span>

    <h4>2015-2019</h4>

        <!-- <h4>Invited</h4> -->
            <span class="bib"><span class="bib-name">Hell, M. C.</span>, Schneider, T., Li, C. Atmospheric Circulation Response to Episodic Arctic Warming in an Idealized Model, 22th Atmosphere and Ocean Fluid Dynamics Meeting, June 2019<br></span>

            <span class="bib"><span class="bib-name">Hell, M. C.</span>, Cornuelle, B., Gille, S. T., Miller, A., Bromirski, P., Crawford A. D., Southern Ocean Storm positions and wave attenuation under sea ice estimated with seismic observations in the Ross Ice Shelf, ACDC 10-year anniversary conference, March 2018, Rondanau, Norway<br></span>

            <span class="bib"><span class="bib-name">Hell, M. C.</span>, Cornuelle, B., Gille, S. T., Miller, A., Bromirski, P., Crawford A. D., Biases in Southern Ocean storm positions from seismic observations in the Ross Ice Shelf. Or, why is the SoCal south swell forecast often wrong?, Scripps Student Symposium 2018, La Jolla, September 2018<br></span>

            <span class="bib"><span class="bib-name">Hell, M. C.</span>, Cornuelle, B., Gille, S. T., Miller, A., Bromirski, P., Crawford A. D., Ross Ice Shelf Seismic Data, Southern Ocean Storms and Antarctic Sea Ice Thickness, Multi-Modal Oscillations in Ocean Basins, Symposium, La Jolla, September 2018<br></span>

            <span class="bib"><span class="bib-name">Hell, M. C.</span>, T. Schneider and N. Keenlyside Stratospherically-mediated Long-term Response to Polar Surface Heating, 20th Atmosphere and Ocean Fluid Dynamics Meeting, June 2015<br></span>
            <span class="bib"><span class="bib-name">Hell, M. C.</span>, Martin King and Noel Keenlyside, Investigation of the atmospheric mechanisms related to the autumn sea ice and winter circulation link in the Northern Hemisphere, EGU Meeting, Mai 2015<br></span>


        <!-- <h4>Posters</h4>
            <span class="bib"><span class="bib-name">Hell, M. C.</span>, Ayet, A., Chapron, B., Gille, S. T., Baratgin L., Open Ocean Swell Dispersion from Moving Wind Fetches, US Clivar Meeting on Surface Currents in the Coupled
                Ocean-Atmosphere System Workshop, Feb 2020, La Jolla, CA, Poster<br></span>
            <span class="bib"><span class="bib-name">Hell, M. C.</span>, Ayet, A., Chapron, B., Gille, S. T., Baratgin L., Open Ocean Swell Dispersion from Moving Wind Fetches, Feb 2020, Ocean Sciences Meeting 2020, San Diego, CA,
                Poster<br></span>

            <span class="bib"><span class="bib-name">Hell, M. C.</span>, Cornuelle, B., Gille, S. T., Miller, A., Bromirski, P.,
                Crawford A. D., Southern Ocean Storm positions and intensity estimated with seismic observations in the Ross Ice
                Shelf, WAIS Meeting 2019, Julian, CA, Poster<br></span>

            <span class="bib"><span class="bib-name">Hell, M. C.</span>, Cornuelle, B., Gille, S. T., Miller, A., Bromirski, P.,
                Crawford A. D., Southern Ocean Storm positions and intensity estimated with seismic observations in the Ross Ice
                Shelf, GCC 2018, Pack Forest, WA, Poster<br></span>

            <span class="bib"><span class="bib-name">Hell, M. C.</span>, Cornuelle, B., Gille, S. T., Miller, A., Bromirski, P.,
                Crawford A. D., Southern Ocean Storm positions and intensity estimated with seismic observations in the Ross Ice
                Shelf, AGU Fall Meeting 2018, Washington DC, Poster<br></span>

            <span class="bib"><span class="bib-name">Hell, M.</span>, Schneider, T., Li, C., Circulation Response to Short-Term Arctic Warming in an IGCM, International Conferences on Subseasonal to Decadal Predictions, Boulder, September 2018, Poster<br></span>

            <span class="bib"><span class="bib-name">Hell, M. C.</span>, Cornuelle, B., Gille, S. T., Miller, A., Bromirski, P., Crawford A. D., Southern Ocean Storm positions and intensity estimated with seismic observations in the Ross Ice Shelf, Frontiers in Oceanic, Atmospheric, and Cryospheric Boundary Layers, Santa Barbara, May 2018, Poster<br></span>

            <span class="bib"><span class="bib-name">Hell, M.</span>, Schneider, T., Li, C. <a href="https://usclivar.org/sites/default/files/meetings/2017/arctic-posters/Hell-Momme-arctic.pdf" target=blank> Circulation Response to Short-Term Arctic Warming</a>, Arctic Change & Its Influence on Mid-Latitude Climate & Weather Workshop, US clivar meeting, Washington DC, February 2016, Poster<br></span> -->

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