Ali Chase Senior Oceanographer achase@apl.uw.edu Phone 206-543-7836 |
Research Interests
Underway Optical Measurements
Phytoplankton Community Composition
Ocean Color Remote Sensing
Imaging-in-flow Cytometry
Machine Learning
Hyperspectral Radiometry
Cloud Computing
Biosketch
Ali is a bio-optical oceanographer conducting research on the use of optics and remote sensing to study phytoplankton dynamics, with a focus on developing methods and tools that enable the use of large and complex datasets. Ali leads the Marine Phytoplankton & Optics Group (planktonoptics.com) and works on projects spanning regional-to-global scales.
Department Affiliation
Air-Sea Interaction & Remote Sensing |
Education
B.A. Geology and Environmental Studies, Bowdoin College, 2009
M.S. Oceanography, University of Maine, 2014
Ph.D. Oceanography, University of Maine, 2020
Videos
First Look at PACE Ocean Color Observations The launch of NASA's PACE satellite in early 2024 begins a new era in observing the Earth's oceans and atmosphere. Evaluating the first data sets beamed to Earth from the satellite's Ocean Color Instrument, Oceanographer Ali Chase notes that we're able to observe, clearer than ever before, spatial patterns in the distribution of phytoplankton populations. |
26 Apr 2024
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PACE: Identifying Phytoplankton Communities from Space APL-UW oceanographers Ali Chase and Peter Gaube traveled to Cape Canaveral to watch the launch of PACE the Plankton Aerosol Cloud and Ocean Ecosystem mission. This NASA satellite is observing the Earth's oceans and atmosphere every day globally. |
11 Apr 2024
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Publications |
2000-present and while at APL-UW |
A model for community-driven development of best practices: the Ocean Observatories Initiative Biogeochemical Sensor Data Best Practices and User Guide Palevsky, H.I., and 38 others including A.P. Chase, "A model for community-driven development of best practices: the Ocean Observatories Initiative Biogeochemical Sensor Data Best Practices and User Guide," Front. Mar. Sci., 11, doi:10.3389/fmars.2024.1358591, 2024. |
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3 Apr 2024 |
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The field of oceanography is transitioning from data-poor to data-rich, thanks in part to increased deployment of in-situ platforms and sensors, such as those that instrument the US-funded Ocean Observatories Initiative (OOI). However, generating science-ready data products from these sensors, particularly those making biogeochemical measurements, often requires extensive end-user calibration and validation procedures, which can present a significant barrier. Openly available community-developed and -vetted Best Practices contribute to overcoming such barriers, but collaboratively developing user-friendly Best Practices can be challenging. Here we describe the process undertaken by the NSF-funded OOI Biogeochemical Sensor Data Working Group to develop Best Practices for creating science-ready biogeochemical data products from OOI data, culminating in the publication of the GOOS-endorsed OOI Biogeochemical Sensor Data Best Practices and User Guide. For Best Practices related to ocean observatories, engaging observatory staff is crucial, but having a "user-defined" process ensures the final product addresses user needs. Our process prioritized bringing together a diverse team and creating an inclusive environment where all participants could effectively contribute. Incorporating the perspectives of a wide range of experts and prospective end users through an iterative review process that included "Beta Testers"’ enabled us to produce a final product that combines technical information with a user-friendly structure that illustrates data analysis pipelines via flowcharts and worked examples accompanied by pseudo-code. Our process and its impact on improving the accessibility and utility of the end product provides a roadmap for other groups undertaking similar community-driven activities to develop and disseminate new Ocean Best Practices. |
Toward a synthesis of phytoplankton communities composition methods for global-scale application Kramer, S.J., and 14 others including A.P. Chase, "Toward a synthesis of phytoplankton communities composition methods for global-scale application," Linmol. Oceanogr. Methods, 22, 217-240, doi:10.1002/lom3.10602, 2024. |
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1 Apr 2024 |
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The composition of the marine phytoplankton community has been shown to impact many biogeochemical processes and marine ecosystem services. A variety of methods exist to characterize phytoplankton community composition (PCC), with varying degrees of taxonomic resolution. Accordingly, the resulting PCC determinations are dependent on the method used. Here, we use surface ocean samples collected in the North Atlantic and North Pacific Oceans to compare high-performance liquid chromatography pigment-based PCC to four other methods: quantitative cell imaging, flow cytometry, and 16S and 18S rRNA amplicon sequencing. These methods allow characterization of both prokaryotic and eukaryotic PCC across a wide range of size classes. PCC estimates of many taxa resolved at the class level (e.g., diatoms) show strong positive correlations across methods, while other groups (e.g., dinoflagellates) are not well captured by one or more methods. Since variations in phytoplankton pigment concentrations are related to changes in optical properties, this combined dataset expands the potential scope of ocean color remote sensing by associating PCC at the genus- and species-level with group- or class-level PCC from pigments. Quantifying the strengths and limitations of pigment-based PCC methods compared to PCC assessments from amplicon sequencing, imaging, and cytometry methods is the first step toward the robust validation of remote sensing approaches to quantify PCC from space. |
Phytoplankton composition from sPACE: Requirements, opportunities, and challenges Cetinic, I., and 28 others including A.P. Chase and P. Gaube, "Phytoplankton composition from sPACE: Requirements, opportunities, and challenges," Remote Sens. Environ., 302, doi:10.1016/j.rse.2023.113964, 2024. |
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1 Mar 2024 |
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Ocean color satellites have provided a synoptic view of global phytoplankton for over 25 years through near surface measurements of the concentration of chlorophyll a. While remote sensing of ocean color has revolutionized our understanding of phytoplankton and their role in the oceanic and freshwater ecosystems, it is important to consider both total phytoplankton biomass and changes in phytoplankton community composition in order to fully understand the dynamics of the aquatic ecosystems. With the upcoming launch of NASA's Plankton, Aerosol, Clouds, ocean Ecosystem (PACE) mission, we will be entering into a new era of global hyperspectral data, and with it, increased capabilities to monitor phytoplankton diversity from space. In this paper, we analyze the needs of the user community, review existing approaches for detecting phytoplankton community composition in situ and from space, and highlight the benefits that the PACE mission will bring. Using this three-pronged approach, we highlight the challenges and gaps to be addressed by the community going forward, while offering a vision of what global phytoplankton community composition will look like through the "eyes" of PACE. |
In The News
New satellite will help NASA keep PACE with Earth systems EOS, Emily Shepherd Color and light measurements will help scientists better assess how our oceans and atmosphere interact. |
5 Feb 2024
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