Planetary Boundary Layer Height Estimates From ICESat-2 and CATS Backscatter Measurements

Palm, Stephen P.; Selmer, Patrick A.; Yorks, John E.; Nicholls, S.; Nowottnick, E. P.

doi:10.3389/frsen.2021.716951

Cited by 21 publications

(14 citation statements)

References 37 publications

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“…Using the Doppler effect, the radial velocity along the direction the laser beam can be retrieved and the distance between scatters (aerosols) in the beam path can be calculated [57][58] . The maximum detection range varies from 2.0 to 3.0 km depending on the micron-sized aerosol load in the atmosphere 59 . More detailed information about the measurements and calculation for PBLH can be found in our parallel work for the CALISHITO campaign.…”

Section: Planetary Boundary Layer (Pbl) Condition Determinationmentioning

confidence: 99%

Diurnal cycle of bioaerosols is a key driver of ice nucleating particle variability for Eastern Mediterranean orographic clouds

Gao,

Vogel,

Foskinis

et al. 2024

Preprint

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We report the drivers of diurnal cycles of ice nucleating particles (INPs) for mixed-phase orographic clouds in the Eastern Mediterranean. In the planetary boundary layer, pronounced INP diurnal periodicity is observed, which is mainly driven by coarse-sized particles. Based on particle fluorescence, we estimate at least 20% of the INPs in the PBL are of biological origin and a major driver of the diurnal cycle. The presence of Saharan dust increases INPs during nighttime but not for daytime compared to non-dust days, thus reducing the INP range throughout the day. Bioaerosols also are important contributors to INP in the free troposphere without any evident diurnal cycle. Given the ubiquity of forests in mountainous regions, the unique ability of bioaerosol to form ice at warm temperatures (effects of which is further amplified by secondary ice processes) and the lack of such cycles in models points to an overlooked glaciation cycle and an important source of bias in precipitation and extreme events in continental and mountainous regions.

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Section: Planetary Boundary Layer (Pbl) Condition Determinationmentioning

confidence: 99%

Diurnal cycle of bioaerosols is a key driver of ice nucleating particle variability for Eastern Mediterranean orographic clouds

Gao,

Vogel,

Foskinis

et al. 2024

Preprint

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“…That paper demonstrated a substantial improvement in both number of layers detected and in horizontal resolution of the data product when the AI/ML analysis was used, although it was demonstrated using existing data sets. Work by Palm et al (2021) applied AI/ML algorithms to existing spaceborne data, detecting layer height and boundaries at greatly improved resolution. In this work we apply AI/ML-based algorithms for real-time detection of atmospheric features and determination of feature height during instrument operation.…”

Section: Real-time Feature Detectionmentioning

confidence: 99%

Machine learning-enabled real-time detection of cloud and aerosol layers using airborne lidar

McGill

Selmer²,

Kupchock³

et al. 2023

Front. Remote Sens.

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Lidar profiling of the atmosphere provides information on existence of cloud and aerosol layers and the height and structure of those layers. Knowledge of feature boundaries is a key input to assimilation models. Moreover, identifying feature boundaries with minimal latency is essential to impact operational assimilation and real-time decision making. Using advanced convolution neural network algorithms, we demonstrate real-time determination of atmospheric feature boundaries using an airborne backscatter lidar. Results are shown to agree well with traditional processing methods and are produced with higher horizontal resolution than the traditional method. Demonstrated using airborne lidar, the algorithms and process are extendable to real-time generation of data products from a future spaceborne sensor.

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“…Furthermore, many of these platforms rely on the assumption of a strong gradient in a signal only at the top of the PBL and are likely unable to resolve mixed layering at multiple heights, especially layering that is above or within the PBL. Note that several groups are employing machine learning to identify where the PBL top is most likely located and to resolve the PBLH in areas of atmospheric stratification (Palm et al., 2021; Sleeman et al., 2020). Other investigations are using current and future low Earth orbit and geostationary passive sensors geared toward understanding the underlying atmospheric chemistry and dynamics of that impact PBLH retrievals in coastal regions (Loría‐Salazar et al., 2021; Turner & Ulrich, 2021; Wang et al., 2021).…”

Section: Representativeness Of Satellite Measurements In Coastal Regionsmentioning

confidence: 99%

Surf, Turf, and Above the Earth: Unmet Needs for Coastal Air Quality Science in the Planetary Boundary Layer (PBL)

et al. 2023

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Most of the world's megacities are in the coastal zone (Brown et al., 2013), and nearly 50% of the US population lives in coastal counties (Crossett et al., 2004), facing urban environmental challenges that occur within the complex coastal atmospheric planetary boundary layer (PBL). While the definitions of the PBL and the PBL height/depth (PBLH) vary depending on scientific application (e.g., gradients in temperature/atmospheric stability, composition, or turbulence), we generally refer to the PBL as the lowest layer of the atmosphere that is directly affected by heat and moisture fluxes and friction from the Earth's surface (Medeiros et al., 2005). The interaction of both land and ocean surfaces with the PBL is a very active area of research, with distinct communities (land-atmosphere and ocean-atmosphere) and driving science questions (e.g., Santanello et al., 2018 and refs therein;Teixeira et al., 2021). Routine measurements of the PBLH are provided via high temporal and vertical resolution ground-based measurements, such as radiosonde soundings, commercial aircraft measurements (e.g., Aircraft Meteorological Data Relay (AMDAR), Y. , and lidar backscatter/ceilometer. For near global coverage, satellite estimates of PBLH can be derived from spaceborne lidar instruments, such as the

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Planetary Boundary Layer Height Estimates From ICESat-2 and CATS Backscatter Measurements

Cited by 21 publications

References 37 publications

Diurnal cycle of bioaerosols is a key driver of ice nucleating particle variability for Eastern Mediterranean orographic clouds

Diurnal cycle of bioaerosols is a key driver of ice nucleating particle variability for Eastern Mediterranean orographic clouds

Machine learning-enabled real-time detection of cloud and aerosol layers using airborne lidar

Surf, Turf, and Above the Earth: Unmet Needs for Coastal Air Quality Science in the Planetary Boundary Layer (PBL)

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