Abstract

Abstract. Ground-based radar observations show that, over the eastern North Atlantic, 50 % of warm marine boundary layer (WMBL) hydrometeors occur below 1.2 km and have reflectivities of < −17 dBZ, thus making their detection from space susceptible to the extent of surface clutter and radar sensitivity. Surface clutter limits the ability of the CloudSat cloud profiling radar (CPR) to observe the true cloud base in ∼52 % of the cloudy columns it detects and true virga base in ∼80 %, meaning the CloudSat CPR often provides an incomplete view of even the clouds it does detect. Using forward simulations, we determine that a 250 m resolution radar would most accurately capture the boundaries of WMBL clouds and precipitation; that being said, because of sensitivity limitations, such a radar would suffer from cloud cover biases similar to those of the CloudSat CPR. Observations and forward simulations indicate that the CloudSat CPR fails to detect 29 %–43 % of the cloudy columns detected by ground-based sensors. Out of all configurations tested, the 7 dB more sensitive EarthCARE CPR performs best (only missing 9.0 % of cloudy columns) indicating that improving radar sensitivity is more important than decreasing the vertical extent of surface clutter for measuring cloud cover. However, because 50 % of WMBL systems are thinner than 400 m, they tend to be artificially stretched by long sensitive radar pulses, hence the EarthCARE CPR overestimation of cloud top height and hydrometeor fraction. Thus, it is recommended that the next generation of space-borne radars targeting WMBL science should operate interlaced pulse modes including both a highly sensitive long-pulse mode and a less sensitive but clutter-limiting short-pulse mode.

Highlights

  • Because of their ubiquitous nature and the way they interact with solar and longwave radiation, warm marine boundary layer (WMBL) clouds play a crucial role in the global energy budget (Klein and Hartmann, 1993)

  • This study focuses on evaluating how well spaceborne cloud profiling radar (CPR) are able to document the properties of warm marine boundary layer (WMBL) clouds

  • The EarthCARE CPR’s performance is significantly better than that of the CloudSat CPR when it comes to detecting thin, tenuous and broken clouds as well as clouds and precipitation near 500 m, its configuration still does not allow for the detection of all WMBL clouds and precipitation

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Summary

Introduction

Because of their ubiquitous nature and the way they interact with solar and longwave radiation, warm marine boundary layer (WMBL) clouds play a crucial role in the global energy budget (Klein and Hartmann, 1993). Using ground-based observations and an instrument forward simulator, Burns et al (2016) determined that the CloudSat CPR’s successor, the EarthCARE CPR (Illingworth et al, 2015), will only detect 70 %–80 % of WMBL cloud segments; its coarse vertical resolution (500 m, same as the CloudSat CPR) will introduce significant biases into reported cloud boundaries These results likely need be revised since changes have since been made to the design of this joint European Space Agency (ESA) and Japan Aerospace Exploration Agency (JAXA) spaceborne mission (https://earth.esa.int/web/guest/ missions/esa-future-missions/earthcare, last access: 30 April 2020). – evaluating the performance of alternative radar configurations designed for an optimum characterization of WMBL clouds and precipitation (Sect. 5)

Datasets
CloudSat spaceborne W-band radar observations
ARM ground-based observations
Forward simulations based on ground-based KAZR observations
Evaluation metrics
Challenges
Path forward
Discussion and conclusions

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