The Dark Target Algorithm for Observing the Global Aerosol System: Past, Present, and Future

Lorraine A Remer,Virginia Sawyer,Shana Mattoo,Yingxi Shi,Rong-Rong Li,Yaping Zhou,Falguni Patadia,Pawan Gupta,Mijin Kim,Santiago Gassó,Didier Tanré,Brent N Holben,Charles Ichoku,Richard G Kleidman,Robert C Levy,Leigh A Munchak

doi:10.3390/rs12182900

Abstract

The Dark Target aerosol algorithm was developed to exploit the information content available from the observations of Moderate-Resolution Imaging Spectroradiometers (MODIS), to better characterize the global aerosol system. The algorithm is based on measurements of the light scattered by aerosols toward a space-borne sensor against the backdrop of relatively dark Earth scenes, thus giving rise to the name “Dark Target”. Development required nearly a decade of research that included application of MODIS airborne simulators to provide test beds for proto-algorithms and analysis of existing data to form realistic assumptions to constrain surface reflectance and aerosol optical properties. This research in itself played a significant role in expanding our understanding of aerosol properties, even before Terra MODIS launch. Contributing to that understanding were the observations and retrievals of the growing Aerosol Robotic Network (AERONET) of sun-sky radiometers, which has walked hand-in-hand with MODIS and the development of other aerosol algorithms, providing validation of the satellite-retrieved products after launch. The MODIS Dark Target products prompted advances in Earth science and applications across subdisciplines such as climate, transport of aerosols, air quality, and data assimilation systems. Then, as the Terra and Aqua MODIS sensors aged, the challenge was to monitor the effects of calibration drifts on the aerosol products and to differentiate physical trends in the aerosol system from artefacts introduced by instrument characterization. Our intention is to continue to adapt and apply the well-vetted Dark Target algorithms to new instruments, including both polar-orbiting and geosynchronous sensors. The goal is to produce an uninterrupted time series of an aerosol climate data record that begins at the dawn of the 21st century and continues indefinitely into the future.

Highlights

The global aerosol system [1,2,3] is an integral component of Earth system science [4]
After comparing average aerosol optical depth (AOD) values at different Moderate-Resolution Imaging Spectroradiometers (MODIS) array sizes with coincident Aerosol Robotic Network (AERONET) average AOD for a 1 h time period at representative locations around the globe, we found the most robust solution to be using an array of 5 × 5 MODIS retrieval boxes with ±30 min of AERONET observations
These results show that the Dark Target (DT) AOD product continues to match AERONET values well, with not much overall change in the validation statistics from 2002, despite increasing the number of collocations by three orders of magnitude

Summary

Introduction

The global aerosol system [1,2,3] is an integral component of Earth system science [4]. The examination of aerosols as a global system, rather than a local one, is only 30 years old 273 An important factor in creating this shift in perspective from local to global was tied directly to the advent of satellite remote sensing of aerosol. The algorithm was designed with climate applications in mind, but the air-quality community began to use the products for forecasting and mitigation work. To serve that community better, we implemented operational production of a 3 km product to supplement the standard 10 km product [17,76]. Creating a Merged Product from Dark Target and Deep Blue

Objectives

Findings

Discussion

Conclusion