Your search keyword '"Merchant, C. A."' showing total 2 results

1. A Call for New Approaches to Quantifying Biases in Observations of Sea Surface Temperature

Author

Alexey Kaplan, John Kennedy, Boyin Huang, David E. Parker, Shoji Hirahara, Thomas M. Smith, Masayoshi Ishii, Huai-Min Zhang, Christopher P. Atkinson, Victor Venema, Finban Lindgren, Nick Rayner, Christopher J. Merchant, David I. Berry, Elizabeth C. Kent, Simone Morak-Bozzo, Souichiro Yasui, Giulia Carella, Philip Jones, and Yoshikazu Fukuda

Subjects

Atmospheric Science, Physical model, 010504 meteorology & atmospheric sciences, Climate change, 010502 geochemistry & geophysics, 01 natural sciences, Sea surface temperature, 13. Climate action, Climatology, Air temperature, Environmental science, 14. Life underwater, Regional differences, Reference dataset, 0105 earth and related environmental sciences

Abstract

Global surface-temperature is a fundamental measure of climate change. We discuss bias estimation for sea-surface temperature and recommend the improvements to data, observational metadata, and uncertainty modeling needed to make progress.Global surface-temperature changes are a fundamental expression of climate change. Recent, much-debated, variations in the observed rate of surface-temperature change have highlighted the importance of uncertainty in adjustments applied to sea-surface temperature (SST) measurements. These adjustments are applied to compensate for systematic biases and changes in observing protocol. Better quantification of the adjustments and their uncertainties would increase confidence in estimated surface-temperature change and provide higher-quality gridded SST fields for use in many applications.Bias adjustments have been based either on physical models of the observing processes or on the assumption of an unchanging relationship between SST and a reference data set such as night marine air temperature. These approaches produce similar estimates of SST bias on the largest space and timescales, but regional differences can exceed the estimated uncertainty. We describe challenges to improving our understanding of SST biases. Overcoming these will require clarification of past observational methods, improved modeling of biases associated with each observing method, and the development of statistical bias estimates that are less sensitive to the absence of metadata regarding the observing method.New approaches are required that embed bias models, specific to each type of observation, within a robust statistical framework. Mobile platforms and rapid changes in observation type require biases to be assessed for individual historic and present-day platforms (i.e., ships or buoys) or groups of platforms. Lack of observational metadata and of high-quality observations for validation and bias model development are likely to remain major challenges.

Published

2017

2. The Global Ocean Data Assimilation Experiment High-resolution Sea Surface Temperature Pilot Project

Author

C. T. Mutlow, Hiroshi Kawamura, Craig Donlon, Ian S. Robinson, Gary A. Wick, Peter J. Minnett, P. LeBorgne, Christopher J. Merchant, David Poulter, Jean-Francois Piolle, Jorge Vazquez-Cuervo, Andrew R. Harris, B. Emery, Edward M. Armstrong, Kenneth S. Casey, Chelle L. Gentemann, S. Heinz, Richard W. Reynolds, Robert Evans, Helen Beggs, David Llewellyn-Jones, A. W. Bingham, I. J. Barton, Olivier Arino, D. May, and Nick Rayner

Subjects

Atmospheric Science, Sea surface temperature, Data assimilation, Data products, Meteorology, Temporal resolution, Infrared radiometer, Environmental science, High resolution, Satellite, Microwave, Remote sensing

Abstract

A new generation of integrated sea surface temperature (SST) data products are being provided by the Global Ocean Data Assimilation Experiment (GODAE) High-Resolution SST Pilot Project (GHRSST-PP). These combine in near-real time various SST data products from several different satellite sensors and in situ observations and maintain the fine spatial and temporal resolution needed by SST inputs to operational models. The practical realization of such an approach is complicated by the characteristic differences that exist between measurements of SST obtained from subsurface in-water sensors, and satellite microwave and satellite infrared radiometer systems. Furthermore, diurnal variability of SST within a 24-h period, manifested as both warm-layer and cool-skin deviations, introduces additional uncertainty for direct intercomparison between data sources and the implementation of data-merging strategies. The GHRSST-PP has developed and now operates an internationally distributed system that provides operational feeds of regional and global coverage high-resolution SST data products (better than 10 km and ~6 h). A suite of online satellite SST diagnostic systems are also available within the project. All GHRSST-PP products have a standard format, include uncertainty estimates for each measurement, and are served to the international user community free of charge through a variety of data transport mechanisms and access points. They are being used for a number of operational applications. The approach will also be extended back to 1981 by a dedicated reanalysis project. This paper provides a summary overview of the GHRSST-PP structure, activities, and data products. For a complete discussion, and access to data products and services see the information online at www.ghrsst-pp.org.

Published

2007