Lagged teleconnections of climate variables identified via complex rotated Maximum Covariance Analysis

TL;DR

This paper introduces a complex rotated Maximum Covariance Analysis method that captures lagged teleconnections in climate variables, improving the understanding of ocean-atmosphere interactions and their temporal shifts.

Contribution

The proposed method extends MCA by incorporating complex space transformations and Varimax rotation, enabling detection of out-of-phase signals and more physically meaningful modes.

Findings

Successfully captures seasonal, ENSO, and climate oscillation patterns.

Identifies regional time lags between ocean temperature and precipitation.

Enhances understanding of long-distance climate teleconnections.

Abstract

A proper description of ocean-atmosphere interactions is key for a correct understanding of climate evolution. The interplay among the different variables acting over the climate is complex, often leading to correlations across long spatial distances (teleconnections). In some occasions, those teleconnections occur with quite significant temporal shifts that are fundamental for the understanding of the underlying phenomena but which are poorly captured by standard methods. Applying orthogonal decomposition such as Maximum Covariance Analysis (MCA) to geophysical data sets allows to extract common dominant patterns between two different variables, but generally suffers from (i) the non-physical orthogonal constraint as well as (ii) the consideration of simple correlations, whereby temporally offset signals are not detected. Here we propose an extension, complex rotated MCA, to address both limitations. We transform our signals using the Hilbert transform and perform the orthogonal decomposition in complex space, allowing us to correctly correlate out-of-phase signals. Subsequent Varimax rotation removes the orthogonal constraints, leading to more physically meaningful modes of geophysical variability. As an example of application, we have employed this method on sea surface temperature and continental precipitation; our method successfully captures the temporal and spatial interactions between these two variables, namely for (i) the seasonal cycle, (ii) canonical ENSO, (iii) the global warming trend, (iv) the Pacific Decadal Oscillation, (v) ENSO Modoki and finally (vi) the Atlantic Meridional Mode. The complex rotated modes of MCA provide information on the regional amplitude, and under certain conditions, the regional time lag between changes on ocean temperature and land precipitation.