2.1. Observational tide gauge record

We focus on local observations of daily sea level from tide gauge data provided by the University of Hawaii Sea Level Center (Caldwell et al., Reference Caldwell, Merrifield and Thompson2018) (https://uhslc.soest.hawaii.edu/). We first consider the period 1970–2017 and keep only tide gauges with less than 20 $ \% $ missing values. Data gaps are not filled. This step reduces the number of time series considered from 116 to 94. The time range 1970–2017 was chosen as a compromise between retaining high-quality, daily sea level observations and sampling a large portion of coastal areas (e.g., many tide gauges records in Japan do not start before 1969). We then investigate distributional shifts for tide gauges with more than 80 years of data and less than 20 $ \% $ of missing values, which amounts to 28 available tide gauges. Such long periods translate in a more robust statistical inference of changes in quantiles. For all tide gauges, the daily climatology is removed from each record by subtracting to each day its average over the whole period of interest. Details on the tide gauges preprocessing are further discussed in Appendix A. Start and end recording dates of tide gauges with records longer than 80 years are presented in Appendix B.

2.2. GFDL-CM4 climate model: Strengths and limitations

We consider outputs from the GFDL-CM4 model (Held et al., Reference Held2019). The ocean component is the MOM6 ocean model (Adcroft et al., Reference Adcroft, Anderson, Balaji, Blanton, Bishuk and Dufour2019) with horizontal grid spacing of 0.25° and 75 vertical layers. With this grid spacing, the model cannot resolve many coastal bays and harbors. Nonetheless, the horizontal grid spacing of 0.25° allows to realistically represent the sloping of continental shelves and its sharp deepening at the boundaries with the open oceans. Such important feature cannot be represented in traditional 1° coupled models. Accurate representation of coastal geometry is key to trustworthy simulations of storm surges and coastal sea level as discussed in Yin et al. (Reference Yin, Griffies, Winton, Zhao and Zanna2020).

The atmospheric/land component is the AM4 model (Zhao, Reference Zhao2018a,Reference Zhaob) with a horizontal grid spacing of roughly 1° and 33 vertical layers. Despite its relatively coarse grid spacing, the model simulates the physical characteristics of tropical cyclones reasonably well, allowing one to study their frequency and changes under different forcings (Zhao, Reference Zhao2018a). However, strong hurricanes (i.e., category 4 and 5) are not simulated, hence their impact on sea level extremes cannot be assessed in our study (Zhao, Reference Zhao2018a; Yin et al., Reference Yin, Griffies, Winton, Zhao and Zanna2020).

A drawback in CM4 is the missing contribution to sea level rise caused by melting of land ice due to the lack of an ice sheet model, similarly to most coupled models in the Coupled Model Intercomparison Project-phase 6 (CMIP6) (Eyring et al., Reference Eyring, Bony, Meehl, Senior, Stevens, Stouffer and Taylor2016). Tides are not simulated and the associated tide surges (Rego and Li, Reference Rego and Li2018), driven by constructive interactions of tides and storm surges, are absent from CM4. Climate-unrelated factors such as GIA and terrestrial water storage, both relevant to sea level (mean) trends (Wang et al., Reference Wang, Church, Zhang, Gregory, Zanna and Chen2021), are also not simulated by this model. As shown by Winton et al. (Reference Winton, Adcroft, Dunne, Held, Shevliakova and Zhao2020), CM4 is a high climate sensitivity model, and so it is likely too sensitive to anthropogenic forcing. A thorough investigation of CM4-model biases in terms of sea level variability was presented in Yin et al. (Reference Yin, Griffies, Winton, Zhao and Zanna2020). Despite some of its limitations, the authors showed that the GFDL-CM4 model can serve as a useful framework to explore changes in sea level statistics under different forcing scenarios. It thus directly serves our interests in the present study.

The focus here is on two simulations. First, we consider one historical experiment in CM4, from 1970 to 2014 with external forcings consistent with observations. Second, we focus on an idealized experiment with a 1% $ {\mathrm{CO}}_2 $ increase per year (hereafter “1pctCO2”). This experiment simulates the climate system under a 1% increase of $ {\mathrm{CO}}_2 $ per year for 150 years, from preindustrial global $ {\mathrm{CO}}_2 $ concentrations up to quadrupling at year 140. We assume that the anthropogenic signal of sea level rise emerges during the first 50 years of the simulation (as shown by Yin et al., Reference Yin, Griffies, Winton, Zhao and Zanna2020 for the US east coast) and focus only on the last 100 years. The 1pctCO2 experiment is especially useful since under an incremental, yearly increase in $ {\mathrm{CO}}_2 $ concentration, sea level statistics are expected to change almost linearly (at least in the last 100 years). This linear change allows us to leverage the framework proposed in Section 3 and to explore the emergence of changes in distributional shapes in coastal sea levels.

The model output is remapped to a uniform 0.5° grid and only grid cells in the latitudinal range $ \left[-60{}^{\circ},60{}^{\circ}\right] $ are considered. In both simulations, outputs are daily averages. We focus only on coastal locations, accounting for 6,318 time series in each case.

2.3. Sea level decomposition

Following Gill and Niiler (Reference Gill and Niiler1973), Yin et al. (Reference Yin, Griffies and Stouffer2010), and Griffies and Greatbatch (Reference Griffies and Greatbatch2012), we decompose the sea level time tendency in a hydrostatic and Boussinesq ocean according to the following sea level budget

(1) $$ \Delta \eta =\frac{\Delta {P}_b}{\rho_0\hskip0.1em g}-\frac{\Delta {P}_a}{\rho_0\hskip0.1em g}-\frac{1}{\rho_0}{\int}_{-H}^{\eta}\Delta \rho \hskip0.1em \mathrm{d}z, $$

where $ \Delta $ refers to a temporal increment relative to an initial time. Variables $ \eta, {P}_b,{P}_a $ _, and $ \rho $ _, respectively, represent the sea level, bottom, and surface pressure and density at time $ t $ and longitude, latitude, vertical position $ \left(x,y,z\right) $ . We make the Boussinesq approximation, which accounts for the constant reference density $ {\rho}_0 $ (e.g., Section 2.4 of Vallis, Reference Vallis2017).

In Eq. (1), $ {P}_b $ is the ocean bottom pressure, so that $ \Delta {P}_b/\left({\rho}_0\hskip0.1em g\right) $ measures the change in sea level associated with changes in water column mass. Changes in water column mass arise from the convergence of mass via ocean currents as well as water crossing the ocean free surface via precipitation, evaporation, river runoff, and sea ice formation/melt. The SLP, $ {P}_a $ , is caused by atmospheric and sea ice loading. The contribution from $ {P}_a $ is referred to as the inverse barometer (e.g., Ponte, Reference Ponte2006), whereby increases in $ {P}_a $ lead to a decrease in sea level. The final term in the budget (1) is the local steric effect, which is measured by the depth integral of changes to in situ ocean density. For example, a decrease in column integrated density, such as through ocean warming or freshening, leads to a sea level rise from local steric expansion.

Changes from bottom pressure and the local steric effect are associated with ocean dynamics and ocean density and are referred to as sterodynamic sea level changes (Gregory et al., Reference Gregory, Griffies and Hughes2019). Following the CMIP6 convention detailed in Appendix H of Griffies et al. (Reference Griffies, Danabasoglu, Durack, Adcroft, Balaji, Böning, Chassignet, Enrique Curchitser, Drange, Fox-Kemper, Gleckler, Gregory, Haak, Hallberg, Heimbach, Hewitt, Holland, Tatiana Ilyina, Komuro, Krasting, Large, Marsland, Masina, McDougall, Nurser, Orr, Pirani, Qiao, Stouffer, Taylor, Anne Marie Treguier, Uotila, Valdivieso, Wang, Winton and Yeager2016), the sea level diagnostic “zos” measures the regional sterodynamic changes by setting the global mean to zero at each diagnostic time step, with Griffies et al. (Reference Griffies, Danabasoglu, Durack, Adcroft, Balaji, Böning, Chassignet, Enrique Curchitser, Drange, Fox-Kemper, Gleckler, Gregory, Haak, Hallberg, Heimbach, Hewitt, Holland, Tatiana Ilyina, Komuro, Krasting, Large, Marsland, Masina, McDougall, Nurser, Orr, Pirani, Qiao, Stouffer, Taylor, Anne Marie Treguier, Uotila, Valdivieso, Wang, Winton and Yeager2016) referring to zos as the dynamic sea level. There have been many studies of changes to the global mean sea level (e.g., Bittermann et al., Reference Bittermann, Rahmstorf, Kopp and Kemp2017; Le Bars et al., Reference Le Bars, Drijfhout and de Vries2017; Frederikse et al., Reference Frederikse, Landerer, Caron, Adhikari, Parkes, Humphrey, Dangendorf, Hogarth, Zanna and Cheng2020; Palmer et al., Reference Palmer, Domingues, Slangen and Dias2021; among many others), with Yin et al. (Reference Yin, Griffies, Winton, Zhao and Zanna2020) discussing the global thermosteric sea level rise in the CM4 model used here. When comparing models to observations, the global thermosteric sea level must be added to the dynamic sea level at every location in the ocean. However, our interest concerns changes in higher order moments that are independent of changes in the global mean sea level. Therefore, we focus our analysis on the dynamic sea level and inverse barometer only.

We furthermore focus on the anomaly patterns of the inverse barometer (i.e, we remove the daily climatology). Note that the inverse barometer contribution is not explicitly simulated by CMIP5 models. We thus diagnose this term offline by saving the SLP from the atmospheric model. As for tide gauges, we remove the climatological daily cycle from all fields before performing our analysis.

3.1. Quantile regression

A quantile function $ {Q}_X(p),p\in \left[0,1\right] $ , of a random variable $ X $ returns a value $ x $ such that $ \left(p\times 100\right)\% $ of the values are less than $ x $ . For example, the 0.95 quantile $ {Q}_X(0.95) $ is a real number $ x $ such that 95% of the values of the random variable, $ X $ , are smaller than $ x $ . $ {Q}_X(p),p\in \left[0,1\right] $ is the inverse $ {F}_X^{-1}(p) $ of the cumulative distribution function $ {F}_X(x)=P\left(X\le x\right)=p $ , representing the probability $ p $ that $ X $ would take a value less than or equal to $ x $ . In what follows, we simplify the notation and refer to $ {Q}_X(p) $ as $ {q}_p $ and to cumulative functions as $ F(x) $ .

Quantile regression allows us to estimate temporal changes in the conditional median (i.e., $ {q}_{0.5} $ ) or any other quantile of a time-dependent distribution (Koenker and Bassett, Reference Koenker and Bassett1978; Koenker and Hallock, Reference Koenker and Hallock2001). Here, we focus on the case of linear regression. For each quantile, $ {q}_p $ , we need to fit two parameters: an intercept $ {\beta}_0\left({q}_p\right) $ and a slope $ {\beta}_1\left({q}_p\right) $ (see Figure 1). Differently from linear regression for which we minimize the mean square error, the quantile regression process places asymmetric weights on positive and negative residuals (Koenker and Hallock, Reference Koenker and Hallock2001).

Formally, given $ n $ observations at times $ {t}_i $ , written as $ \left\{\left({t}_1,{s}_1\right),\left({t}_2,{s}_2\right),\dots \right\} $ , and the assumption of linear relationship for each quantile $ {q}_p(t),p\,\in\,\left[0,1\right] $ , then the goal is to minimize the following cost function:

(2) $$ \underset{\beta_0\left({q}_p\right),{\beta}_1\left({q}_p\right)\in \mathrm{\mathbb{R}}}{\arg \min}\sum \limits_{i=1}^n{\rho}_p\left({s}_i-{\beta}_0\left({q}_p\right)-{\beta}_1\left({q}_p\right)\hskip0.1em {t}_i\right), $$

where the “check function” $ {\rho}_p(u)=p\max \left(u,0\right)+\left(1-p\right)\max \left(-u,0\right) $ , with $ p\,\in\,\left[0,1\right] $ , assigns asymmetric weights to residuals. For a given time series, we apply quantile regression for the range of quantiles $ {q}_p $ with $ p\,\in\,\left[\mathrm{0.05,0.95}\right] $ every $ dp=0.05 $ for a total of 19 slopes (as done in McKinnon et al., Reference McKinnon, Rhines, Tingley and Huybers2016). This number of slope was found to be sufficient to discover the right changes in moments, as shown later on in the next section. An example of quantile regression for $ p=\mathrm{0.95,0.5} $ and $ 0.05 $ is shown in Figure 1a.

In practice, quantile regression studies depend on the existence of very fast algorithms (Chernozhukov et al., Reference Chernozhukov, Fernàndez-Val and Melly2022). Portnoy and Koenker (Reference Portnoy and Koenker1997) proposed a precise and time-efficient minimization method based on the Frisch–Newton algorithm. However, the computation time is still rather long in the case of multiple quantile regressions and bootstrap inference. To this end, very recently Chernozhukov et al. (Reference Chernozhukov, Fernàndez-Val and Melly2022) showed that the computation of many quantile regressions can be (vastly) accelerated by exploiting nearby quantile solutions. This method was essential for the completion of our work, especially when analyzing the climate model outputs, which included 12,636 time series each with 36,500 time steps. The algorithm can be found in the quantile regression package “quantreg” implemented in R as “quantile regression fitting via interior point methods” (i.e., method pfnb) (Koenker, Reference Koenker2022). In the case of sea level, each quantile $ {q}_p $ has dimensionality of $ \left[{q}_p\right]=\left[\mathrm{length}\right] $ , so that the slopes have dimensions of $ \left[{\beta}_1\left({q}_p\right)\right]=\left[\frac{\mathrm{length}}{\mathrm{time}}\right] $ .

3.2. Linking changes in quantiles to changes in statistical moments

The quantile regression step allows us to quantify slopes in $ N $ quantiles. This quantification can come at the expense of interpretability, especially when $ N $ is large and when analyzing more than one time series. To facilitate analysis and interpretation, we quantify how changes in quantiles of a distribution are driven by changes in the mean, variance, skewness, and kurtosis, therefore defining a single framework to study changes in quantiles and moments. All throughout the paper, we refer to the mean, variance, skewness, and kurtosis as $ \left({m}_1,{m}_2,{m}_3,{m}_4\right) $ for practical convenience and report their mathematical expression in Appendix C. A possible way to link changes in quantile to changes in moments was proposed in McKinnon et al. (Reference McKinnon, Rhines, Tingley and Huybers2016). The authors empirically derived a set of polynomials by observing how quantiles of a distribution change when changing its moments one at a time. The lack of orthogonality of such functions motivated the authors to adopt Legendre polynomials, which are orthogonal by construction and share similar shapes to the derived functions. Inspired by McKinnon et al. (Reference McKinnon, Rhines, Tingley and Huybers2016), here we approach the problem from a theoretical point of view. We take advantage of the work of Cornish and Fisher (Reference Cornish and Fisher1937) and define a unified framework useful to study and explore temporal changes in both quantiles and moments of a distribution.

3.2.1. Stationary process

The starting point of our derivation is the Cornish–Fisher expansion (Cornish and Fisher, Reference Cornish and Fisher1937; Wallace, Reference Wallace1958; Fisher and Cornish, Reference Fisher and Cornish1960; Hill and Davis, Reference Hill and Davis1968). Cornish and Fisher (Reference Cornish and Fisher1937) derived an asymptotic expansion expressing any quantile of a distribution as a function of its cumulants.Footnote ¹ Studies often focus on a modified version written in terms of the first four distributional moments. Furthermore, in practical applications higher order moments show large sensitivity to sampling fluctuations, and Bekki et al. (Reference Bekki, Fowler, Mackulak and Nelson2009) showed that a fourth-order truncation often allows for very accurate estimations of quantiles.

Given a stationary distribution with mean $ {m}_1 $ , variance $ {m}_2 $ , skewness $ {m}_3 $ , and excess kurtosis $ {m}_4 $ parameters, the following asymptotic relation holds (Cornish and Fisher, Reference Cornish and Fisher1937; Bekki et al., Reference Bekki, Fowler, Mackulak and Nelson2009):

(3) $$ {q}_p\sim {m}_1+\sqrt{m_2}\hskip0.1em w;\hskip2pt w={z}_p+\left({z}_p^2-1\right)\frac{m_3}{6}+\left({z}_p^3-3{z}_p\right)\frac{m_4}{24}-\left(2{z}_p^3-5{z}_p\right)\frac{m_3^2}{36}, $$

where $ {q}_p $ is the quantile of the “true” distribution and $ {z}_p $ is the quantile of a standard normal $ \mathcal{N}\left(0,1\right) $ at $ p\in \left[0,1\right] $ .Footnote ² In other words, $ {z}_p $ is the inverse $ {F}^{-1}(p) $ of the cumulative distribution $ F(x)={\left(2\pi \right)}^{-1/2}{\int}_{-\infty}^x\exp \left(-{\upsilon}^2/2\right) d\upsilon $ of a Gaussian distribution with zero mean and unit variance. Importantly, $ {q}_p $ , $ {m}_1 $ _, and $ \sqrt{m_2} $ have the same dimension, whereas $ {z}_p $ , $ {m}_3 $ _, and $ {m}_4 $ are nondimensional. A synthetic and a first climate-related test are discussed in Appendix D.

In the case of a normal distributions, $ {m}_3={m}_4=0 $ and the expansion (3) reduces to $ {q}_p={m}_1+\sqrt{m_2}\hskip0.1em {z}_p $ . The inclusion of the third and fourth moments, $ {m}_3 $ and $ {m}_4 $ , allows us to approximate any quantile of a nonnormal distribution as a function of a normal (Gaussian) distribution. This formula is a powerful tool as it can provide asymptotic estimations of arbitrarily large quantiles, otherwise difficult from data alone. It is useful for distributions that do not show large differences from a normal distribution with the domain of validity further discussed by Maillard (Reference Maillard2012) and Amédée-Manesme et al. (Reference Amédée-Manesme, Barthélémy and Maillard2019).

3.2.2. Nonstationary process

Here, we aim to understand and quantify how temporal changes in individual quantiles are driven by changes in statistical moments. In theory, each quantile $ {q}_p $ is time dependent through all moments of the distribution. Here, we consider dependence only up to the first four moments:

(4) $$ {q}_p(t)={q}_p\left({m}_1(t),{m}_2(t),{m}_3(t),{m}_4(t)\right). $$

Here, $ {m}_1,{m}_2,{m}_3 $ _, and $ {m}_4 $ refer to the mean, variance, skewness, and excess kurtosis. We focus on linear changes in time and therefore write

(5) $$ \frac{dq_p}{dt}=\frac{\partial {q}_p}{\partial {m}_1}\frac{dm_1}{dt}+\frac{\partial {q}_p}{\partial {m}_2}\frac{dm_2}{dt}+\frac{\partial {q}_p}{\partial {m}_3}\frac{dm_3}{dt}+\frac{\partial {q}_p}{\partial {m}_4}\frac{dm_4}{dt}=\sum \limits_{i=1}^4\frac{\partial {q}_p}{\partial {m}_i}\frac{dm_i}{dt}. $$

Each term $ \frac{\partial {q}_p}{\partial {m}_i} $ in Eq. (5) can be further evaluated by differentiating Eq. (3):

(6) $$ \left\{\begin{array}{l}\frac{\partial {q}_p}{\partial {m}_1}=1\\ {}\frac{\partial {q}_p}{\partial {m}_2}=\frac{1}{2}\frac{1}{\sqrt{m_2}}\left[{z}_p+\frac{1}{6}\left({z}_p^2-1\right)\hskip0.1em {m}_3-\frac{1}{36}\left(2{z}_p^3-5{z}_p\right)\hskip0.1em {m}_3^2+\frac{1}{24}\left({z}_p^3-3{z}_p\right)\hskip0.1em {m}_4\right]\\ {}\frac{\partial {q}_p}{\partial {m}_3}=\sqrt{m_2}\hskip0.1em \left[\frac{1}{6}\left({z}_p^2-1\right)-\frac{1}{18}\left(2{z}_p^3-5{z}_p\right)\hskip0.1em {m}_3\right]\\ {}\frac{\partial {q}_p}{\partial {m}_4}=\frac{\sqrt{m_2}}{24}\left({z}_p^3-3{z}_p\right).\end{array}\right. $$

We assume relatively small deviation from Gaussian behavior and focus only on first-order changes in Eq. (6). This is a reasonable assumption as the dynamics of many climate observables often show a strong Gaussian component, especially when focusing on anomalies (after removing climatologies). In case of (relatively) large deviation from Gaussianity, the framework is still useful at first order as suggested by tests in Appendix D.1. In other words, we evaluate Eq. (6) locally at the point $ {m}_{\ast }=\left({m}_1=0,{m}_2=1,{m}_3=0,{m}_4=0\right) $ to describe changes in the neighborhood of a Gaussian distribution. Therefore, we relate the slopes $ {\beta}_1\left({q}_p\right) $ computed in the quantile regression step in Eq. (2) to changes in moments as:

(7) $$ {\beta}_1\left({q}_p\right)\sim {\left.\frac{dq_p}{dt}\right|}_{m_{\ast }}={\left.\sum \limits_{i=1}^4\frac{dm_i}{dt}\frac{\partial {q}_p}{\partial {m}_i}\right|}_{m_{\ast }}=\sum \limits_{i=1}^4\frac{dm_i}{dt}{b}_i(p). $$

Here, the set of polynomials, $ {b}_i(p) $ , are defined by evaluating the terms $ \frac{\partial {q}_p}{\partial {m}_i} $ ; $ i\,\in\,\left[1,4\right] $ in Eq. (6) in the point $ {m}_{\ast }=\left({m}_1=0,{m}_2=1,{m}_3=0,{m}_4=0\right) $ :

(8) $$ \left\{\begin{array}{ll}{\left.{b}_1(p)=\frac{\partial {q}_p}{\partial {m}_1}\right|}_{m_{\ast }}& =1\\ {}{\left.{b}_2(p)=\frac{\partial {q}_p}{\partial {m}_2}\right|}_{m_{\ast }}& =\frac{z_p}{2}\\ {}{\left.{b}_3(p)=\frac{\partial {q}_p}{\partial {m}_3}\right|}_{m_{\ast }}& =\frac{1}{6}\left({z}_p^2-1\right)\\ {}{\left.{b}_4(p)=\frac{\partial {q}_p}{\partial {m}_4}\right|}_{m_{\ast }}& =\frac{1}{24}\left({z}_p^3-3{z}_p\right).\end{array}\right. $$

Such functions are scaled Hermite polynomials of the function $ {z}_p $ and defined in the range $ p\,\in\,\left[0,1\right] $ . The polynomials in Eq. (8) satisfy

(9) $$ {\int}_0^1{b}_i(p){b}_j(p) dp=0\hskip1em \mathrm{if}i\ne j, $$

and so they are orthogonal to each other. We depict these four functions in Figure 1b.Footnote ³

Eq. (7) allows us to examine how time changes in distributional quantiles are driven by time changes in the first four moments. We note that apart from $ {b}_1(p) $ , all polynomials in Eq. (8) differ from the ones in McKinnon et al. (Reference McKinnon, Rhines, Tingley and Huybers2016). As an example, an important difference is in the $ {b}_2(p) $ function, quantifying changes in variance. In the case of a drifting Gaussian distribution, $ {b}_2(p) $ quantifies the exact link between changes in moments and quantiles. In the “bulk” of the distribution, the function $ {b}_2(p) $ derived in Eq. (8) gives negative(positive) corrections to the correspondent function in McKinnon et al. (Reference McKinnon, Rhines, Tingley and Huybers2016) for $ p $ greater (smaller) than $ p=0.5 $ . Furthermore, $ {b}_2(p) $ shows how changes in variance also drive changes in distributional tails, with quantiles diverging to $ +\infty \left(-\infty \right) $ when $ p\to (1)0 $ .

The slopes $ {\beta}_1\left({q}_p\right) $ appearing in Eq. (7) can be efficiently estimated through the quantile regression step as shown in Eq. (2). The polynomials $ {b}_i(p) $ have been derived in Eq. (8) and follow from Cornish and Fisher (Reference Cornish and Fisher1937). Therefore, changes in moments, $ \frac{dm_i}{dt} $ , can be computed as the least-squares solution of Eq. (7). An example is shown in Figure 1b for a Beta distribution with changes coming exclusively from variance and kurtosis (i.e., $ {m}_2 $ and $ {m}_4 $ ). $ \frac{dm_1}{dt} $ is equivalent to a linear regression. We refer to the coefficients $ \frac{dm_i}{dt} $ as changes (or slopes) in moments. However, such inferred changes are orthogonal to each other, and this property may not be the case for changes in the true moments. The orthogonality constraint offers a useful and interpretable way to decompose independent sources of shifts in a distribution.

In the case of sea level, the dimensionality in changes in moments $ \frac{dm_i}{dt} $ ; $ i\,\in\,\left[1,4\right] $ is as follows: $ \left[\frac{dm_1}{dt}\right]=\left[\frac{\mathrm{length}}{\mathrm{time}}\right],\left[\frac{dm_2}{dt}\right]=\left[\frac{{\mathrm{length}}^2}{\mathrm{time}}\right],\left[\frac{dm_3}{dt}\right]=\left[\frac{1}{\mathrm{time}}\right],\frac{dm_4}{dt}=\left[\frac{1}{\mathrm{time}}\right] $ .

3.3. Statistical significance

The significance test is performed via the bootstrapping methodology (Chernick et al., Reference Chernick, González-Manteiga, Crujeiras, Barrios and Lovric2011). For a given dataset (i.e., model’s output or tide gauges), we consider the $ j $ -th time series, $ {x}_j(t) $ , and estimate the statistical significance of each coefficient $ {a}_i=\frac{dm_i}{dt} $ , $ i\,\in\,\left[1,4\right] $ . We do so by permuting (with replacement) $ {x}_j(t) $ $ B $ times and recomputing the slopes in moments $ {a}_i $ at each iteration. We choose a value of $ B=1000 $ and show the sensitivity of such a choice for one time series in Figure F2 (results do not change on average for randomly chosen time series). This method allows to construct a distribution approximating the null distribution under the null hypothesis of stationarity. For this resampling approach, we use block-bootstrapping, with blocks of one season to satisfy the assumption of statistical independence required in the bootstrapping test (Chernick et al., Reference Chernick, González-Manteiga, Crujeiras, Barrios and Lovric2011). The robustness on this choice of block size is mentioned in Section 4 and detailed in Appendix B. The specific block-bootstrapping considered is the moving block-bootstrapping that allows for overlapping blocks as described in Künsch (Reference Künsch1989).

We consider the following two significance tests.

1. 1. When dealing with one or few time series, we consider a two-tailed test and deem slopes as significant at level $ \alpha $ if in the $ \left(1-\frac{\alpha }{2}\right)\% $ (or $ \frac{\alpha }{2}\% $ ) of the upper (or lower) tails of the bootstrapped distribution. We choose $ \alpha =0.05 $ (i.e., 95% significance level).

2. 2. When considering many time series, we face a multiple testing problem and more and more false positives are expected in the statistical inference (James et al., Reference James, Witten, Hastie and Tibshirani2013. To control the ratio of false positives, we adopt the false discovery rate (FDR) test proposed by Benjamini and Hochberg (Reference Benjamini and Hochberg1995). For a given time series $ {x}_j(t) $ and a corresponding slope $ {a}_i $ , $ i\,\in\,\left[1,4\right] $ , we compute a p-value p_i. We perform this computation for all $ M $ time series in the dataset under investigation. We then rank all $ M $ p-values in the ascending order and keep only the first $ m<M $ so that $ {p}_m $ is the largest p-value such that $ {p}_m<\phi \frac{m}{M} $ , where $ \phi $ is the FDR. Note that the FDR is usually denoted by the letter “ $ q $ ”. Here, we use $ \phi $ to avoid confusions with quantiles $ q $ in the quantile regression step. In plain words, a FDR of 10% would imply that no more than $ 10\% $ of the rejected null hypotheses are false positives. This method has been shown to be an efficient test to control on average the ratio of false positives arising from multiple testing (Benjamini and Hochberg, Reference Benjamini and Hochberg1995) and found applications in climate science (Ventura et al., Reference Ventura, Paciorek and Risbey2004; Wilks, Reference Wilks2006; Fountalis et al., Reference Fountalis, Dovrolis, Bracco, Dilkina and Keilholz2018; Runge et al., Reference Runge, Nowack, Kretschmer, Flaxman and Sejdinovic2019).

In our case, this step requires to approximate a p-value from a bootstrapped distribution. Given the $ j $ -th time series $ {x}_j(t) $ and a slope $ {a}_i=\frac{dm_i}{dt} $ , $ i\,\in\,\left[1,4\right] $ , we denote $ {a}_i^{\ast 1},{a}_i^{\ast 2},\dots, {a}_i^{\ast B} $ as the $ B $ bootstrapped slopes. We define the correspondent p-value of $ {a}_i $ as $ {p}_i=\frac{\sum_{b=1}^B{1}_{\mid {a}_i^{\ast b}\mid \ge \mid {a}_i\mid }}{B} $ , where $ {1}_{\mid {a}_i^{\ast b}\mid \ge \mid {a}_i\mid }=1 $ if $ \mid {a}_i^{\ast b}\mid \ge \mid {a}_i\mid $ and zero otherwise (James et al., Reference James, Witten, Hastie and Tibshirani2013).

3.4. Synthetic tests

In this section, we test the proposed framework on two time-dependent distributions with known changes in moments. We consider two time-dependent processes sampled from a Gaussian and Beta distribution and display tests in Figure 2.

• • We define a time-dependent Gaussian process $ P\left(x,t\right)=\frac{1}{\sqrt{2\pi bt}}{e}^{\frac{{\left(x- at\right)}^2}{2 bt}} $ defined over $ x\,\in\,\mathrm{\mathbb{R}} $ with mean $ {m}_1= at $ and variance $ {m}_2= bt $ . $ a,b\,\in\,\mathrm{\mathbb{R}} $ and $ t $ represents the time vector. We choose $ a=b=5 $ . In this case, we expect distributional changes to be driven exclusively by the mean and variance.

• • We consider a stationary Beta distribution $ P(x)=\frac{x^{\alpha -1}{\left(1-x\right)}^{\beta -1}}{B\left(\alpha, \beta \right)} $ defined over $ x\,\in\,\left[0,1\right] $ . Here, $ B\left(\alpha, \beta \right)=\frac{\Gamma \left(\alpha \right)\Gamma \left(\beta \right)}{\Gamma \left(\alpha +\beta \right)} $ , with $ \Gamma $ being the Gamma function (Davis, Reference Davis1959). Therefore, $ P(x) $ depends on two parameters, $ \alpha $ and $ \beta $ , controlling the “thickness” of the tails of the distribution. A larger $ \alpha $ ( $ \beta $ ) implies negative (positive) skewness; the distribution is symmetric if $ \alpha =\beta $ . The mean, variance, skewness, and kurtosis read as:

(10) $$ \left\{\begin{array}{ll}{m}_1& =\frac{\alpha }{\alpha +\beta}\\ {}{m}_2& =\frac{\alpha \beta}{{\left(\alpha +\beta \right)}^2\left(1+\alpha +\beta \right)}\\ {}{m}_3& =\frac{2\left(\beta -\alpha \right)\sqrt{1+\alpha +\beta }}{\sqrt{\alpha}\sqrt{\beta}\left(2+\alpha +\beta \right)}\\ {}{m}_4& =\frac{3\left(1+\alpha +\beta \right)\left(\alpha \beta \left(\alpha +\beta -6\right)+2{\left(\alpha +\beta \right)}^2\right)}{\alpha \beta \left(2+\alpha +\beta \right)\left(3+\alpha +\beta \right)}.\end{array}\right. $$

Figure 2.

Testing the methodology on time series $ \left\{\left({t}_1,{s}_1\right),\left({t}_2,{s}_2\right),\dots \right\} $ sampled from time-dependent Gaussian and Beta distributions $ P\left(s,t\right) $ . (a) Time series sampled from a time-dependent Gaussian distribution. (b) Linear quantile slopes for the time series shown in panel (a). The slopes $ {\beta}_1\left({q}_p\right) $ are computed for $ p\in \left[\mathrm{0.05,0.95}\right] $ every $ dp=0.05 $ and indicated as blue dots. The black dashed line indicates the projection onto polynomials as defined in Eq. (7). Green “check” marks indicate statistically significant (95% confidence level) changes in moments; red “crosses” indicate nonsignificant changes. (c) Time series sampled from a time-dependent Beta distribution. (d) Same as panel (b) but for the case of the Beta distribution. In both cases, the method identifies the statistical moments driving changes in the distributions.

We then introduce a “drift” in this distribution by prescribing $ \alpha = at $ and $ \beta = bt $ and choose $ a=1 $ and $ b=2 $ . This defines a process with constant mean but time-dependent variance, skewness, and kurtosis. For these parameters, the exact moments are then $ \left({m}_1,{m}_2,{m}_3,{m}_4\right)=\left(\frac{1}{3},\frac{2}{9+27t},\frac{\sqrt{2+6t}}{2+3t},3-\frac{3}{2+3t}\right) $ .

In both cases, we create a time-dependent process $ \left\{\left({t}_1,{s}_1\right),\left({t}_2,{s}_2\right),\dots \right\} $ in the temporal range $ t\,\in\,\left[1,3\right] $ . In this temporal range, changes can be weakly nonlinear but still far from strong nonlinearities. Specifically, at each time step $ dt={10}^{-4} $ we random sample from the two distributions $ P\left(s,t\right) $ . We then apply the proposed framework to (a) estimate quantile slopes $ {\beta}_1\left({q}_p\right) $ and (b) compute the respective changes in moments $ \frac{dm_i}{dt} $ . By random sampling at each $ dt $ , consecutive time steps are independent by definition and block sizes in the boostrapping procedure are equal to 1 time step. Results for the Gaussian and Beta distributions cases are shown in Figure 2. The method correctly identifies the statistical moments driving changes in the distributions. We note that the proposed linear framework is still valid in the presence of weak nonlinearities such as for $ {m}_2,{m}_3 $ _, and $ {m}_4 $ for the process sampled from the Beta distribution.

Tests for a process with prescribed changes in only the variance, $ {m}_2 $ , and kurtosis, $ {m}_4 $ , are shown in the schematic in Figure 1.