Data set

This study is based on a collection of more than 9800 instantaneous temperature and salinity profiles, with data available at the standard levels (5, 10, 25, 50, 75, 100, 150, 200, 250, 300, 400, 500, 750, 1000 and so on every 500 m), collected between 1950 and 1993. The data were obtained from the Russian Arctic and Antarctic Research Institute (AARI) database, which was also used in the creation of the Joint US–Russian Atlas of the Arctic Ocean for winter (Timokhov and Tanis, Reference Timokhov and Tanis1997). The AARI database was first introduced by Lebedev and others (Reference Lebedev, Karpy, Pokrovsky, Sokolov and Timokhov2008). This is complemented by the data made available over the period 2007–2012 from the expeditions of the International Polar Year (IPY) and afterward, which consist of Conductivity Temperature Depth (CTD) and eXpendable Conductivity Temperature Depth (XCTD) data, as well as data from the Ice-Tethered Profiler (ITP)-buoys (more than 14 600 stations in total). The average vertical resolution of all these profiles was 1 m. In areas where observations were missing, temperature and salinity data were reconstructed in a regular grid for the period 1950–1989 as detailed in the next subsection. The time period of 1994–2006 was not included in the analysis as there are too few data to construct reliable gridding fields. Thus, the working database is represented by grids with 200 km horizontal spacing, covering the deep part of the Arctic Ocean (with depths of more than 50 m). According to Treshnikov (Reference Treshnikov1959), Rudels and others (Reference Rudels, Anderson and Jones1996, Reference Rudels, Jones, Schauer and Eriksson2004) and Korhonen and others (Reference Korhonen, Rudels, Marnela, Wisotzki and Zhao2013), the average thickness of the Arctic Ocean mixed layer for the winter season is ~50 m. A description of the data sources for other physical parameters, used as predictors for the statistical model, can be found in Table 1.

Table 1. Predictors used for the approximation of PCs

The database used in this study belongs to the Oceanography Department of the Arctic and Antarctic Research Institute and it is not freely available. To mitigate the related issues, we provide additional data description. Table A1 in the Appendix contains a list of the expeditions and number of stations that were used for reconstruction and gridding of salinity fields. Figure A1 shows the overall observation density and the year associated with each observation. The data exhibit a spatiotemporal non-uniformity that is undesirable but expected given the logistical challenges associated with recovering long-term observations of Arctic salinity. While this dataset has gaps and is proprietary, we believe it provides one of the most spatiotemporally detailed observational resources for studying multidecadal variations in basin-wide Arctic salinity. This manuscript is motivated by the potential to advance understanding through identification, dissemination and modeling of the principal modes of variability in these long-term salinity observations.

Gridded fields of surface winter salinity were compared with fields from the Pan-Arctic Ice-Ocean Modeling and Assimilation System (PIOMAS; Zhang and Rothrock, Reference Zhang and Rothrock2003; Lindsay and Zhang, Reference Lindsay and Zhang2006) for their overlapping period 1978–1993 (dashed curves, Fig. 1). PIOMAS is a coupled ice-ocean model which uses data assimilation methods for ice concentration and ice velocity. Forced by atmospheric observations, its output is available for 1978 to near present and is widely used as a reference for Arctic variables with limited long-term observations including salinity and sea-ice thickness. Maps of long-term means for both datasets are similar (Figs 2a and A2a), with a correlation coefficient of 0.88. Nevertheless, PIOMAS data generally provide higher salinity values for the Amerasian Basin (Canada Basin together with Makarov Basin) for the overlapping period (Fig. 1). The associated variance maps are also significantly correlated with each other (correlation coefficient R = 0.36; statistical significance level p = 0.05) but exhibit some salient differences (Fig. A3). In particular, a high variance zone along the Lomonosov Ridge is prominent in the AARI dataset, but is absent in PIOMAS data. PIOMAS instead features several centers of high variance along the shelf.

Fig. 2. The average salinity field (a) and first three modes of the average salinity field decomposition for the layer 5–50 m: (b), (c), (d) – first, second and third modes, respectively, for the periods 1950–1993 and 2007–2012.

To test for artifacts from the data gaps and the interpolation procedure (reviewed in the next subsection), we make several comparisons across methods and to independent datasets in the subsections to follow. For example, we also performed the EOF analysis with and without the additional 2007–2012 period, and report only modest change to the resulting modes of variability (section ‘Decomposition of surface-layer salinity fields by EOF’). In section ‘Decomposition of surface-layer salinity fields by EOF’, we also compare EOFs from the AARI data to those from PIOMAS.

Field reconstruction and interpolation

To provide temporal and spatial continuity, we have unified existing datasets using reconstruction and gridding. The technique of computing gridded fields for the period from 1950 to 1993 was described by Lebedev and others (Reference Lebedev, Karpy, Pokrovsky, Sokolov and Timokhov2008), and is summarized here.

These techniques are based on the method of ocean field reconstruction, proposed by Pokrovsky and Timokhov (Reference Pokrovsky and Timokhov2002). This method, which was used to obtain gridded salinity fields, is given by

(1)$$\eqalign{z_i = & z_i^{\left( r \right)} + e_i,\; \; {\langle} z_iz_j{\rangle} = \sigma _{x_ix_j},\; \; {\langle}z_ie_i{\rangle} = 0, \cr {\langle}e_i{\rangle} = & 0,\; \; {\langle}e_ie_j{\rangle} = \delta _{ij}\sigma _{\rm e}^2 = \sigma _{{\rm e}_{ij}}^2.} $$

Here z(t, x) is the measured value of an oceanographic variable (e.g., temperature or salinity), and is a random function of time t and spatial coordinates x; i and j are the nodes of the irregular data grid; the notation <…> denotes the ensemble average of a value. We can write the observed value of z(t, x) as the sum of a true value z ^(r)(t, x) of the oceanographic variable and an observational error e(t, x). In addition, we introduce $\sigma _{x_ix_j}$ as a std dev. of spatial coordinates and $\sigma _{{\rm e}_{ij}}^2 $ as a std dev. of errors. We also propose that z _i^(r) has spatial correlations to the oceanographic parameters; that a systematic error is not identified; a std dev. of error (σ _e²) does exist; and $\delta _{ij} = \left\{ {\matrix{ {0,\; \; {\rm if}\; i \ne j} \cr {1,\; \; {\rm if}\; i = j} \cr}} \right.$ is the Kronecker δ.

Biorthogonal decomposition of the oceanographic variable can help to identify the connections between spatial and temporal distributions within the data:

(2)$$z\left( {t_j,\; x_i} \right) = \mathop \sum \limits_k c_k^j f_k\left( {x_i} \right) + e(t_j,x_i),$$

where f _k(x _i) is the spatial EOF, and c _k^j is the calculated coefficient or so-called k ^th PC.

As the next step, we approximate the EOF through linear combinations (with coefficients b _kl) of convenient analytical functions P _l(x _i) (e.g., polynomials, splines, etc.):

(3)$$f_k\left( {x_i} \right) = \mathop \sum \limits_l b_{kl}P_l\left( {x_i} \right).$$

Thus, the modified biorthogonal decomposition can be written as

(4)$$z\left( {t_j,\; x_i} \right) = \mathop \sum \limits_k d_l^j P_l\left( {x_i} \right) + e(t_j,\; x_i),$$

where $d_{l}^{j} = \mathop \sum {b}_{kl}\;c_k^j $.

The main goal of this spectral analysis method is to estimate the coefficients of spectral decomposition $\{ c_k^j \} $ and {b _kl}, in order to identify dominant modes of behavior. In this case, we rewrite formula (2) in the following matrix form:

(5)$$Z = F \, \cdot \, C + e,$$

where · denotes matrix multiplication.

The matrix F is formed by the values of the EOF, the matrix Z is composed of the totality of the measurement data at the points of the observation net x _i, and the matrix e is filled out by observational error values.

The system of linear equations (5) with respect to the unknown coefficients $c_k^j$ can be solved on the basis of the a priori statistical information (1) with the use of the standard estimation of the least squares method. A formula for the estimation of the matrix of the unknown coefficients C was obtained in (Pokrovsky and Timokhov, Reference Pokrovsky and Timokhov2002), and is written

(6)$$\hat C = (F^{\rm T} \, \cdot \, K_{\rm e}^{ - 1} \, \cdot \, F + K_{\rm c}^{ - 1} )^{ - 1}F^{\rm T} \, \cdot \, K_{\rm e}^{ - 1} \, \cdot \, Z^{\prime},$$

where X ⁻¹ and X^T denote the inverse and transpose of a matrix X, respectively. The covariance matrix of errors of the expansion coefficients K _c is a diagonal matrix composed of eigenvalues of the covariance matrix K _z. Here, the matrices K _z and K _e are covariance matrices of the std dev. of spatial coordinates and the std dev. of errors, respectively.

In order to obtain an estimate of the unknown variables at the nodes of the regular grid $\tilde x_i$, it is necessary to interpolate the EOF into the corresponding nodes of the grid and obtain a new matrix $\tilde F$ of the EOF, a new matrix $\tilde C$ of decomposition coefficients, and new matrix $\tilde e$ of observational errors. Using the matrix $\tilde F$ obtained in this way and the estimates of the coefficients $\hat C$ from formula (6), from the matrix relationship

(7)$$\tilde Z = \tilde F \, \cdot \, \tilde C + \tilde e,$$

we obtain an estimate of the unknown parameters at the nodes of a regular grid. Simultaneously with the salinity fields in the nodes of a regular grid, we can also calculate the covariance matrices of the errors of estimations obtained from the following equations:

$$K_{\hat{\rm C}} = \left( {I + \left( {K_{\rm c} \, \cdot \, \left( {{\tilde F}^{\rm T} \, \cdot \, \tilde K_{\rm e}^{ - 1} \, \cdot \, \tilde F} \right)} \right)} \right)^{ - 1} \, \cdot \, K_{\rm c},$$

(8)$$K_{\hat{\rm Z}} = \tilde F \, \cdot \, K_{\rm z} \, \cdot \, \tilde F^{\rm T},$$

where I is the identity matrix and $\tilde K_{\rm e}^{ - 1} $ is the covariance matrix of the observation error expanded over the regular grid x _i.

This approach is a combination of singular value decomposition and statistical regularization. These coefficients (modes) can be linked to the real physical processes that influence salinity as presented in section ‘Statistical approach’. Preparation of the average salinity field data for 2007–2012 consisted of several stages as detailed in the Appendix. First, we checked the data for random errors. Then, we used linear interpolation and assimilated the real plane with the field data through the virtual plane of data. Next, we constructed an interpolation via a grid of nodes (separately for each plane). The gaps in the data for uncovered sites were filled with climatic values from the Joint US–Russian Atlas of the Arctic Ocean (Timokhov and Tanis, Reference Timokhov and Tanis1997). Using an older climatology to fill in recent (2007–2012) salinity fields is appropriate here as the areas where the most significant changes are observed, i.e., Canadian and Eurasian Basins, have sufficient data coverage to lessen concerns about potential inaccuracies (Fig. A1).

Statistical approach

Here we describe the approaches to data analysis which were used for physical interpretation of our statistical model. Polyakov and others (Reference Polyakov2010), Rabe and others (Reference Rabe2011) and Morison and others (Reference Morison2012) have emphasized that the thermohaline structure of the surface layer has undergone significant change over the last decade. However, there is still room for discussion on what physical processes led to these changes or what the future trends may be.

The analysis of the variability of the surface layer (including salinity fields) of the Arctic Ocean may be based on a decomposition using EOFs. This approach is useful in our case because decomposition by EOF analysis gives modes (spatial patterns) and PC time series, which allow us to divide the variability into spatial and temporal components. Each mode describes a certain fraction of the total variance of the initial data, and the EOFs are conventionally ordered so that the first EOF explains the most variance and subsequent EOFs explain progressively less variance (Hannachi and others, Reference Hannachi, Jolliffe and Stephenson2007). The first three modes describe more than half the variance of the analyzed fields as further detailed below, which allows significant compressing of the information contained in the original data (Hannachi and others, Reference Hannachi, Jolliffe and Stephenson2007; Borzelli and Ligi, Reference Borzelli and Ligi1998). The EOF decomposition was carried out for the average salinity fields for the layer 5–50 m, yielding PCs for the periods of 1950–1993 and 2007–2012.

Multiple linear regression was used to model the PC time series to identify predictors that determined variability of the salinity fields. The regression equations can give projections of future changes because the predictors lead the salinity field by various temporal lags. The statistical model is characterized by a system of linear regression equations constructed for the first three PCs. The candidate predictors were as follows: atmospheric circulation indices (Arctic oscillation (AO) and Arctic dipole (AD) indices; see Table 1) calculated for winter (October–March to cover the period of active ice formation) and summer (July–September to cover the period of active ice melting), river runoff, the area of the ice-free surface in Arctic seas in September and water exchange with the Pacific and Atlantic Oceans. For the latter two water exchanges, we used the Pacific decadal oscillation (PDO) and Atlantic multidecadal oscillation (AMO) indices as respective proxies because of their influence on the temperature and salinity of water, which is entering through the Bering Strait and the Faeroe-Shetland Strait to the Arctic Ocean (Zhang and others, Reference Zhang, Woodgate and Moritz2010; Dima and Lohmann, Reference Dima and Lohmann2007). Atmospheric indices were averaged by different time periods within indicated winter and summer seasons. The optimal periods of averaging for a particular index were chosen on the basis of maximal correlations with PCs.