4.1 The stepwise shift of 4+ year ice extent in the Arctic Basin

Figures 2a and S4 show the evolution of the annual average (average over one growth–melt cycle) SIE of different ages during 1985–2022. From the perspective of linear trend during the whole period, a striking feature is the drastic and significant decreasing trend in the extent of 4+ year ice, with a rate of −0.82 × 10⁶ km² decade⁻¹ (p < 0.01; Fig. 2a). The extent of 3 year ice shows a non-significant decreasing trend, whereas the extent of 2 year ice exhibits a significant (p < 0.05) but moderate increasing trend (Fig. S4). This results in a non-significant trend in the extent of 2–3 year ice (Fig. 2a). Therefore, the evident decline in the MYI coverage reported in previous studies (e.g. Comiso, Reference Comiso2012; Reference BabbB23) might be primarily driven by the decline in the 4+ year ice. As mentioned previously, due to the below-freezing temperature, the greatly reduced MYI extent can be occupied by newly formed FYI in winter. Therefore, there is a significant increasing trend in the FYI extent, with a rate of 0.49 × 10⁶ km² decade⁻¹ (p < 0.01; Fig. 2a), which can largely offset the decrease of MYI, and thus limit the total loss of sea ice.

Figure 2. (a) Evolution of the annual average sea ice extent (SIE) of different ages during 1985–2022. The gray-dashed lines represent the equilibrium states of first year ice (FYI) and 4+ year ice during three periods (1985–89, 1990–2007 and 2008–22), respectively. The brackets indicate the slopes and their 95% significance limits. One and two asterisks represent the slopes exceeding 95 and 99% significance levels, respectively. (b) The 7 year moving t-test results of 4+ year ice extent and FYI extent. The gray-dashed line indicates the 99% significance level. (c–e) The difference in the ratio of each gridcell occupied by certain SIA between 2008–22 and 1990–2007. The purple box signifies where the 4+ year ice has been obviously replaced by the FYI.

However, it is noteworthy that the changes of FYI and 4+ year ice extent are not gradual; instead, they exhibit stepwise characteristics before and after around 1990 and 2008, respectively. After the stepwise changes, the equilibrium states of FYI and 4+ year ice extent (gray-dashed lines in Fig. 2a), which represent the mean state of the sea-ice system after adjusting to climate forcing (Armour and others, Reference Armour, Bitz, Thompson and Hunke2011), have transitioned significantly from the former to the latter. The former stepwise change has been reported in many previous studies, which emphasize the key role of a shift in the Arctic Oscillation (AO) to high-index conditions (e.g. Belchansky and others, Reference Belchansky, Douglas and Platonov2004; Reference BabbB23). The rise in the AO flushed MYI out of the Beaufort Gyre and into Transpolar Drift Stream, leading to increased MYI export. The latter stepwise change, which is the main focus of our investigation, has also been raised in recent studies (e.g. Sumata and others, Reference Sumata, De Steur, Divine, Granskog and Gerland2023) and can be clearly identified using the 7 year moving t-test (Fig. 2b; similar results are obtained using 9 year and 11 year windows). After this stepwise shift, the FYI extent increased from ~3.0 × 10⁶ to ~3.9 × 10⁶ km², with its fraction relative to the total ice changing from 42.5 to 61.4%. Meanwhile, the extent of 4+ year ice decreased from ~2.1 × 10⁶ to ~0.6 × 10⁶ km², with its fraction changing from 30.5 to 10.0%.

The shift towards younger Arctic sea ice after 2008 is also evident in the SIA spatial distribution, as shown in Figures 2c–e. For the 4+ year ice, a noticeable decrease is observed across almost the entire western Arctic (0–180° W). Its decrease in the north of Greenland and the CAA has been primarily offset by an increase in 2–3 year ice in that region, while its decrease in the Pacific Arctic (purple box in Figs 2c, e) has been primarily offset by an increase in FYI. Additionally, the 2–3 year ice exhibits a decrease in the Arctic Ocean more toward Eurasia, which has been offset by an increase in FYI there. The dipole feature of the change in 2–3 year ice eventually explains a non-significant trend of its extent (Fig. 2a). Overall, after this stepwise shift, sea ice in most regions of the Arctic has been occupied by younger ice, with the most pronounced changes in the Pacific Arctic (purple box in Figs 2c, e).

4.2 The control from the decreased survivability

Considering the increase of FYI as an offset to the decline of MYI, which is primarily attributed to the loss of 4+ year ice, our focus here will be on exploring the stepwise decrease of 4+ year ice extent. In the previous subsection, we mentioned that there was no significant trend in the extent of 3 year ice during 1985–2022, whereas the extent of 4+ year ice showed a significant decline after 2008. Therefore, we can reasonably speculate that it is the decrease of survivability that drives less sea ice entering or remaining in the 4+ year ice. As described in Section 2.2, we can calculate the survival ratio of 3+ year ice extent $\beta _{3^ + , \,\,\,n}$ and its counterpart in growth season $\beta _{3^ + , \,\,n}^{{\rm growth}}$ and melt season $\beta _{3^ + , \,\,n}^{{\rm melt}}$. We will have:

(6)$$SIE_{4^ + , \,\,( n, \,\,St^{{\rm th}}) } = \beta _{3^ + , \,\,n} \times SIE_{3^ + , \,\,( n-1, \,\,\,St^{{\rm th}}) }$$

Figures 3a and b show the evolution of three survival ratios during 1985–2022 and their 7 year moving t-test results. It is evident that the $\beta _{3^ + , \,\,n}$ exhibits stepwise decrease since 2007, which is 1 year earlier than the shift year of the annual average SIE of 4+ year ice (see Fig. 2b; i.e. 2008). Indeed, this 1 year earlier relationship is expected. According to Eqn (6), it is the survival ratio in the n year ($\beta _{3^ + , \,\,n}$) that determines the 4+ year ice extent at the onset of n + 1 year ($SIE_{4^ + , \,\,( n, \,\,St^{{\rm th}}) }$), which can highly capture the variability of the annual average 4+ year ice extent in the n + 1 year (their correlation coefficients are 0.99 and 0.93 for non-detrend and detrended time series). During 1989–2006, the mean state of $\beta _{3^ + , \,\,n}$ stood at ~71.7%. However, it significantly decreased to 47.0% after 2007 (p < 0.01, two-sample t-test). The stepwise decrease of $\beta _{3^ + , \,\,n}$ was mainly driven by the decrease of its melt season counterpart $\beta _{3^ + , \,\,n}^{{\rm melt}}$, which also exhibited a stepwise decrease since 2007. The $\beta _{3^ + , \,\,n}^{{\rm growth}}$ also exhibits a significant stepwise decrease, albeit 3 years later (around 2010), thus contributing to the decrease of $\beta _{3^ + , \,\,n}$ as well. Additionally, it is noteworthy that enhanced interannual variability has also been observed in all survivability metrics since 2007 (Fig. 3a). The decrease of $\beta _{3^ + , \,\,n}^{{\rm growth}}$ and $\beta _{3^ + , \,\,n}^{{\rm melt}}$ suggests the combined impact of dynamic and thermodynamic processes on the decrease of $\beta _{3^ + , \,\,n}$. The contribution of specific processes will be estimated in the next subsection. Subsequently, we will quantify the relationship between the stepwise decrease of $SIE_{4^ + , \,\,( n, \,\,St^{{\rm th}}) }$ and $\beta _{3^ + , \,\,n}$.

Figure 3. (a) Survival ratio of 3+ year ice in the growth season (blue line), the melt season (red line) and the whole growth–melt cycle (black line) during 1985–2022. The gray- and red-dashed lines represent the averages of the survival ratio over the periods 1989–2006 and 2007–22, while the blue-dashed line shows the averages for 1989–2009 and 2010–22. (b) The 7-year moving t-test of survival ratio in (a). The gray-dashed lines represent the 99% confidence level. (c) The extent of 4+ year ice in the start week during 1985–2022. The gray and blue lines indicate the observed and reconstructed mean of period 1989–2006 and 2007–22, respectively. (d) The net loss of 4+ year ice extent in the start week. Red shading region represents the period of 2004–10.

First, we have:

(7)$$SIE_{3^ + , \,\,( n-1, \,\,St^{{\rm th}}) } = SIE_{3, \,\,( n-1, \,\,St^{{\rm th}}) } + SIE_{4^ + , \,\,( n-1, \,\,\,St^{{\rm th}}) }.$$

Following Armour and others (Reference Armour, Bitz, Thompson and Hunke2011), we can decompose each variable into equilibrium and perturbation components: $A_n = \bar{A} + A_n^{\prime}$. The equilibrium represents the mean state before and after the shift mentioned above. The perturbation represents deviations from the equilibrium state, equivalent to interannual variations. Substituting Eqn (7) into Eqn (6) and considering only the equilibrium state, we will have:

(8)$$\overline {SIE_{4^ + , \,\,St^{{\rm th}}}} = \overline {SIE_{3, \,\,St^{{\rm th}}}} \times \displaystyle{{\overline {\beta _{3^ + }} } \over {1-\overline {\beta _{3^ + }} }}.$$

Equation (8) reveals a non-linear relationship between $\overline {SIE_{4^ + , \,\,St^{{\rm th}}}}$ and $\overline {\beta _{3^ + }}$. This non-linear relationship signifies that the reduction rate in $\overline {SIE_{4^ + , \,\,St^{{\rm th}}}}$ could be several times greater than the reduction rate in $\overline {\beta _{3^ + }}$. Specifically, for the equilibrium state of 1989–2006, where $\overline {\beta _{3^ + }} = 71.7\%$, $\overline {SIE_{4^ + , \,\,St^{{\rm th}}}}$ will be 2.53 times the $\overline {SIE_{3, \,\,St^{{\rm th}}}}$. In comparison, for the equilibrium state of 2007–22, where $\overline {\beta _{3^ + }} = 47.0\%$, $\overline {SIE_{4^ + , \,\,St^{{\rm th}}}}$ will reduce to only 0.89 times the $\overline {SIE_{3, \,\,St^{{\rm th}}}}$. With Eqn (8), we can reconstruct $\overline {SIE_{4^ + , \,\,St^{{\rm th}}}}$ over 1990–2007 and 2008–22 by substituting $\overline {SIE_{3, \,\,St^{{\rm th}}}}$ and $\overline {\beta _{3^ + }}$ into it. Given that the extent of 3 year ice exhibits no significant trend, its average value over 1985–2022 was used to substitute for $\overline {SIE_{3, \,\,St^{{\rm th}}}}$. Then $\overline {\beta _{3^ + }}$ in periods over 1989–2006 and 2007–22 were substituted into Eqn (8), respectively, to obtain $\overline {SIE_{4^ + , \,\,St^{{\rm th}}}}$ in their corresponding periods. The outcomes indicate that the reconstructed $\overline {SIE_{4^ + , \,\,St^{{\rm th}}}}$ can capture the shift observed between two periods (Fig. 3c), validating Eqn (8) and highlighting the role of decreased $\overline {\beta _{3^ + }}$ in controlling the decline of $\overline {SIE_{4^ + , \,\,St^{{\rm th}}}}$.

Figure 3d shows the net loss/replenishment of 4+ year ice extent ($SIE_{4^ + , \,\,( n, \,\,St^{{\rm th}}) }-SIE_{4^ + , \,\,( n-1, \,\,St^{{\rm th}}) }$), which predominantly displays characteristics of interannual oscillations. These oscillations are possibly related to the negative feedback of SIE (Notz and Marotzke, Reference Notz and Marotzke2012), where most strong negative year-to-year change in SIE is followed by a positive year-to-year change and vice versa. Notably, a sustained net loss is observed during the period 2004–10. Here, this period could be considered as a transition period from a regime with relatively high $\overline {\beta _{3^ + }}$ (1989–2006) to a regime with relatively low $\overline {\beta _{3^ + }}$ (2007–22). Specifically, lower $\overline {\beta _{3^ + }}$ represents greater loss and less replenishment for the 4+ year ice extent. As a result, the 4+ year ice extent must reduce to a certain degree to achieve a balance between its loss and replenishment, thereby maintaining an equilibrium state as demonstrated by Eqn (8). Therefore, rather than regarding the sustained loss during 2004–10 as a cause, it is the relatively low $\overline {\beta _{3^ + }}$ since 2007 that has controlled or maintained the relatively low 4+ year ice extent.

4.3 The contribution of various processes on the decrease of survivability

Then how have various processes contributed to the decrease of $\overline {\beta _{3^ + }}$ since 2007? As described in Section 3, we will first illustrate the MYI loss of each SIA due to export through FS and summer melting (Fig. 4), and then focus on their loss rate concerning the budget of $\overline {\beta _{3^ + }}$ (loss divided by $SIE_{3^ + , \,\,( n-1, \,\,\,St^{{\rm th}}) }$; Fig. 5).

Figure 4. Multi-year ice extent loss due to (a) export through Fram Strait and (b) summer melting during 1985–2022. The gray line in (a) indicates the export flux of total ice (FYI and MYI).

Figure 5. The 3+ year ice loss rate during 1985–2022 contributed by (a) export through FS, (b) summer melting, (c) residual part in the growth season and (d) residual part in the melt season. (e) Comparison in the average loss rate between 1989–2006 and 2007–22.

The average annual area export of total ice (including MYI and FYI) through the FS is ~0.75 × 10⁶ km² (Fig. 4a), with MYI accounting for 66% (0.50 × 10⁶ km²). This proportion closely aligns with the findings (67%) reported by Wang and others (Reference Wang, Bi and Liang2022), although they identify the MYI based on satellite products during 2002–20. Additionally, the results are not sensitive to the location of the gate (Fig. S5). Notably, since around 2007, the 2–3 year ice flux has dominated the MYI flux, while the flux of 4+ year ice accounts for only a minor proportion. Furthermore, over our study period, the MYI proportion in export through FS decreased significantly at a rate of −4% (p = 0.015; not shown). Therefore, the ice export through FS has become younger, which could be due to the contraction of MYI away from FS towards the north of CAA (Krumpen and others, Reference Krumpen2019; Reference BabbB23).

For the MYI loss due to summer melting, its annual average is ~0.32 × 10⁶ km² (Fig. 4b). Before around 2010, the MYI melt was mainly 5+ year ice, but after that, it shifted to being primarily composed of 2–3 year ice. In 2013, our estimated MYI melt was extremely low. This is because the summer minimum extent edge in 2013 was more extensive than the previous few years, and simultaneously, few MYI were moving outside of it during the growth season (Fig. 1; Perovich and others, Reference Perovich2013). This low melt is consistent with a relatively high sea-ice volume in 2013 (Tilling and others, Reference Tilling, Ridout, Shepherd and Wingham2015). Again, it is important to note that the estimated MYI melt presented here and below does not account for MYI melt within the summer minimum edge (see Sections 3.2 and 5), and therefore, may underestimate the actual MYI melt area.

Regarding the loss rate driven by the export of 3+ year ice through the FS, no significant trend has been observed since the early 1990s (Fig. 5a). Moreover, there is only a modest increase before and after 2007 (12.6 vs 15.4%; Fig. 5e), suggesting that the export through FS may not be a primary contributor to the decrease of $\overline {\beta _{3^ + }}$ since 2007.

For the melt rate of 3+ year ice, there was an evident increase during 2007–16, although it appeared to rebound back in recent years (Fig. 5b). The average melt rate has significantly risen from 4.9 to 14.3% before and after 2007 (Fig. 5e). Consequently, we can attribute the intensified summer melting as a main contributor to the decrease of $\overline {\beta _{3^ + }}$. As stated in Section 3.2, it is worth emphasizing that the estimated melt primarily consists of those 3+ year ice that move to regions that are relatively warm and hard to survive, such as the Beaufort Sea and Chukchi Sea, rather than where they formed. Specifically, during 1989–2006, the summer minimum extent edge is relatively more extensive, and there is only limited 3+ year ice located outside of the edge at the onset of melt season (Fig. 6a). Consequently, the amount of melted 3+ year ice is expected to be relatively small. In contrast, after 2007, the summer minimum extent edge has significantly shrunk, especially in the Pacific Arctic (compare the white lines in Figs 6a, b), corresponding to intensified melting. However, as a permanent system, the Beaufort Gyre could consistently transport 3+ year ice from the north of CAA to the Beaufort and Chukchi seas during the growth season. This process can be clearly indicated by the westward extension of the tongue of MYI drawn through the Beaufort Gyre (see shading in Fig. 6b and the 10th week in Fig. 1). Since the MYI typically cannot survive through the Beaufort Gyre in recent periods (Maslanik and others, Reference Maslanik2007; Kwok, Reference Kwok2018; Babb and others, Reference Babb2022), the loss rate of melt is expected to increase. In addition, the Beaufort Gyre has strengthened during the growth season since 2007, as indicated by the vectors in Figure 6c. This strengthening may be associated with dipole sea-level pressure anomaly patterns (contours in Fig. 6c) and decreasing ice thickness (Rampal and others, Reference Rampal, Weiss and Marsan2009). Consequently, this enhanced Gyre can transport more 3+ year ice to the Beaufort and Chukchi seas, where the summer 2 m air temperature has warmed noticeably since 2007 (shading in Fig. 6c), possibly helping more melt.

Figure 6. Ratio of each gridcell occupied by 3+ year ice at the onset of melt season (20th–25th weeks) during (a) 1989–2006 and (b) 2007–22. The white line indicates the averaged summer minimum SIE during corresponding periods. (c) The difference of SIM (vectors) and sea-level pressure averaged over January–May (contours), and 2 m air temperature averaged over August–September (shading) between 2007–22 and 1989–2006. (d) The increase of FYI extent from 1st week (1–7 January) averaged over 2011–22 (red line) and 1989–2010 (black line). The asterisks indicate where their difference is significant (p < 0.1; two-sample t-test). The shadings represent the range of one std dev.

The residual loss rate during the growth season shows a noticeable increase after 2011 (Fig. 5c), corresponding to the stepwise decrease of $\beta _{3^ + , \,\,n}^{{\rm growth}}$ since 2010. Before and after 2007, it has increased from 7.7 to 16.5% (Fig. 5e), thus also largely contributing to the decrease of $\overline {\beta _{3^ + }}$. The residual loss rate during the melt season is relatively small compared to its counterpart in the growth season, exhibiting an increase from 3.1 to 6.7% before and after 2007 (Figs 5d, e). While the exact causes of the increased residual term remain uncertain, we speculate that increasing sea-ice deformation processes, which are related to ice becoming thinner and more dynamic (Rampal and others, Reference Rampal, Weiss and Marsan2009; Zhang and others, Reference Zhang, Lindsay, Schweiger and Rigor2012), may have played a role. For the MYI, its export through FS and convergence can both reduce its area but produce FYI during winter (see also Section 3.3). Since 2011, the FYI production during winter in the Arctic Basin has significantly increased compared to before (Fig. 6d). Notably, this increase can even be evident in the north of CAA (Fig. S6), where is dominated by the oldest ice in the Arctic. Given that the MYI export through FS exhibits a decreasing trend since 2011 (Fig. 4a), we consider that the increased FYI production during winter since 2011 may serve as potential evidence of the strengthened deformation process of MYI, thereby contributing to the increased residual term during the growth season. Detailed examinations of these processes are a promising avenue for future research.