Long term decline of the planktonic biomass in a hotspot of nitrogen fixation

Abstract

Oceanic N₂ fixation by diazotrophic microorganisms is the primary external source of new nitrogen to the surface ocean sustaining net production of organic matter. Studying long-term trends in biomass within N₂ fixation hotspots is crucial for understanding and predicting the response of N₂ fixation to global climate change. Here we developed a bio-optical model based on the spectral phytoplankton absorption coefficient derived from satellite ocean color observations to estimate a proxy for particulate organic nitrogen in the western tropical South Pacific. We demonstrate the existence of a seasonal new biomass production annually over the past 20 years, likely driven by recurrent N₂ fixation. Importantly, our results also reveal a gradual decline in biomass within this N₂ fixation hotspot over the last two decades. This decline indicates that seasonal nitrogen inputs via N₂ fixation are decreasing. This trend inevitably could lead to a decline in the efficiency of the biological carbon pump, with potential implications for global biogeochemical cycles and climate regulation.

Introduction

The nutrient availability in the upper ocean, and more particularly fixed nitrogen (N) availability^1,2,3 is a key factor limiting the growth of marine biota and the build-up of organic matter in the ocean⁴. Accordingly, the addition of new N to the bioavailable pool enhances the ocean’s capacity to store organic carbon and its derivatives, while removing it might decrease this capacity⁴. The major external source of new N to the surface open ocean, before atmospheric deposition and riverine inputs, is from biological N₂ fixation by diazotrophic microorganisms^5,6. This process offers the marine phytoplankton community a mechanism to relieve N limitation in the euphotic surface layer, sustaining net production of organic matter in surface waters as well as carbon export from the upper surface to the ocean interior by biological processes (the biological carbon pump, BCP)^7,8.

The western tropical South Pacific is an oligotrophic area⁹, characterized by an archipelago of islands (referred as the Melanesian archipelago), including New Caledonia, Vanuatu, and Fiji, situated in the western part of the Tonga-Kermadec subduction zone. Large blooms of diazotrophs have been observed in this vast region extending from the Melanesian archipelago to the Tonga Trench^10,11,12,13. In this area identified as a hotspot of N₂ fixation¹⁴, previous studies have shown that the net production of organic matter is supported almost exclusively by N₂ fixation, which is primarily controlled by phosphate availability¹⁵ in this iron-rich environment fertilized by the volcanic arc of Tonga¹⁶. Obtaining an insight into the controls and variability of the particulate organic matter pool produced via N₂ fixation over long temporal scales is thus important for understanding the future role of these parts of ocean as a sink of CO₂. This is particularly important as the intensity of N₂ fixation, and the amount of particulate organic matter produced and exported may be altered in the future ocean^17,18,19. However, despite decades of satellite observations of surface mass concentrations of particulate organic carbon (POC) and chlorophyll-a^20,21,22,23, the temporal and spatial variability of biomass in the western tropical South Pacific remains poorly characterized.

The use of the seawater inherent optical properties (IOPs) measured in situ or estimated from spaceborne remote-sensing platforms using ocean color radiometry, represents an alternative to discrete measurements of particulate organic matter. To a first order, the variability in particulate IOPs is driven by the total concentration of suspended particulate matter and by composition and particle size distribution at second order. In the western tropical South Pacific, a relationship was identified, for the first time, between surface mass concentrations of particulate organic nitrogen (PON) and spectral particulate backscattering coefficients, b_bp(λ), measurements (where λ is the wavelength in a vacuum) performed by BGC-Argo floats²⁴. The use of this relationship made it possible to study the temporal variability of PON and thus to highlight the seasonal increase of biomass during summer periods in absence of significant N sources other than N₂ fixation. However, while BGC-Argo float measurements successfully revealed seasonal-scale variations in PON, they were limited in providing a long-term perspective, which is crucial for understanding the future role of N₂ fixation hotspots. Moreover, although it has been confirmed that b_bp(λ) can provide a good proxy of PON in open-ocean environments^24,25, it has been shown that the total particulate, a_p(λ), and phytoplankton, a_ph(λ), spectral absorption coefficients demonstrate a better capacity to serve as proxy for PON²⁵. The use of satellite ocean color observations currently offers the opportunity to observe trends over relatively long timescales. Given that the IOPs can now be estimated from satellite ocean color observations^26,27, the use of IOPs estimated from satellite observations therefore offers the unique opportunity to study the spatial and temporal variability of PON over the entire period of satellite data acquisition in environments characterized by active biological N₂ fixation, where N budgets are needed.

In this study, we aim to assess the seasonal and interannual variability, as well as the trend of PON in the western tropical South Pacific using ocean color remote-sensing data collected from December 2002 to December 2022. To address this, we developed and validated a new bio-optical model based on a_ph(λ) coefficients derived from satellite ocean color observations to estimate PON^26,27. This algorithm is based on a relationship developed over a global dataset of coincidence between in situ PON measurements and satellite derived a_ph(λ) product using the GlobColour²⁸ remote sensing reflectance as input parameter. The seasonal and interannual variability of PON was analyzed by temporally decomposing the algorithm-derived PON time series using the Census X-11 method²⁹. To examine the long-term trend, we applied the non-parametric seasonal Kendall test²⁹. Finally, we evaluated the implications of PON concentration temporal trends for the BCP.

Results and discussion

Comparison between the algorithm-derived and measured PON

Figure 1a shows a map of monthly average algorithm-derived PON concentrations in the South Pacific over the time period of the OUTPACE cruise⁹. For comparison, the field surface PON measurements collected during the cruise and not used in the development of the algorithm are also shown (colored markers). The application of the a_ph(442)-based algorithm to the satellite ocean color observations reveals a global pattern of PON distribution consistent with the expected geographical distribution observed in situ during the OUTPACE cruise. Relatively elevated PON ranging from 8 to 14 mg m^-3 are observed in the western part of the South Pacific bounded between southern New Caledonia at 22°S to northern Vanuatu and Fiji Islands at 14°S and between 160°E and 170°W (black solid box on Fig. 1a). In striking contrast, very low concentrations, 2 to 3 times lower than those in the Melanesian archipelago, are found to the east of the Tonga-Kermadec arc within the South Pacific Gyre (black dashed box on Fig. 1a). The results in Fig. 1a demonstrate the ability of the a_ph(442)-based algorithm to effectively reproduce contrasting spatial patterns of PON concentrations between these two distinct biogeochemical provinces. It is worth noting that at the spatial and temporal scale of the OUTPACE cruise, both algorithm-derived POC and chlorophyll-a concentrations follow the same spatial patterns as PON, with a clear distinction between the biomass-rich waters of the Melanesian archipelago and the oligotrophic waters of the gyre (Supplementary Fig. 1 and Fig. 2).

Fig. 1: Surface mass concentrations of particulate organic nitrogen (PON) in the tropical South Pacific in March 2015.

Average 1-month (March 2015) composite images of (a) algorithm-derived PON concentrations (mg m^-3) in surface waters of the tropical South Pacific. The black solid and dashed boxes refer to the Melanesian archipelago and the South Pacific Gyre areas, respectively. The red box corresponds to the region defined as N₂ fixation hotspot¹⁶. b Station-by-station comparison between the algorithm-derived PON concentrations (mg m^-3) (blue squares) and the surface in situ PON concentrations measured in the mixed layer during the OUTPACE cruise (green circles). Shaded regions show standard deviation around the satellite mean derived PON concentrations. Error bars show standard deviation around the in situ PON concentrations.

Fig. 2: Temporal variability of surface mass concentrations of particulate organic nitrogen (PON).

a Temporal variations of monthly PON concentrations (mg m^-3) in surface waters as indicated with blue and grey colors corresponding to the Melanesian archipelago (station 9 on Fig. 1a), South Pacific Gyre (station 15 on Fig. 1a) datasets, respectively. b Temporal variations of monthly PON concentrations in surface waters of the Station ALOHA (black triangle on Extended data Fig. 4). Shaded regions show standard deviation around the mean. The green circles refer to the surface in situ PON concentrations measured at the Station ALOHA. c Contribution of the seasonal, and (d) trend components to the total variance of PON in the Melanesian archipelago region (black solid box on Fig. 1a) as calculated with the Census X-11 method applied on the monthly time series between December 2002 and December 2022.

To evaluate the regional performance of the a_ph(442)-based algorithm, a station-by-station comparison was performed between the algorithm-derived and the measured PON in the western tropical South Pacific (Fig. 1b). We applied the a_ph(442)-based algorithm to satellite data with an 8-day temporal resolution and a 25 km spatial resolution. The station-by-station comparison reveals excellent agreement between PON derived from algorithms and measured PON over the whole range of longitudinal variability measured during the OUTPACE cruise. Relatively high values are observed in the Melanesian archipelago, especially at station B, followed by a sharp decrease in values between stations 13 and 15. The best-fit regression functions of algorithm-derived vs. measured PON align closely with the 1:1 line (Supplementary Fig. 3). The aggregate bias is negligibly small with a median ratio, MdR = 0.97. For all stations, a_ph(442) reproduce the PON variability with a median absolute percentage difference, MdAPD, values slightly below 15% (Supplementary Table 1). Although PON is associated with both phytoplankton and non-algal organic particles and the a_ph(λ) are intended to represent the light absorption only by phytoplankton pigments, these results confirm that a_ph(442) has the ability to predict PON in the western tropical South Pacific (Supplementary Table 1). This can be explained by the fact that, non-algal particles (including detritus, bacteria, zooplankton) are generally correlated with phytoplankton biomass³⁰. As a result, phytoplankton absorption is expected to be strongly correlated with the overall PON pool in the western tropical South Pacific Ocean. In addition, in this specific environment characterized by intense biological N₂ fixation, most of the new N is rapidly synthetized into the phytoplanktonic biomass. Even if part of N is released to the labile dissolved organic and inorganic pools, it is rapidly re-assimilated by the N-starved organisms^31,32. Therefore, the PON variability in this region is mostly related to living organic matter, i.e. phytoplankton cells, and to a lesser extent, detritus²⁴.

Temporal variability of surface PON concentrations

The temporal variations of algorithm-derived PON were extracted at two contrasting stations (Fig. 2a): one located in the Melanesian archipelago to the south of Fiji Island (station 9 on Fig.1a) and the other situated in the waters of the South Pacific Gyre (station 15 on Fig. 1a) over two decades from December 2002 to December 2022. For comparison, Fig. 2b also includes the temporal variations of both in situ (green color) and algorithm-derived PON (red color) extracted in the North Pacific Subtropical Gyre at the Station ALOHA (black triangle on Supplementary Fig. 4).

In the South Pacific Gyre, very low seasonal variations were observed. Indeed, the algorithm-derived PON remained relatively constant throughout the study period, with an average value of 4.3 ± 0.6 mg m^-3 (Fig. 2a). The concentrations of PON in the North Pacific Gyre were also extremely low (4.1 ± 0.6 mg m^-3), with very similar values as those observed in the South Pacific Gyre (Fig. 2b), suggesting a relatively steady phytoplankton biomass and associated particles in both regions. It is notable that the algorithm-derived PON agree reasonably well with in situ PON measurements at Station ALOHA, thus confirming the ability of a_ph(442) to accurately predict PON in oligotrophic subtropical waters over the past two decades. The results are consistent with expectations regarding the variability of PON in open-ocean environments. For example, remarkably stable and low (~3 mg m^-3) surface concentrations of PON have been reported in the South Pacific Gyre at seasonal temporal scales²⁴. Similarly, at Station ALOHA in the North Pacific Subtropical Gyre, the concentrations of PON in surface waters average between 4.3 mg m^-3 in spring and 4.7 mg m^-3 in autumn³³. In these areas, previously defined as permanently stratified subtropical biomes³⁴, the low supply of nutrients year-round combined with a probable iron limitation of nitrogen fixation, constrain biological productivity, which is overall primarily limited by nitrogen availability in the region¹⁵.

In striking contrast, the temporal variation of PON observed in the Melanesian archipelago shows a clear seasonal cycle over the entire observation period (Fig. 2a). Despite interannual variability, the PON generally increases from November to January-February and decreases from March to July-August. During the austral summer (January-February), the maximum PON varies from about 10 and 14 mg m^-3 in the Melanesian archipelago, which is two to three times higher than in the subtropical North and South Pacific Gyres.

Comparison with existing satellite products shows that PON exhibits temporal patterns broadly consistent with satellite-derived POC³⁵ and chlorophyll-a²⁸ (Supplementary Fig. 5). Numerous studies have demonstrated that the carbon-to-chlorophyll-a ratio can vary substantially, particularly in oligotrophic regions^36,37. In contrast, satellite-derived POC and chlorophyll-a display nearly identical seasonal patterns (Supplementary Fig. 5a), with a very strong correlation (R² = 0.96, N = 243; Supplementary Fig. 6a), reflecting their common derivation from similar remote-sensing reflectance, R_rs(λ), band-ratio algorithms³⁸. Algorithm-derived PON displays only a moderate correlation with chlorophyll-a (R² = 0.43, N = 243; Supplementary Fig. 6b), with noticeable offsets during the austral winter (Supplementary Fig. 5b). Such wintertime increases in chlorophyll-a have already been reported in the western tropical South Pacific²⁴. However, while chlorophyll-a exhibited a pronounced seasonal cycle with higher values during the austral winter, PON concentrations over the same period remained relatively constant and low. This decoupling indicates that winter increases in chlorophyll-a largely reflect physiological responses to light limitation rather than actual biomass accumulation^39,40, potentially leading to biased estimates of new biomass production²⁴. Although our PON product may also be subject to some degree of photoacclimation, the effect appears to be small. For example, in the South Pacific Gyre, where biomass remains relatively constant over time²⁴, PON concentrations exhibited only minor winter increases (<1 mg m^-3; Fig. 2a), which are negligible compared to the much larger variability observed in the Melanesian archipelago. This supports the robustness of the PON algorithm in capturing biologically driven dynamics, such as N₂ fixation, with minimal interference from physiological light responses.

The Census X-11 method was applied in the selected region of the Melanesian archipelago spanning from New Caledonia to the Tonga volcanic arc (within the black box on Fig. 1a). In the Melanesian archipelago, the seasonal component accounts for most of the total variance, with an average contribution of 50 ± 7% (Fig. 2c). The area where the seasonality in the data is maximal is located in the south of the Fiji Islands, with a variance contribution ranging between 28 and 70 % of the total variance. It is important to emphasize that the observed seasonal production of biomass in the Melanesian archipelago occurs in surface waters despite no winter replenishment of nitrate (NO₃^-) to surface waters¹⁵. Observations from the OUTPACE¹⁵, TONGA¹⁶, and the GLODAPv2.2⁴¹ (Supplementary Fig. 7) datasets indicate that no NO₃^- was quantified (limit of quantification = 0.05 µM) in the top 100 m of the water column in this region. This is because the deepening of the mixed layer depth (MLD) which averages 70 m during the winter mixing period (black and light blue lines on Supplementary Fig. 7), is insufficient to reach the nitracline (~ 100 m)¹⁵. However, the deepening of the MLD is sufficient to reach the phosphacline (~ 30 m)¹⁵. Consequently, the seasonal winter mixing plays a significant role in providing excess PO₄^3- relative to NO₃^- to the upper waters, and therefore in controlling N input by N₂ fixation¹⁵.

Apart from the role of winter mixing in supplying nutrients, it is important to assess the contribution of potential additional sources of NO₃^- to surface waters. In this context, we considered the potential role of vertical turbulent diffusion of NO₃^-. During the OUTPACE cruise, in situ microstructure measurements, including estimates of the vertical diffusion coefficient, were performed within the upper 800 m of the water column⁴². Based on these measurements, theoretical NO₃^- inputs from deep waters through turbulent diffusion at the top of the nitracline (~ 100 m) were estimated⁶. These observations indicated that vertical turbulent diffusion may provide only a minimal contribution (1−8%) to new nitrogen inputs in the photic layer of the western tropical South Pacific, far lower than the contribution from N₂ fixation. Given that the nitracline depth (~100 m) has remained relatively stable in this region¹⁵ (Supplementary Fig. 7), such low NO₃^- fluxes are expected to have had no significant impact on biomass production within the upper 0−50 m of the water column, where most N₂ fixation occurs^12,13,16.

Beyond vertical turbulent diffusion processes, atmospheric deposition may also represent a potential external source of nitrogen to surface waters. It is worth noting that the western tropical South Pacific receives among the lowest levels of atmospheric nitrogen deposition worldwide^43,44,45. During the OUTPACE cruise, atmospheric nitrogen deposition fluxes in the Melanesian archipelago ranged between 0.51, and 0.90 µmol N m^-2 d^-1, which are ~3 orders of magnitude lower than the N₂ fixation rates measured during the same cruise⁶. These results indicate that atmospheric deposition accounted for <1.5% of the total new nitrogen input to surface waters⁶, confirming its negligible role in the nitrogen budget of this region. In order to account for potential temporal variability in atmospheric deposition over the study period, we analyzed satellite-derived Absorbing Aerosol Index (AAI)⁴⁶ data covering the last two decades (see Method). Supplementary Fig. 8 presents the mean AAI over the period 1995-2022. The average AAI values over the Melanesian archipelago and the surrounding waters of the South Pacific gyre are close to zero or even negative, indicating a persistent absence or extremely low presence of aerosols in the region over the last two decades. The mean AAI values are very low (<0.5) and exhibit a similar temporal pattern in both the Melanesian archipelago and the South Pacific gyre (Supplementary Fig. 8c). This confirms that atmospheric deposition levels are comparable in the archipelagic and gyre waters, supporting the assumption that differences in PON are not driven by variations in atmospheric nitrogen input.

Another source of NO₃^- could be provided from the few emerged Tonga islands, potentially supplying additional nutrients. A recent study demonstrates that nutrients of terrestrial origin are not sufficient to sustain blooms of large amplitude in the Melanesian archipelago¹⁶. The mass effects of these islands tend to be very localized around the islands, with a chlorophyll-a patch area of 9−13 km²⁴⁷, which is far less than the total surface area of the Melanesian archipelago. The results of Fig. 2a, c therefore provide important additional insights by confirming that a seasonal new production of biomass in the whole Melanesian archipelago exists over the last 20 years, likely related to recurrent N₂ fixation events. This new production is made possible by the supply of iron from the Tonga arc¹⁶ combined with a seasonal input of PO₄^3- in surface waters¹⁵.

In addition to the substantial contribution of the seasonal component, the analysis of the spatial patterns in the temporal variability using the Census X-11 method reveals that the trend-cycle (inter-annual nonlinear modulation) accounts for 23 ± 7 % of the total temporal variability over the two decades (Fig. 2d). As previously mentioned, the trend-cycle extracted from the X-11 procedures does not contain any additional variations related to inter-annual change in seasonality⁴⁸. Consequently, the X-11 trend-cycle component is more effective in capturing the long-term evolution of the mean variable under study, making it particularly suitable for modeling climate variations⁴⁹. Overall, the results shown in Fig. 2d support that, although the temporal variability of PON in the Melanesian archipelago is mainly driven by the seasonal component, there are external factors that partially control the long-term temporal variability of PON. Establishing relationships between long-term trends in new production of biomass and climate variability is beyond the scope of this study. However, it can be hypothesized that changes in climate forcing, such as global climate change or natural oscillations, and consequently changes in the environment in which diazotrophic microorganisms develop, may partly explain the notable contribution of the trend-cycle component to the total variance of the time series.

Long term trends

We now examine the long-term trend in PON within the Melanesian archipelago region (black solid box on Fig. 1a). For this purpose, we first tested for the presence of monotonic upward/downward significant inter-annual trends (expressed in %/year) in the time series of PON by using the non-parametric seasonal Kendall test. Significant decreasing trends (up to 3%/year) are observed south and east of the Fiji Islands, where the data seasonality is maximal, as well as in the western part of the Melanesian archipelago, particularly north and west of New Caledonia (Fig. 3a). The inter-annual changes of PON, extracted where significant trends are observed, confirm the latter observations. Specifically, the average PON values decrease significantly by 0.05 mg m^-3 y^-1 (R = −0.85, p-value < 0.01) over the last two last decades (Supplementary Fig. 9a). A similar pattern is observed for the median values of the PON (Supplementary Fig. 9b). These results indicate a robust decline in PON concentrations in some key areas of the Melanesian archipelago, providing valuable insights on the long-term changes in biomass in this N₂ fixation hotspot.

Fig. 3: Long term trend of surface mass concentrations of particulate organic nitrogen (PON).

a Significant monotonic trend in % per year (seasonal Kendal test, p-value < 0.05) of surface a_ph(442) algorithm-derived PON concentrations. b Regional averaged Census X-11 component of the seasonal term (mg m^-3) and (c) of the trend-cycle term (mg m^-3). The shaded area around the line represents the inter-pixel variability at a given date, and not the statistical uncertainty of the trend estimate.

The X-11 temporal decomposition of the seasonal and trend-cycle terms was applied specifically to the pixels where the seasonal Kendall test identified significant trends (p-value < 0.05) (Fig. 3b, c). The results of this temporal decomposition show that the significant decreasing trend observed in the Melanesian archipelago (Fig. 3a) is linked to a notable reduction in the amplitude of seasonal fluctuations (Fig. 3b). Specifically, the amplitude of the PON seasonal fluctuations decreases significantly (R = −0.87, p-value < 0.01) between 2003 and 2016, before reaching relatively stable values between 2016 and 2022 (Supplementary Fig. 10). The amplitude of the annual cycle of the seasonal term averaged over 2016-2022 is therefore 55% lower than the averaged one over 2003-2005 (Fig. 3b; Supplementary Fig. 10).

Along with the decrease in seasonal amplitude, the results of the X-11 temporal decomposition indicate an associated decline in the trend-cycle term between 2003 and 2022 (Fig. 3c). The trend-cycle term decreases by ~10% between 2003 and 2022, indicating a decline in PON in the Melanesian archipelago region.

We then examined the trend of the total area-integrated water column standing stock of PON in the upper 50 m (PON_{INT(0-50m)-total-area}) within the region influenced by natural iron supply from the Tonga arc, identified as N₂ fixation hot spot¹⁶ (red box on Fig. 1a). As expected, similar to surface PON concentrations, the analysis of seasonal variations in PON_{INT(0-50m)-total-area} (in unit of Tg) shows a recurring seasonal cycle from 1 year to the next, with increases from November to January-February and decrease from March to July-August (Fig. 4a). Despite interannual variability potentially linked to interannual fluctuations in PO₄^3- and/or iron inputs in surface waters, it is remarkable that the maximum values of peaks observed each year decrease significantly over time (R = −0.63, p-value < 0.01, Fig. 4a).

Fig. 4: Long term trend of standing stock of particulate organic nitrogen (PON).

a Temporal variability of the total area-integrated standing stock of PON (PON_{INT(0-50m)-total-area}, in unit of Tg). The black solid line is the best-fit function obtained from model-II linear regression between the annual maximum value and time. The panel includes the coefficient of correlation, R. b Cumulative yearly (from November to October) integration of the PON_{INT(0-50m)-total-area} within the top 50 m of the study area (red box on Fig. 1a). The black solid line is the best-fit function obtained from model-II linear regression. The panel includes the coefficient of correlation, R, and the slope, S, of the best linear fit. Dashed blue lines represent the 95% confidence interval.

To evaluate interannual changes in PON_{INT(0-50m)-total-area}, we calculated an approximation of the cumulative annual integration of PON_{INT(0-50m)-total-area} using the trapezoidal method with temporal unit spacing (see Method). The PON_{INT(0-50m)-total-area} values have been integrated over 12 months, for each year and including a complete seasonal cycle (from November to October). The analysis revealed a clear long-term decline in the cumulative annual integration of the total area-integrated standing stock of PON_{(INT(0-50m)-total-area} (in unit of Tg) within the top 50 m over the two last decades (Fig. 4b). The estimate of the rate of decrease is −0.010 ± 0.002 Tg y^-1 (p-value < 0.01), corresponding to an approximate reduction of 10% in the initial stock within the last 20 years. Overall, this declining trend in PON_{INT(0-50m)-total-area} (Fig. 4b), coupled with the reduced amplitude of seasonal PON fluctuations (Fig. 3b), provides strong evidence of diminishing seasonal biomass production in the Melanesian archipelago. Given that the surface waters of the western tropical South Pacific are consistently nitrogen-depleted^13,15,50 (Supplementary Fig. 7), these findings suggest a reduction of the input of N via N₂ fixation over time, potentially driven by changes in the availability of limiting nutrients, and/or in environmental conditions following anthropogenic or natural climate alteration.

Summary and implications for the biological carbon pump

Using a new bio-optical model based on a_ph(442) coefficient, estimated from satellite ocean color observations, an optical proxy of PON was derived providing a long-term (December 2002-December 2022) survey of biomass in the subtropical Pacific Ocean. Our results reveal that, over the past two decades, PON concentration was remarkably low in the surface waters of the North and South Pacific Gyres. In these regions, the absence of phytoplanktonic blooms is attributed to NO₃^- limitation^15,50, while N₂ fixation is likely constrained by limited iron and/or phosphate availability^15,51,52. In contrast, the temporal analysis of PON concentration within the NO₃^--depleted surface waters of the Melanesian archipelago¹⁵ highlighted a temporally variable new production of biomass over the past 20 years, likely driven by seasonal N₂ fixation. Previous studies have demonstrated that diazotrophic microorganisms significantly contribute to carbon sequestration in the deep ocean within the Melanesian archipelago^6,53, with the BCP almost exclusively sustained by N₂ fixation on a seasonal timescale¹⁵. Our findings suggest that the seasonal excess of new biomass production in the Melanesian archipelago, compared to the North and South Pacific Gyres, may contribute to the BCP and carbon sequestration over longer time-scale.

Our results reveal that over the last two decades there has been a gradual decline in biomass within this N₂ fixation hotspot of the Melanesian archipelago. This decline is attributed to a reduction in the amplitude of seasonal cycles over time, indicating that seasonal nitrogen inputs via N₂ fixation are decreasing and/or the seasonal export of PON are increasing. This trend inevitably leads to a significant reduction of nitrogen available to primary producers and to the entire food web. Such a reduction could contribute to a decline in oceanic carbon sequestration in the future, with potential implications for biogeochemical cycles and climate regulation. Our observations suggest a shift of the BCP out of its equilibrium state which need to be studied on a more global perspective. Our results closely agree with those observed in the northwestern Pacific Ocean¹⁹ where, based on the comparison of sediment trap data with physical and biogeochemical variables, the authors have shown that the magnitude of the springtime BCP has reduced with time due to a corresponding decrease in the biomass of cyanobacterial N₂ fixers¹⁹.

Although no long-term monitoring of iron inputs to surface waters in the Melanesian archipelago exists over the past two decades, all available measurements consistently indicate elevated iron concentrations in the Melanesian archipelago, regardless of the season considered, compared to the South Pacific gyre^16,51,52. Recent studies have shown that these relatively high concentrations in the Melanesian archipelago are driven by hydrothermal inputs from the volcanic arc, thereby sustaining iron enrichment^16,54. In iron-rich surface waters of the Melanesian archipelago, the seasonal variations in the rates of N₂ fixation are ultimately controlled by the concentration of phosphate, PO₄^3- in surface water, which are replenished through seasonal winter mixing¹⁵. In response to surface ocean warming, increased stratification is expected, which in turn will reduce nutrient fluxes to the upper ocean^55,56. Based on modeled forecast data from the CMEMS database (E.U. Copernicus Marine Service Information), a decrease in the annual mean depth of the MLD is observed in the Melanesian archipelago, particularly since 2014 (Supplementary Fig. 11). Such an increase in stratification is expected to be accompanied by a decline in the winter supply of PO₄^3- to surface waters. Alongside the increase in stratification, Gerace et al.⁵⁶ recently identified a deepening of the phosphacline, especially throughout the southern hemisphere, leading to increasing phosphorus stress for marine phytoplankton. Consequently, although this hypothesis has yet to be confirmed, a reduction in seasonal PO₄^3- inputs through winter mixing appears to be the most plausible explanation for the observed decrease in annual biomass production in the Melanesian archipelago.

In closing, as pointed out in previous studies^17,57,58,59, our results indicate that the productivity of the ocean, and hence the strength of the BCP, may be deviating from its previous equilibrium condition. Nevertheless, it is important to stress that the magnitude and direction of future changes in the N₂ fixation process and the BCP remains uncertain. In the broader context, the entire region under study is characterized by warm and persistently stratified surface waters, even during winter, which strongly limit vertical NO₃^- supply but simultaneously favor diazotrophs. Such conditions are expected to become more frequent in warmer and increasingly stratified nutrient-poor surface waters projected for the future, which could in turn favor diazotrophs and potentially enhance overall productivity^18,55,60. Our study demonstrates that the use of ocean satellite color data offers a promising alternative to discrete measurements for assessing trends in biomass in regions influenced by N₂ fixation, especially in response to surface ocean warming. Climate-induced changes in the ocean have the potential to affect N₂ fixation hotspots across the global ocean. A next step for this research would be to evaluate long-term trend in biomass using ocean color data in various hotspots of N₂ fixation across the global ocean. Such analyses could improve our understanding and predictive capability regarding the responses of N₂ fixation and the BCP to global climate change.

Methods

In situ measurements

A dataset of in situ measurements of mass concentrations of surface (<10 m) particulate organic nitrogen (PON) was compiled from multiple open access databases covering the period from 1997 to 2023 (Supplementary Table 2). Nearly all PON measurements are here considered as the particulate nitrogen retained by a pre-combusted Whatman GF/F filter according to the JGOFS (Joint Global Ocean Flux Study) protocol⁶¹. The exceptions were the “Oligotrophy to UlTra-oligotrophy PACific Experiment”, OUTPACE⁹, and the “shallow hydroThermal sOurces of trace elemeNts-potential impacts on the bioloGicAl productivity and biological carbon pump”, TONGA⁶², datasets, where PON measurements were quantified spectrophotometrically using the wet oxidation method based on persulfate digestion at 120 °C⁶³. PON concentrations obtained using the wet oxidation method has been shown to yield results consistent with the standard JGOFS/CHN protocol^64,65, ensuring methodological consistency for algorithm validation. To further evaluate this, we analyzed six oligotrophic seawater samples using both the wet oxidation and CHN methods applied during the OUTPACE cruise (Supplementary Table 3). Importantly, the results confirmed that PON concentrations obtained by the wet oxidation method are consistent with those from CHN analysis, within the expected uncertainty for oligotrophic waters.

In situ nitrate and phosphate measurements were extracted from the open-access Global Ocean Data Analysis Project version 2.2 (GLODAPv2.2) dataset⁴¹. These data correspond to the Melanesian Archipelago region, spanning latitudes 14°S to 24°S and longitudes 160°E to 170°W.

Ocean color data and PON algorithms

We used the GlobColour daily merged L3 Ocean Color remote sensing reflectance, R_rs(λ), (in sr^-1, where λ is light wavelength in vacuum) at 4 km x 4 km of spatial resolution²⁸ (https://hermes.acri.fr/images/GlobCOLOUR_PUG.pdf) collected from 1997 to 2023. We also used the GlobColour daily merged L3 chlorophyll-a concentrations at the same spatial resolution and time period²⁸. Particulate organic carbon (POC) concentrations were estimated from R_rs(λ) using the algorithm developed by Stramski et al.³⁵. Empirical PON algorithm was developed by using the spectral absorption coefficients of phytoplankton, a_ph(442) estimated from R_rs(λ) using a three-step inverse model (3SAA)^26,27. The satellite a_ph(442) were extracted over in situ PON measurements to generate the match-up dataset (Supplementary Fig. 12a). This dataset was computed following the Eumetsat validation protocols (EUM/SEN3/DOC/19/1092968)⁶⁶ which is in agreement with the NASA Ocean Color protocol⁶⁷. The matchups between satellite a_ph(442) and PON in situ measurements were performed within a 3 × 3 pixel-box centered at the location of the field station, and a minimum of 5 valid pixels with a coefficient of variation <0.15 were required to keep the match-up data point. This final dataset of 1979 matchup data points was divided into two parts: 70% for the model development dataset, (N = 1376, red markers on Supplementary Fig. 12a), and 30% for the model validation (N = 603, blue markers on Supplementary Fig. 12a). It should be noted that the frequency distribution of PON and a_ph(442) is comparable for the model and validation datasets (Fig. not shown).

In this study, model-II linear regression using the major axis method^68,69 was applied to the log₁₀-transformed PON and a_ph(442) coefficients derived from satellite data, to determine predictive relationships for PON (in unit of mg m^-3) as a function of a_ph(442). From these analyses, we present the best-fit equations in the form of a power function. The general formula of the power function is:

$${{{\rm{PON}}}}=226.58\,{{a}_{{{{\rm{ph}}}}}(442)}^{0.78\,}$$

(1)

The goodness-of-fit of regression equation was evaluated through the analysis of algorithm-derived PON vs. measured PON using independent satellite sensor-specific validation dataset. For this evaluation, model-II linear regression analysis was performed using the major axis method^68,69 applied to the data of algorithm-derived vs. measured PON. Additionally, this evaluation involves calculating several statistical metrics that quantify the differences between algorithm-derived and measured values of PON (Supplementary Table 4). Supplementary Fig. 12b supports a reasonably good agreement between PON derived from a_ph(442) and measured PON over the whole range of variability observed within the whole dataset. Deviation between the linear fit of the relationships between the a_ph(442)-algorithms derived PON and measured PON and the 1:1 line is very low (Supplementary Fig. 12b). The slopes, S, reach very high values (S = 0.94) and the coefficient of correlation, R, also shows high values (R = 0.88). The MdAPD and MdSA, values of the a_ph(442)-algorithm PON vs. measured PON relationships are 26.15 % and 30.10 %, respectively. Overall, this indicates that a_ph(442) has the potential to be used as predictive variable in a_ph(442)-based algorithms for estimating PON over a wide range of oceanic environments.

Absorbing Aerosol Index (AAI)

The Absorbing Aerosol Index (AAI) dataset provide from the Multi-Sensor Absorbing Aerosol Index (MS-AAI) data record (https://www.temis.nl/airpollution/absaai/#GOME2_AAI), which consists of AAI data from the TOMS, GOME-1, SCIAMACHY, OMI, GOME-2A, GOME-2B, and GOME-2C instruments. The AAI is based on the difference in reflectance measurements at two wavelengths, typically around 340 nm and 380 nm⁴⁶. The aerosol types that are mostly seen in the AAI are desert dust and biomass burning aerosols. By comparing the measured UV reflectance with the theoretical reflectance expected in a purely Rayleigh-scattering atmosphere (i.e., without absorbing aerosols), the AAI provides a qualitative estimate of the presence and intensity of UV-absorbing aerosols. When a positive residue is found, absorbing aerosols were detected. Negative or zero residues on the other hand suggest an absence of absorbing aerosols.

Mixed layer depth (MLD)

The MLD values were extracted at each station from the Multi-Observation Global Ocean ARMOR3D L4 reanalysis product (https://doi.org/10.48670/moi-00052)^70,71 which provides temperature and salinity profiles interpolated onto a regular grid, and is suitable for large-scale, long-term analyses. As the ARMOR3D L4 MLD product does not cover the earliest field cruises, we complemented our dataset with MLD values derived from the global climatology developed by⁷². It should be noted that both MLD values were calculated using a threshold criterion of a 0.2 °C temperature deviation from the reference value at 10 m depth.

Time series analysis

In the present study, the monthly time series of PON have been temporally decomposed using the Census X-11 method. This method has been introduced for the analysis of sea surface temperature⁴⁹ and has been extensively documented for various ocean color applications^{29,48,73,74,75,76}. This approach is of interest for precisely describing the temporal variation patterns in a time series. The iterative analysis based on the successive application of bandpass filters aims at decomposing the time series into three additive components representing the seasonal, the trend-cycle (inter-annual modulation), and irregular (or residual) modulations in the data. The relative part of the variance of the components is estimated for each grid point, to identify the spatial patterns of the temporal variability in the series.

In addition, we tested for the presence of monotonic upward or downward significant inter-annual trends in the time series of PON. We used the non-parametric seasonal Kendall test, based on the calculation of a set of Mann-Kendall statistics applied to each separate month, which are then combined to evaluate the existence of long-term monotonic changes in the original time series⁷⁷. We used Sen’s slope, a non-parametric slope estimator^77,78 to estimate the magnitude of each time series trend, expressed in % per year⁷⁹.

Estimation of the PON content integrated over the 0-50 m depth layer

Satellite observations of ocean color provide information restricted to the first optical depth. However, diazotrophic activity occurs not only in surface waters but also throughout the upper water column. In the western tropical South Pacific, N₂ fixation have been consistently detected in the top 50 m of the photic layer^12,13,14. To estimate and evaluate the long-term trend of standing stock of PON in the upper 50 m water column from satellite observations, it is possible to develop an empirical relationship to derive PON content integrated over the 0-50 m depth layer, and then apply it to satellite observations of ocean color. Similar empirical relationship between near-surface POC concentrations and POC content integrated over the euphotic zone have been developed to assess the integrated content of POC over the global ocean from satellite observations³⁵. In the Southern Ocean, the area-integrated water column standing stock of POC have been estimated in the upper 100 m water column from empirical relationship between surface POC concentrations and POC integrated within the 0-100 m depth layer⁸⁰.

In the present study, we develop an empirical relationship between in situ near-surface PON concentrations and the PON content integrated over the 0-50 m depth layer by using the OUTPACE and TONGA datasets. The OUTPACE cruise was conducted during the austral summer, from February 18 to April 3, 2015, along a 4000 km zonal transect from north of New Caledonia to the western part of the South Pacific Gyre⁹. Along this transect, 18 stations were sampled (black circle on Supplementary Fig. 4). The TONGA dataset includes PON measurements collected in the western tropical South Pacific in November 2019 along a west-to-east transect⁶¹ (white square on Supplementary Fig. 4). We assume that the 50 m depth boundaries the biologically active layer where the majority of PON production sustained by N₂ fixation takes place in the Melanesian archipelago. Our field data show that the surface PON concentration is reasonably well correlated with the PON integrated within the 0−50 m depth layer (Supplementary Fig. 13). The coefficient of determination between the log₁₀-transformed data is high (R² = 0.91) and the pattern of data suggests that the relationships can be well described by a power function (blue line Supplementary Fig. 13):

$${{{{\rm{PON}}}}}_{{{{\rm{INT}}}}(0-50{{{\rm{m}}}})}=63.62\times {{{{\rm{PON}}}}}^{0.80}$$

(2)

For comparison, Supplementary Fig. 13 includes the relationship established in the North Pacific subtropical gyre using in situ measurements of PON performed over two decades from December 2002 to December 2022 as part of the Hawaii Ocean Time-series, HOT, program at Station ALOHA (black triangle on Supplementary Fig. 4). It is notable that the best-fit power functions for the PON_INT(0-50m) vs. PON are similar for the whole dataset and its subsets, HOT and OUTPACE/TONGA datasets. This indicates, on one hand, that the PON_INT(0-50m) vs. PON relationship is consistent for different subtropical regions of the open ocean, and on the other hand, that it shows relatively low variability over time.

Therefore, based on these observations, the relationship established in the western tropical South Pacific has been applied to satellite-derived monthly surface PON concentration in order to estimate the integrated water column standing stock of PON within the upper 50 m. Details of the method used to estimate the total area-integrated standing stock of PON within the top 50 m of the column waters of the study area are provided below. The first step involves estimating the integrated water column standing stock of PON within the upper 50 m (PON_INT(0-50m), in unit of mg m^-2) for each pixels in a restricted area of the western tropical South Pacific (red box on Fig. 1a). This corresponds to the area recently defined as N₂ fixation hotspot¹⁶. According to these authors, the fluids emitted from the Tonga volcanic arc have a substantial impact on iron concentrations in the photic layer. The natural iron fertilization fuels regional hotspot of N₂ fixation which extend 800 km in longitude and 400 km in latitude (~360 000 km²). The region defined as the hotspot of N₂ fixation was divided into sections of 1.5° of longitude and 1° of latitude, which is reasonably limited in terms of spatial extent. As a result, each satellite derived monthly maps of mass of PON_INT(0-50m) was divided into 16 sectors of 35 pixels each. As satellite data are not available at any given time, the number of valid pixels varies from one sector to another. It should be noted that each sector contains a sufficient number of valid pixels to calculate an average value of monthly mean of PON_INT(0-50m) in each sectors (PON_{INT(0-50m)-sector}, in unit of g m^-2).

$${{{{\rm{PON}}}}}_{{{{\rm{INT}}}}\left(0-50{{{\rm{m}}}}\right)-{{{\rm{sector}}}}}=\frac{1}{{{{{\rm{N}}}}}_{{{{\rm{p}}}}}}\,\sum {{{{\rm{PON}}}}}_{{{{\rm{INT}}}}(0-50{{{\rm{m}}}})}$$

(3)

Given the relatively small surface area of each sector, we assume that the data from the valid pixels provide an average value of PON_INT(0-50m). N_p is the number of valid pixels in each section. The next step was to calculate the area-integrated value of water column PON within each sector (PON_{INT(0-50m)-sector-area}, in unit of g). For that purpose, the PON_{int(0-50m)-sector} has been multiplied by the surface area (S, in unit of m²) of each sector.

$${{{{\rm{PON}}}}}_{{{{\rm{INT}}}}\left(0-50{{{\rm{m}}}}\right)-{{{\rm{sector}}}}-{{{\rm{area}}}}}={{{{\rm{PON}}}}}_{{{{\rm{INT}}}}\left(0-50{{{\rm{m}}}}\right)-{{{\rm{sector}}}}}\times {{{\rm{S}}}}$$

(4)

The final step involves calculating the total area-integrated standing stock of PON within the top 50 m of the column waters of the study area, PON_{INT(0-50m)-total-area} (in unit of g). Afterwards, PON_{INT(0-50m)-total-area} was converted to Tg (1 Tg = 10¹²g).

$${{{{\rm{PON}}}}}_{{{{\rm{INT}}}}\left(0-50{{{\rm{m}}}}\right)-{{{\rm{total}}}}-{{{\rm{area}}}}}=\sum {{{{\rm{PON}}}}}_{{{{\rm{INT}}}}\left(0-50{{{\rm{m}}}}\right)-{{{\rm{sector}}}}-{{{\rm{area}}}}}$$

(5)