Study area

The study area was located on northwestern Calvert Island on the central coast of BC, situated approximately 80 km north of Vancouver Island (Fig. 1a). Calvert Island is situated in the Hecate lowlands ecoregion in the CWH biogeoclimatic zone (Hebda 1995), Very Wet Hypermaritime subzone, and Central variant (CWHvh2; Banner et al. 2005). Calvert Island has a temperate, humid climate ( Supplementary Table S1 (cjss-2021-0033suppla.docx)¹1; MOE 2016). The characteristic tree species within the CWHvh2 variant are western redcedar (Thuja plicata Donn ex D. Don), western hemlock [Tsuga heterophylla (Raf.) Sarg.], and yellow cedar (Callitropsis nootkatensis D. Don), and the characteristic shrubs are false azalea (Menziesia ferruginea Sm.), salal (Gaultheria shallon Pursh), and Alaskan blueberry (Vaccinium alaskaense Howell; Banner et al. 1993). The Calvert Island chronosequence has a variety of specific site units within the CWHvh2 variant that also have Sitka spruce [Picea sitchensis (Bong.) Carr.] and shore pine (Pinus contorta Douglas ex Loudon var.contorta).

Studies from Haida Gwaii, about 250 km to the northwest, suggest that the Cordilleran Ice Sheet advanced over Calvert Island between 30 and 22 ka (Mathewes and Clague 2017), whereas a local study indicates that it had begun to retreat from Calvert Island by ∼18 ka (Darvill et al. 2018). Calvert Island was at least locally forested prior to 14.2 cal ka, when a cooling climate resulted in a short-lived glacial advance that ended by about 13.8 cal ka when relative sea level (RSL) dropped to a position slightly lower than present (Eamer et al. 2017, 2018). During that time, cold and dry conditions facilitated the development of significant dune fields along the coastal regions of Calvert Island, which had begun to stabilize by about 11 cal ka (Eamer et al. 2018). The period from about 8.5 until 0.4 cal ka saw the development and stabilization of extensive low-lying sandy landscapes (isthmuses), such as those that formed North and West beaches, and closed off Kwakshua Channel forming Pruth Bay (Eamer et al. 2018). Episodes of destabilization of sedimentary landforms as a result of fire have also been recorded on Calvert Island during postglacial time (Hoffman et al. 2016), and some events may have been associated with human presence in the area over the last 1000 yr (Stafford and Christensen 2014).

Calvert Island has a distinctive sea level history, whereby the RSL has remained within 1–2 m of the current sea level for the past 15 000 yr, following the retreat of the short-lived re-advanced lobe of the Cordilleran Ice Sheet mentioned earlier (McLaren et al. 2014; Eamer et al. 2017). Broader empirical evidence of RSL trends in the region suggests that the study site is located along a sea-level “hinge” where RSL changed very little over the Holocene due to the counteracting effects of isostatic rebound of Calvert Island coinciding with post-glacial eustatic adjustments (McLaren et al. 2014; Shugar et al. 2014; Eamer et al. 2017).

This study focuses on an array of sites developed on sandy landforms that are composed predominantly of quartz sand (Neudorf et al. 2015). Eight aeolian sand dune locations were examined in this study, with ages ranging from a modern, established foredune [∼0 yr before 2012, when samples were collected and dated (0 a)] to a stabilized, relict sand dune dated to approximately 10 760 ± 864 a ( Supplementary Table S2 (cjss-2021-0033suppla.docx)¹; Fig. 1b). These landforms were dated by optically stimulated luminescence (OSL) dating, which estimates the last time that mineral grains were exposed to sunlight (Neudorf et al. 2015). Prior to this study, these dune sites were visited to verify the extent to which they met key requirements for a soil chronosequence, including progressive soil development, minimal disturbance, similar soil parent material, and topography (Jenny 1941; Walker et al. 2010), and sufficient area to accommodate two replicate sampling locations. The maximum separation of these sites was approximately 8 km, so it would be reasonable to assume that similar climatic conditions would have existed across the sequence at any given time.

All parent material (C) and (or) deep transitional (BC) horizons when the C horizon was not reached were comparable in physical, chemical, and morphological characteristics (e.g., no differences in carbonate content, texture, colour; Nelson 2018). Drainage appeared to be similar across all sites, aside from those where cemented horizons impeded water flow, which is an expected stage of soil development in this portion of the CWH zone (Banner et al. 2005). Seepage was identified on the 3588, 4198, and 7236 a sites, due to the degree of cementation. All sites lie within 35 m of sea level, with the two sites at the lower end of the elevation range (105 and 7236 a) experiencing somewhat poorer drainage conditions ( Supplementary Table S2 (cjss-2021-0033suppla.docx)¹), although their relative degrees of soil development were comparable to those of other sites of similar age. Although there have been significant changes in climate during the past 11 000 a, palaeobotanical records show that current early successional plant species (e.g., coastal strawberry; Fragaria chiloensis ssp. Pacifica) were present on Calvert Island when the oldest site was formed (10 760 ± 864 a), and tree species currently dominant on Calvert Island [e.g., Sitka spruce, red alder (Alnus rubra Bong.) and redcedar] were also present by 840 a (Eamer 2017). The successional stage within the 605 a site was not consistent due to downed trees and large woody debris within the soil profile (replicate B); however, the degree of soil development and horizonation were not significantly disrupted and were comparable to replicate A. On balance, the Calvert Island sites collectively meet the requirements for a chronosequence study (Jenny 1941; Walker et al. 2010) and, as such, they provide adequate potential to yield insights into long-term soil and ecosystem development in this region.

Site selection and sample collection

Two sampling locations (designated as replicates A and B) on each sand dune were selected in stable, representative landscape positions to capture the variability of soil development within the dune. When possible, sampling locations were chosen on upland positions that were flat to gently sloping, with well- to moderately well-drained conditions. Elevation was estimated from a 3 m digital elevation model derived from aerial LiDAR ( Supplementary Table S2 (cjss-2021-0033suppla.docx)¹).

Horizons were designated and each pedon was described and classified according to Canadian System of Soil Classification (SCWG 1998) and Ministry of Forests and Range (2010). Samples were collected from each soil genetic horizon. All soil samples were air-dried, ground using a mortar and pestle or coffee grinder, and sieved to 2 mm. Soil mass per unit area was determined for individual horizons, except where multiple thin horizons were captured in a single core sample. For organic horizons, a cordless drill with a steel coring tube was utilized to sample the entire FF to calculate its mass per unit area (Nalder and Wein 1998). When the organic horizon thickness was greater than the length of the coring tube, a slide hammer and coring ring were used to take bulk density samples from the side of the pit, whereas for uncemented mineral soil horizons, a slide hammer corer was utilized on a ledge of undisturbed soil (Blake and Hartge 1986). For cemented soil horizons, the clod method was used to determine soil bulk density (Blake and Hartge 1986).

Soil characterization

Samples were sent to Maxxam Laboratories (Burnaby, BC) for particle size analysis via the pipette technique (Gee and Bauder 1986) after pre-treatment with hydrogen peroxide and citrate–dithionite–bicarbonate for removal of OM and iron oxides, respectively. Samples were sent to the BC MECCS Analytical Chemistry Services Laboratory (Victoria, BC) for chemical analysis, including total carbon (C) and nitrogen (N), exchangeable cations [calcium (Ca²⁺), magnesium (Mg²⁺), sodium (Na²⁺), and potassium (K⁺)], pH in 0.01 mol·L⁻¹ calcium chloride (CaCl₂), and total elemental analysis. Sample analysis is described in detail in Nelson (2018) and Nelson et al. (2020).

Sodium pyrophosphate (0.1 mol·L⁻¹) and acidified ammonium oxalate (0.2 mol·L⁻¹) were used to extract Fe, Al, and silicon (Si) from mineral samples, followed by inductively coupled plasma optical emission spectroscopy (McKeague and Day 1966; Courchesne and Turmel 2008). Pyrophosphate-extractable Fe (Fe_p) and Al (Al_p) represent organically complexed Fe and Al, whereas oxalate-extractable Fe (Fe_o) and Al (Al_o) represent amorphous and organically complexed Fe and Al. The difference between oxalate- and pyrophosphate-extractable Fe and Al provides an indication of the quantity of amorphous forms (Farmer and Fraser 1982; Gustafsson et al. 1995). The estimated concentration of allophanic materials (non-crystalline aluminosilicates) of each horizon was calculated using the method developed by Parfitt (1990).

Aboveground biomass measurements

Basal area was used as a surrogate method to assess aboveground tree biomass, and it was determined using an adapted form of the National Forest Inventory protocol (NFI 2008). Due to the variable widths of the dunes, the narrowest dune was used to determine the maximum radius for a fixed-radius plot allowing for replication. Therefore, a fixed-radius plot of 3.99 m was used. Basal area determination was replicated three times per site to encompass the variability of the aboveground biomass, and locations ran lengthwise across foredunes and were randomly spread on all other dunes. All trees over 9 cm diameter at breast height (DBH) were measured to one mm, whereas trees less than 9 cm DBH were tallied according to size class (0–2.9, 3.0–5.9, and 6.0–8.9 cm DBH).

Tree foliage sampling and analysis

Foliage was collected from western redcedar and western hemlock growing within 5 m of each pedon when present using an adapted Ballard and Carter (1986) method. Foliage samples were pruned by hand when possible and intact, green foliage was retrieved from the ground if hand sampling was not feasible. Sampling could not be limited to current year foliage because it was not possible to separate needle cohorts reliably on slow-growing, stunted trees on the older sites. Foliage samples were oven-dried at 60 °C, ground using a coffee grinder, and stored at room temperature in sealed plastic bags prior to analysis. Individual foliage samples were analyzed for total C, N, and P as described in Nelson (2018) and Nelson et al. (2020).

Chemical weathering index

The chemical index of alteration (CIA) provides an indication of the degree of weathering of a soil horizon by comparing the molar ratio of a relatively immobile element, Al, to the sum of Al and more mobile elements (Ca, Na, and K), expressed in oxide form (eq. 1; Nesbitt and Young 1982). Total element concentrations were obtained by lithium metaborate fusion using a Claisse M4 Fluxer (Claisse 2003) [see Nelson (2018) for more details]. The CIA values from the deepest C horizons on the youngest site (replicate A, C3 horizon; replicate B, C2 horizons) were used as the assumed parent geological material CIA value for comparison purposes. Calcium was corrected (CaO*) to represent only Ca occurring in silicate minerals (Nesbitt and Young 1982).

(1)

Data analysis

Means and standard deviations were calculated for the replicate pedons to examine variability within a dune. Because each profile had unique genetic horizons and associated thicknesses, a weighted average using bulk density and mass per area measurements were calculated for all horizon types (FF, A, and B) for all data unless otherwise noted. All depth graphs were created using weighted averages for 10 cm increments.

Linear and non-linear regression analyses were performed on the mass of total C to 1 m depth using STATA 14 IC. Akaike’s information criteria was used to determine which model fitted best, and only models that realistically represented pedogenic processes were used (Schaetzl et al. 1994).

Soil morphology

Pedons on the youngest site (∼0 a), an established foredune, were classified as Cumulic Regosols (CU.R; Table 1; Fig. 2; SCWG 1998). Within 105 ± 15 to 139 ± 17 a on stabilized, forested foredunes, bleached eluvial horizons had formed, and 28–37 cm of FF had accumulated (Table 1; Fig. 2). Pedons on these sites were classified as Eluviated Dystric Brunisols (E.DYB). After 605 ± 50 a, pedons on an established, forested dune with evidence of tree throw had developed diagnostic organic-enriched B horizons and ortstein cemented horizons. Pedons on the 605 a site were classified as E.DYB (Table 1).

Table 1.

Pedon classification, site series, and soil morphology including bulk density (Db) and pH in calcium chloride (CaCl₂).

Fig. 2.

Representative soil profiles from the youngest to the oldest sites on the Calvert Island Chronosequence, BC. The youngest site (0 a, CIDS1A) is a Cumulic Regosol, the 139 a (CIDS4B) is an Eluviated Dystric Brunisol, the 3588 a (CIDS8B) is an Ortstein Humic Podzol, and the 10 760 a (CIDS10A; knife handle is 11 cm) sites is a Placic Humic Podzol. [Colour online.]

Within 3588 ± 303 a, mature Podzols had formed on a forested, dune-capped tombolo landform, which is a narrow isthmus that connects the main island to smaller proximal island(s) (see Eamer et al. 2018). Two types of cemented horizons (ortstein and placic) had formed, and pedons met the criteria for an Ortstein Humic Podzol (OT.HP; Table 1; Fig. 2). The pedons at the 4198 a site exist on a relict (stabilized, inactive) forested foredune and were also classified as OT.HP. On the 7236 a site on a forested foredune, both pedons were classified as Humic Folisols (H.FO) due to FF thickness but morphologically resembled an Orthic Humic Podzol (O.HP; replicate A) and an Ortstein Humic Podzol (OT.HP; replicate B), respectively. Replicate B was sampled at the original site where the OSL sample was obtained, and the depth of soil development was considerably greater than for any other pedon, with the Bh horizon transitioning to a BC at 2.23 m (Table 1). The two pedons at the 10 760 a site, a dune occupied by bog forest, were morphologically similar, but differences in B horizon thickness placed them in different soil orders: Placic Humic Podzol (P.HP) and E.DYB (Table 1; SCWG 1998). The FF at this site had a distinctive light brown humic horizon (Hh2) beneath the much darker brown organic Hh1 horizon (Table 1; Fig. 2).

Most soil horizons remained structureless with increasing age; however, there was a shift from single grained to massive as cementation developed. Soil textures other than sand were present in some Ae and Ahe horizons after 3588 ± 303 a (Table 1). The average concentration of clay in all horizons is 2.2% [standard deviation (SD) 1.8] and ranged from <0.01% clay in the C horizons of the youngest site to 9.1% clay in the Ahe horizon of the 7236 a site ( Supplementary Table S3 (cjss-2021-0033suppla.docx)¹). Root restriction and seepage from temporary perched water tables above cemented horizons were evident at most sites older than 3500 a (Nelson 2018). Evidence of fire was prevalent in the form of charcoal in at least one horizon (typically the lowest organic or first mineral horizon) in all sites older than 3500 a and fires scars on living trees on all sites older than 7000 a.

Soil chemical properties

The greatest decline in pH was between 0 and 105 ± 15 a in all horizons, corresponding to Ae development and FF accumulation, followed by little change in the remainder of the chronosequence (Table 1). The pH within the FF decreased with depth (Nelson et al. 2020). The FF maintained appreciable concentrations of exchangeable base cations with increasing age, particularly on the 3588 and 4198 a sites (Fig. 3a). The greatest base cation concentration in the A horizon was found on the youngest site (∼0 a), and the least was on the oldest site (10 760 a; Fig. 3b). The concentration of base cations was least in the B horizon compared with all other horizon types (Fig. 3b).

Fig. 3.

Average sum of barium chloride-extractable base cations (Ca²⁺, Mg²⁺, Na⁺, and K⁺) of each soil horizon with one standard deviation indicated by the error bars; forest floor (FF; a), A and B mineral horizons (b; n = 2). (Note that the 0 a site did not have an FF or a B horizon, so only data for the BC horizon appear.)

The mass of C to 1 m depth, including the FF, increased with age up to 7200 a and then plateaued, and was fit with a Michaelis–Menton non-linear model (Fig. 4). The highest C mass was present on the 7236 a site (47.3 kg·m⁻²), and the lowest was on the youngest site (∼0 a; 6.3 kg·m⁻²). Total C mass on the oldest site (10 760 a; 23.9 kg·m⁻²) was less than on the 7236 a site.

Fig. 4.

Average mass of carbon (C) to 1 m depth for each site including the forest floor with one standard deviation (n = 2).

The peaks of Fe_p in the depth profile corresponded to the presence of placic horizons, whereas peaks of Al_p represented either ortstein or placic horizons (Fig. 5). Replicate A on the 3588 a site (CIDS8A) had the greatest Fe_p concentration, followed by the oldest site replicate A (10 760 a) and then replicate B on the 3588 a site (Fig. 5a). The CIDS10A pedon had the greatest Al_p concentration, followed by CIDS8B, CIDS8A, and CIDS10B (Fig. 5b).

Fig. 5.

(a) Pyrophosphate-extractable iron (Fe_p), (b) pyrophosphate-extractable aluminum (Al_p), (c) amorphous inorganic Fe [oxalate-extractable Fe (Fe_o) — Fe_p], and (d) amorphous inorganic Al [oxalate-extractable Al (Al_o) — Al_p] in selected pedons to 90 cm depth: 0 yr before present (a; site CIDS1, replicate A), 3588 a (site CIDS8, replicates A and B), 10 760 a (site CIDS10, replicates A and B).

The concentrations of amorphous Fe (Fe_o-Fe_p) and Al (Al_o-Al_p) increased with increasing age (Figs. 5c, 5d). Peaks in amorphous Fe did not always correspond to peaks in Fe_p, and the concentration of Fe_o-Fe_p decreased with increasing depth (Figs. 5a, 5c). Pyrophosphate-extractable Fe concentration ranged from 0.0 g·kg⁻¹ in the youngest sites to 19.7 g·kg⁻¹ in a Bfc1 (3588 a). Oxalate-extractable Fe ranged from 0.0 g·kg⁻¹ in an Ahb (0 a) to 34.2 g·kg⁻¹ in a Bfc2 (3588 a;  Supplementary Table S3 (cjss-2021-0033suppla.docx)¹). The total Fe concentration (Fe_T) in all horizons and ages ranged from 2.03 g·kg⁻¹ in an Ae horizon (4198 a) to 43.2 g·kg⁻¹ in a Bfc2 (3588 a;  Supplementary Table S3 (cjss-2021-0033suppla.docx)¹). The total amorphous Al concentration increased with increasing age. Amorphous Al was distributed throughout the profile for both replicates on the 3588 a site compared with the youngest site (∼0 a; Fig. 5d). Replicate B on the oldest site (10 760 a; CIDS10B) had an apparent peak of amorphous Al where the Bfc and Bmcj horizons were present, whereas the concentration of amorphous inorganic Al was relatively consistent with depth on site CIDS10A (Fig. 5d). The proportion of total Fe that was oxalate extractable was much greater than for Al (Nelson 2018). There was no clear separation with depth of pyrophosphate- or oxalate-extractable Fe and Al; however, appreciable concentrations of extractable Al (>1.0 g·kg⁻¹) extended to depths greater than extractable Fe ( Supplementary Table S3 (cjss-2021-0033suppla.docx)¹).

Estimated allophanic materials increased in abundance with increasing age (Fig. 6a;  Supplementary Table S3 (cjss-2021-0033suppla.docx)¹) with the B horizons on sites less than 3600 a exhibiting estimated allophane concentrations of 0.0–5.0 g·kg⁻¹, whereas sites >3600 a had estimated allophane concentrations of 0.0–41 g·kg⁻¹. Interestingly, the highest estimated allophane concentrations were not correlated to the greatest percent clay, although horizons with >5.0 g·kg⁻¹ estimated allophane typically had more clay than those without allophane. The youngest site, ∼0 a (CIDS1A), had a consistent, but minimal, concentration of estimated allophane throughout the entire profile. Soil depth profiles indicated increasing concentrations of allophane with increasing age, particularly in Ae, Bhc, and Bfc horizons (Fig. 6a). The peaks of estimated allophane concentration occurred closer to the surface in the older soils with estimated allophane concentrations >35 g·kg⁻¹ in the Bfc horizons at 10–15 cm depth on the 10 760 a site (both replicates), whereas the peak concentrations (>3.0 %) of estimated allophane on the 3588 a site was at depths greater than 57 cm in the Bfc2 (replicate A) and Bfcj1 horizons (replicate B) (Fig. 6a;  Supplementary Table S3 (cjss-2021-0033suppla.docx)¹). The 4198 a site (CIDS15) had the greatest concentration of allophane compared with all other soil profiles ( Supplementary Table S3 (cjss-2021-0033suppla.docx)¹).

Fig. 6.

Selected soil depth profiles for (a) estimated allophane (%) and (b) chemical index of alteration (CIA) values in the <2 mm fraction, with reference values for the assumed parent geological material determined for the deepest identified C horizons at the youngest site (site CIDS1; n = 2): 0 yr before present (a; site CIDS1, replicate A), 3588 a (site CIDS8, replicates A and B), 10 760 a (site CIDS10, replicates A and B). [Colour online.]

The average CIA for the assumed parent geological material was 44.5 (n = 2; Fig. 6b). All pedons had CIA values greater than the assumed parent geological material, except for the Ahb2 horizon on the youngest site (replicate A) that had a CIA value of 42.8 ( Supplementary Table S3 (cjss-2021-0033suppla.docx)¹), and with increasing age, the CIA ratio for all soil profiles increased. The 3588 a site had similar CIA values for both soil profiles, reaching a plateau around 49 in the B horizons (Fig. 6b). The CIA depth profiles for the oldest site (10 760 a) replicates followed similar trends, with the greatest CIA in the Bfc and Bmcj horizons. The highest CIA value identified on the chronosequence was in the Bfc horizons on the 10 760 a site with a CIA value of 55.2 (Fig. 6b;  Supplementary Table S3 (cjss-2021-0033suppla.docx)¹).

Aboveground biomass

Basal area was variable within and among sites (Fig. 7). The youngest site did not have any trees over 1.3 m height. With increasing landform age, the average BA increased until 3588 ± 303 a followed by a decline, except for the 605 a site (Fig. 7). The 605 a site did not have a consistent successional stage throughout due to significant tree fall. Only one of the three BA plots was in a mature forest so there was high variability within the 605 a site BA data (see Nelson 2018). Representative photographs of the youngest site, ∼0 a, an intermediate site, 3588 a, and the oldest site, 10 760 a (Fig. 8), display the build-up phase, maximal biomass phase, and decline phase, respectively, illustrating the decline in aboveground biomass with increasing age.

Fig. 7.

Tree basal area (BA) on each site by age [years before present (a); n = 3]. Standard deviation is indicated by error bars.

Fig. 8.

Characteristic photographs of the three successional stages present on the Calvert Island chronosequence; the progressive (build-up) phase (∼0 a; CIDS1), maximal biomass phase (3588 a; CIDS8), and the retrogressive (decline) phase (10 760 a; CIDS10). [Colour online.]

The youngest site had an early seral stage plant community consisting mostly of dune wildrye grass [Leymus mollis (Trin.) Pilg. subsp. mollis] and red fescue (Festuca rubra L. subsp. rubra) with other species that grow easily on naturally disturbed coastal dunes including yarrow (Achillea millefolium L.), Indian paintbrush (Castilleja miniata Dougl. Ex. Hook. var. miniata), coastal strawberry, and peavine (Lathyrus japonicus Willd.;  Supplementary Table S4 (cjss-2021-0033suppla.docx)¹). Red alder was only present on the 105 and 605 a sites. Sitka spruce was present on most intermediate-aged sites from 105 ± 15 to 4198 ± 332 a ( Supplementary Table S4 (cjss-2021-0033suppla.docx)¹). After 7236 ± 546 a, yellow cedar, mountain hemlock [Tsuga mertensiana (Bong.) Carr.], and shore pine became more dominant tree species and were associated with an increase in sphagnum moss (Sphagnum sp.) and Labrador tea (Rhododendron groendlandicum Oeder;  Supplementary Table S4 (cjss-2021-0033suppla.docx)¹).

Foliar N and P

Nitrogen concentrations declined from 9.7 g·kg⁻¹ at the 139 a site to 4.5 g·kg⁻¹ at the oldest site in western redcedar, and from 8.0 g·kg⁻¹ (SD 1.2) to 5.1 g·kg⁻¹ (SD 0.5) in western hemlock (Table 2). Phosphorus concentrations declined to a greater extent over the chronosequence, from 1.4 g·kg⁻¹ at 139 ± 17 a to 0.4 g·kg⁻¹ at 10 760 ± 864 a in western redcedar (Table 2). For western hemlock, the peak P concentration of 1.8 g·kg⁻¹ occurred at 605 a, declining to 0.5 g·kg⁻¹ (SD 0.0) on the 10 760 a site. As a result of these trends, the foliar N:P ratios gradually increased over time, reaching a maximum of 11.3 at the oldest site, and 10.2 at the second oldest site, for western redcedar and western hemlock, respectively (Table 2).

Table 2.

Nitrogen (N) and phosphorus (P) concentrations and ratio in western redcedar and western hemlock foliage with the standard deviation in brackets if applicable (otherwise the replicate of the sample is denoted), Calvert Island chronosequence.

Soil development trends and processes

Within the first 100 yr of soil development in this hypermaritime chronosequence, the soil morphological changes suggest that podzolization was the dominant soil-forming process. This rapid development can be attributed to the temperate climate and high rainfall (approximately 2800 mm·a⁻¹;  Supplementary Table S1 (cjss-2021-0033suppla.docx)¹). It took <105 ± 15 a of pedogenesis to develop a distinct eluvial horizon beneath a FF with well-differentiated S/L, F, and H horizons. Between 139 ± 17 and 605 ± 50 a, the development of an organic-enriched, weakly cemented B horizon occurred. By 3588 ± 303 a, a mature Podzol formed with both ortstein and placic horizons.

The primary cementing agents in placic horizons were organically complexed Fe and Al, whereas ortsteins were cemented by organically complexed Al and organic material. Some developing ortsteins, such as Bmcj horizons, were less enriched in organic material, but organically complexed Al was the likely cementing agent, consistent with findings by McKeague and Wang (1980), Lapen and Wang (1999), and Sanborn et al. (2011).

The base cation concentration in the FF was significantly higher than in the mineral soil, most likely due to surface enrichment from litter fall and the close proximity to sea spray. All sites were within approximately 310 m from the shoreline, with the 3588 and 4198 a sites being closest (140 m). On the west coast of Vancouver Island, sea spray can deposit on the order of 250 g·m⁻² of Na, 22 g·m⁻² of Mg, 8.9 g·m⁻² of K, and 7.0 g·m⁻² of Ca annually (Cordes 1972; Sondheim et al. 1981). The peak base cation concentration within the FF on the 3588 and 4198 a sites may be attributed to litterfall from the dominant yellow and redcedar, which are known to have high Ca concentrations (Radwan and Harrington 1986). However, the mineral horizons had continual depletion of base cations with age.

Comparison of soil development rates

Long-term ecosystem development

Plant communities on the Calvert Island chronosequence appear to have shifted from early successional plant communities on the youngest site (∼0 a) to climax plant communities on intermediate-aged sites (3588 and 4198 a), followed by a less-productive plant community that was adapted to poorer and wetter soil conditions by 10 760 ± 864 a (Figs. 8 and 9) (Banner et al. 2005). The younger and intermediate-aged sites on Calvert Island had more productive forest types CWHvh2 – 01 CwHw Salal (zonal forest) and 15-Ss Kindbergia (higher productivity, shoreline forest), whereas the older sites were 11-CwYc goldthread (bog forest), which are classified as low-productivity forests (Kranabetter et al. 2005). The distribution of tree BA along the Calvert Island chronosequence increased to a maximum followed by a decline as expected for a retrogressed chronosequence, despite the significant tree throw on the 605 a site. Tree throws occur frequently on Calvert Island due to high exposure to strong winter storm winds and because trees are typically shallowly rooted. As a result, trees on Calvert Island rarely live longer than 300 a.

Fig. 9.

Conceptual depiction of soil and forest development with increasing age along the Calvert Island chronosequence including the development of cemented ortstein (Bhc) and placic (Bfc) horizons with age and the dominance of stunted tree growth on the oldest sites. Note that implied horizon thicknesses in this diagram are relative, not absolute. For reference, the actual elevation range across the chronosequence is 3.6–34.6 m above sea level. Tree icons adapted from Banner et al. (1993) with permission [Copyright © Province of British Columbia. All rights reserved. Reproduced with permission of the Province of British Columbia].

The mass of total C on the 10 760 a site was less than the mass on the 7236 a site, partly due to differences in site microtopography, drainage, slope position, and resultant FF development, which resulted in the younger site accumulating a FF horizon thick enough to be classified as organic soil. Therefore, the mass of total C on the 7236 a site was uncharacteristically high. If this site were located in a comparable upland landscape position, it is likely that the mass of total C would follow the expected trend of increasing to a maximum and plateauing with increasing age; as such, the data were analyzed with a Michaelis–Menton non-linear model (Wardle et al. 2004; Wardle et al. 2008; Peltzer et al. 2010).

We previously reported significant declines in total P reserves along the Calvert Island chronosequence with increasing age and a shift towards more recalcitrant forms of organic P, consistent with the Walker and Syers (1976) model of long-term soil P dynamics (Nelson et al. 2020). Despite these trends, evidence for P limitation to tree growth in the later phases of the chronosequence is mixed. Although N:P ratios in tree foliage generally increased over time in this study, the values are not extreme in relation to the ranges observed elsewhere for other types of forest vegetation (Güsewell 2004). However, it is apparent that ecosystem retrogression is occurring on the older sites of the Calvert Island chronosequence, which may be caused by some combination of reduced P supply and soil physical changes, such as impedance of root penetration and water movement resulting from cemented horizons forming within the rooting zone.

Retrogression is most frequently associated with a depletion-driven system where P within the soil has been utilized and lost with increasing age, causing a reduction in primary productivity as illustrated by the Walker and Syers (1976) model (Wardle et al. 2004). Vitousek et al. (2010) further explained mechanisms that may influence the path of retrogression, such as soil barriers, low P parent material, transactional limitations due to difficulties releasing P from parent material, and anthropogenic causes. Two retrogressive chronosequences, Waitutu, NZ and Glacier Bay, Alaska, had severe alterations to soil drainage associated with a shift in plant communities as well as P limitations (Wardle et al. 2004). Gaxiola et al. (2010) found higher water table height to be significantly correlated to BA declines on Waitutu. The Mendocino, California, chronosequence is another well-known case study where iron pans, formed on older sites, may contribute to ecosystem retrogression (Jenny et al. 1969). The Haast chronosequence had placic horizon formation in <4000 a, which is thought to have ecological significance as a driver of retrogression (Turner et al. 2012).

The Glacier Bay chronosequence is very similar to the Calvert Island chronosequence because they are both within the coastal temperate rainforest and both exhibit retrogression after ∼11 000 a (Wardle et al. 2004). Similar plant communities exist at the Calvert Island chronosequence after 7236 ± 546 a and the Glacier Bay chronosequence after 11 000 a, with dominant species including crowberry (Empetrum nigrum L.), Labrador tea, sphagnum moss, mountain hemlock, and shore pine (Wardle et al. 2004). Noble et al. (1984) concluded that podzolization raised the water table in Glacier Bay, which was further accelerated by the presence of sphagnum moss.

The Calvert Island chronosequence documents the long-term trends in BA and changes in plant communities that accompany ageing aeolian soils on the coast of BC. This information is useful for understanding the potential mechanisms of reduced tree growth in low-productivity forests on the coast. The knowledge gained from this study can be used to further inform the mechanisms of ecosystem and soil development on the Cox Bay and Naikoon chronosequences. Lastly, this study can be added to the global repository of documented chronosequences experiencing retrogression, to further the understanding of this concept.