5.a. Effects of post-emplacement alteration on chemical compositions of kimberlites

Alterations in kimberlites commonly include serpentinization, carbonatization, silicification, chloritization and pyritization, which can significantly modify rock compositions (Stripp et al., Reference Stripp, Field, Schumacher, Sparks and Cressey2006; Vasilenko et al., Reference Vasilenko, Kuznetsova, Minin and Tolstov2012; Mitchell, Reference Mitchell2013; Afanasyev et al., Reference Afanasyev, Melnik, Porritt, Schumacher and Sparks2014). For instance, the serpentinization reaction [3Mg₂SiO₄ (olivine) + SiO₂ (fluid) + 4H₂O = 2Mg₃Si₂O₅(OH)₄ (serpentine)] introduces silica and water into the rocks, resulting in an increased Si/Mg ratio (Sparks et al., Reference Sparks, Brooker, Field, Kavanagh, Schumacher, Walter and White2009; Zhang et al., Reference Zhang, Zhou, Sun and Zhou2010). Silicification and carbonatization typically add Si and Ca to the rocks, respectively, leading to elevated Si/Mg ratios and reduced MgO/CaO ratios (Tompkins et al., Reference Tompkins, Meyer, Han, Hu, Armstrong, Tayer, Gurney, Gurney, Pascoe and Richardson1999; Vasilenko et al., Reference Vasilenko, Kuznetsova, Minin and Tolstov2012). Pyritization and serpentinization can decouple Ni and Co contents in the rocks, causing contrasting variations in the Ni/Co ratio (Cui et al., Reference Cui, Su, Wang and Yuan2024). In many cases, multiple types of alteration can be observed within a single kimberlite occurrence, as evidenced by the compositions of altered kimberlite samples from Mengyin. The Si/Mg, SiO₂/Al₂O₃, Ni/Co and TFe₂O₃/MgO ratios in these altered kimberlites exceed the restricted ranges found in pristine kimberlite samples (Table 1). These element ratios exhibit covariations in the altered kimberlites (Fig. 2a, b), while in pristine kimberlite samples, they remain relatively constant despite varying K₂O contents.

Potassium is a fluid-mobile element, and its isotopes can be sensitive to weathering processes and hydrothermal fluid activities (e.g. Santiago Ramos et al., Reference Santiago Ramos, Coogan, Murphy and Higgins2020). During the chemical weathering of igneous rocks, ⁴¹K is preferentially partitioned into fluids relative to ³⁹K, enriching the fluids in ⁴¹K and the solid residue in ³⁹K (Chen et al., Reference Chen, Liu and Wang2020; Teng et al., Reference Teng, Hu, Ma, Wei and Rudnick2020; Liu et al., Reference Liu, Wang, Sun, Xiao, Xue and Tuller-Ross2020). Similarly, hydrothermal alteration can lead to K isotope fractionation of up to 1.4 ‰ (Parendo et al., Reference Parendo, Jacobsen and Wang2017; Li et al., Reference Li, Wang, Huang, Wang and Wu2019; Li et al., Reference Li, Coogan, Wang, Takahashi, Shakouri, Hu and Liu2024). In the case of the altered kimberlites from Mengyin, the overall low δ⁴¹K values (except for sample 22CM04 with δ⁴¹K = −0.114‰) relative to those of the pristine kimberlite samples are consistent with the behaviour of K isotopes during weathering and alteration processes, as anticipated from theoretical models and principal investigations. The lack of correlation between δ⁴¹K and MgO/CaO or chemical index of alteration (CIA) (Fig. 2c, d) further confirms that these altered kimberlites underwent multiple alteration processes. Conversely, the δ⁴¹K values of the Mengyin pristine kimberlite samples do not show covariations with these geochemical proxies of alteration (Fig. 2c, d), indicating that their K isotope compositions retain their primary features. In addition, negative correlations between δ⁴¹K and K₂O and Rb in the altered samples (Fig. 3a, b) suggest the removal of fluid-mobile elements K and Rb during alteration.

Figure 3.

Bivariate plots of δ⁴¹K vs. (a) K₂O and (b) Rb for Mengyin kimberlites. Panels c and d are magnified version of panels a and b, respectively. Bulk silicate Earth value (−0.42 ± 0.07 ‰) is from Hu et al. (Reference Hu, Teng, Helz and Chauvel2021a). (e) Modelling of K isotopic variations during magmatic differentiation of Mengyin kimberlite magma. Solid orange lines represent calculated K isotopic compositions of residual melts during phlogopite fractional crystallization by assuming a Rayleigh fractionation process. Dashed blue lines represent calculated mixing lines between the residual melt and phlogopite phenocrysts. The δ⁴¹K values of primary melt and phlogopite are assumed as − 0.458 ‰ (sample 22CM18 with the lowest δ⁴¹K value and K₂O content of 0.17 wt.%; Table 1) and − 0.576 ‰ (average K isotopic compositions of phlogopite separates from basaltic lavas with K₂O content of 8.72 wt.%; Su et al., Reference Su, Pan, Bai, Li, Cui and Pang2024), respectively, with phlogopite-melt fractionation factors (Δδ⁴¹K_{phlogopite-melt} = δ⁴¹K_phlogopite − δ⁴¹K_melt) of − 0.175 ‰. The orange stars represent the increased K₂O contents in melts (0.34 wt.%, 0.51 wt.%, 0.68 wt.%, 0.85 wt.%, 1.70 wt.%, 2.55 wt.%, 3.40 wt.% and 4.25 wt.%) caused by K-poorly mineral accumulations prior to phlogopite.

5.b. K isotope fractionation during magma differentiation of kimberlites

During the magma differentiation of kimberlites, minerals such as olivine, pyroxene and spinel crystallize at an earlier stage, followed by the crystallization of carbonate minerals and hydrous phases like phlogopite (Mitchell, Reference Mitchell2013; Giuliani et al., Reference Giuliani, Schmidt, Torsvik and Fedortchouk2023). In the Mengyin pristine kimberlite samples, K is primarily hosted by phlogopite, which has a high K₂O content of approximately 9 wt.%. The contrasting K₂O contents between phlogopite and bulk rocks (0.02–1.17 wt.%, Table 1) suggest that the crystallization of solely phlogopite from the magma would reduce the K₂O content of the evolved melt. However, the amount of phlogopite in the Mengyin kimberlites is lower than that of other kimberlites worldwide (Lu et al., Reference Lu, Wang, Chen and Zheng1998; Tompkins et al., Reference Tompkins, Meyer, Han, Hu, Armstrong, Tayer, Gurney, Gurney, Pascoe and Richardson1999; Kjarsgaard et al., Reference Kjarsgaard, Pearson, Tappe, Nowell and Dowall2009; Pearson et al., Reference Pearson, Woodhead and Janney2019). The crystallization of K-poor phases (e.g. olivine, garnet and spinel) increases the K₂O content of the residual melt. Consequently, K₂O tends to increase with the differentiation of kimberlite magmas (Zhang and Yang, Reference Zhang and Yang2007; Zhang et al., Reference Zhang, Zhou, Sun and Zhou2010). Rb, which behaves similarly to K, also shows covariation with K₂O contents. In addition, there is no increase in K or Rb with a decrease in Mg/Fe or MgO (not shown), which can be attributed to the abundance of olivine and the effects of phlogopite addition during magma ascent (Brett et al., Reference Brett, Russell and Moss2009; Arndt et al., Reference Arndt, Guitreau, Boullier, Le Roex, Tommasi, Cordier and Sobolev2010).

Phlogopite, due to its higher coordination numbers of K (7–11, Cibin et al., Reference Cibin, Mottana, Marcelli and Brigatti2005; Li et al., Reference Li, Wang, Huang, Wang and Wu2019) compared to silicate melts (5–7, Greaves, Reference Greaves1985), is expected to exhibit a lower δ⁴¹K value than the magma from which it crystallizes (Li et al., Reference Li, Wang, Huang, Wang and Wu2019). This expectation aligns with reported K isotope compositions in volcanic rocks (Δ⁴¹K_{phlogopite-silicate rock} = −0.502 to −0.109 ‰, Su et al., Reference Su, Pan, Bai, Li, Cui and Pang2024). The δ⁴¹K values of the Mengyin pristine kimberlite samples correlate with K₂O contents (correlation coefficient R ² = 0.66, Fig. 3a, b) and Rb contents (R ² = 0.70, Fig. 3c, d), suggesting that the fractional crystallization of phlogopite is a primary controller of K isotope fractionation in these kimberlites.

Quantitative modelling is conducted based on Rayleigh fractionation and mixing calculation for the kimberlites (Fig. 3e). The equation for isotopic fractionation in a Rayleigh fractionation process is:

$$[{\delta ^{{\rm{41}}}}{{\rm{K}}_{melt}} = \left( {{\delta ^{{\rm{41}}}}{{\rm{K}}_0} + 1000} \right){f^{\left( {\alpha - 1} \right)}} - 1000]$$

where δ ⁴¹ K ₀ , the initial K isotope composition of melts, is assumed as −0.458 ‰ (sample 22CM18 with the lowest δ⁴¹K value and K₂O content of 0.17 wt.%; Table 1), and the initial K₂O contents of melts is set as 0.17 wt.%. The fraction of K₂O remaining in the melt and other phases is given by f = (F × C _melt )/C ₀ , where C _melt and C ₀ represent the K₂O concentration in the remaining melts and the initial melts, and F is the fraction of melts remaining. The fractionation factor α is calculated by:

$$[{\Delta ^{{\rm{41}}}}{{\rm{K}}_{phl - melt}} = {\delta ^{{\rm{41}}}}{{\rm{K}}_{phl}} - {\delta ^{{\rm{41}}}}{{\rm{K}}_{melt}} \approx {10^{\rm{3}}}\ln {\alpha _{phl - melt}}]$$

where the phlogopite-melt fractionation factor (Δ ⁴¹ K _phl-melt = δ ⁴¹ K _phl -δ ⁴¹ K _melt ) is −0.175 ‰ in our model, calculated using δ⁴¹K values of phlogopite (−0.576 ‰, average K isotopic compositions of phlogopite separates from basaltic lavas with K₂O content of 8.72 wt.%; Su et al., Reference Su, Pan, Bai, Li, Cui and Pang2024) and melt (−0.458 ‰).

In the mixing model, the equation for mixing two end-members is:

$$[{C_A} = {\left( {{C_A}} \right)_{melt,0}} \times {F_{melt,0}} + {\left( {{C_A}} \right)_{phl}} \times {F_{phl}}]$$

where C _A is the fraction of K₂O from end member 1, end member 2, and the mixing phase, and F is the fraction in each member. The K isotope composition of the kimberlites can be calculated by:

$$[{\delta ^{{\rm{41}}}}{{\rm{K}}_{lava}} = {\delta ^{{\rm{41}}}}{{\rm{K}}_{residual{\rm{ }}melts,0}} \times {(C)_{residual{\rm{ }}melts,0}} \times {F_{residual{\rm{ }}melts,0}} + {\delta ^{{\rm{41}}}}{{\rm{K}}_{Phl,0}} \times {(C)_{Phl,0}} \times {F_{Phl,0}}]$$

where the δ ⁴¹ K _{residual melt, 0} and δ ⁴¹ K _Phl could identify with δ ⁴¹ K ₀ and δ ⁴¹ K _lava in the model for Rayleigh fractionation.

The modelling results demonstrate that the obtained K isotopic compositions of the kimberlites are a mixture between phlogopite and evolved melts with phlogopite fractionation. The elevated K₂O contents of the samples compared to the modelling results (Fig. 3e) are due to K elevation from the crystallization of K-free minerals, which is consistent with the mineral assemblage of the kimberlites.

5.c. K isotope features of kimberlite source and possible formation mechanism

Since the K isotope variation observed in the pristine kimberlite samples from Mengyin is attributed to magma differentiation (Fig. 3), the lowest δ⁴¹K value (−0.458 ‰) of sample 22CM18 can represent the K isotope composition of a relatively primary kimberlite melt, falling within the range of BSE (Hu et al., Reference Hu, Teng, Helz and Chauvel2021a) (Fig. 3c, d). In contrast, mantle xenoliths from the continental lithospheric mantle (non-subduction zone) exhibit overall low δ⁴¹K values, ranging from −2.15 to −0.37 ‰ and low K₂O contents (< 0.1 wt.%) (Ionov and Wang, Reference Ionov and Wang2021). Among these mantle xenoliths, some highly-metasomatized peridotites align well along the varying trends of the Mengyin kimberlites (Fig. 4a, b). These samples, characterized with higher K₂O and Rb contents and the presence of phlogopite, may represent the mantle source of kimberlite melts. The δ⁴¹K value of the kimberlite source can be estimated from the average compositions of these samples (δ⁴¹K = −0.414 ‰) (Fig. 4), which is indistinguishable from the pristine mantle (δ⁴¹K = −0.42 ± 0.17 ‰) and BSE (δ⁴¹K = −0.42 ± 0.07 ‰) (Hu et al., Reference Hu, Teng, Helz and Chauvel2021a).

Figure 4.

Correlation diagrams of (a) δ⁴¹K vs. (a) K₂O and (b) Rb for Mengyin pristine kimberlite samples (this study) and mantle peridotites (Ionov and Wang, Reference Ionov and Wang2021). Five highly-metasomatized samples (with high K and Rb contents) are plotted along the varying trends of the Mengyin kimberlites, and their average values (K₂O = 0.088 wt.%; Rb = 5.56 ppm; δ⁴¹K = − 0.414 ‰) are considered as source composition of the kimberlite melt.

The BSE-like K isotope composition of kimberlite source does not align with the previously proposed mixed source of a carbonated asthenosphere, lithospheric keel and a subduction-dehydrated oceanic slab located at the diamond-stable mantle level or deeper, as inferred from diamond-bearing mineralogy and Sr-Nd-Hf-C-O isotope compositions (Lu et al., Reference Lu, Wang, Chen and Zheng1998; Liu et al., Reference Liu, Zhang, Sun and Ye2004; Zhang and Yang, Reference Zhang and Yang2007; Zhang et al., Reference Zhang, Zhou, Sun and Zhou2010). This discrepancy may be related to varying metasomatic media at different depths in the mantle. In subduction zones, metasomatism in the mantle wedge mainly occurs shallower than 75 km in the spinel-facies environment. Hydrous melts/fluids released from subducting slabs in these conditions tend to be enriched in heavy K isotopes (e.g. Liu et al., Reference Liu, Wang, Sun, Xiao, Xue and Tuller-Ross2020, Reference Liu, Xue, Geldmacher, Hoernle, Wiechert, An, Gu, Sun, Tian, Li and Wang2024), resulting in higher δ⁴¹K values in both subduction zone peridotites (Wang and Ionov, Reference Wang and Ionov2023) and arc lavas (e.g. Parendo et al., Reference Parendo, Jacobsen, Kimura and Taylor2022; Pan et al., Reference Pan, Xiao, Su, Robinson, Li, Wang and Liu2024) (Fig. 5). As dehydration progresses, the residual slabs represented by eclogites become isotopically lighter (δ⁴¹K = −1.64 to −0.24 ‰; Liu et al., Reference Liu, Wang, Sun, Xiao, Xue and Tuller-Ross2020), which could contribute to lighter isotope compositions in the metasomatized mantle. This inference is consistent with the low δ⁴¹K values observed in non-subduction zone mantle peridotites, which range from −2.15 to −0.27 ‰ (Ionov and Wang, Reference Ionov and Wang2021). Notably, these mantle peridotites are derived from the lithospheric mantle at depths from 60 to <150 km (Ionov and Wang, Reference Ionov and Wang2021). The K isotope features at such depths are likely inherited by intra-continental alkali basaltic lavas (−1.330 to 0.126 ‰, Sun et al., Reference Sun, Teng, Hu, Chen and Pang2020; Su et al., Reference Su, Bai, Tang, Xiao, Li, Zhao and Moynier2025; Fig. 5), where heavy K isotope compositions arise from the fractionation of isotopically light K-rich minerals during magma differentiation (Su et al., Reference Su, Bai, Tang, Xiao, Li, Zhao and Moynier2025).

Figure 5.

K isotope compositions of kimberlites in this study and comparisons with data of various rocks in literature (Tuller-Ross et al., Reference Tuller-Ross, Marty, Chen, Kelley, Lee and Wang2019a, b; Hu et al., Reference Hu, Teng, Plank and Chauvel2020, Reference Hu, Teng, Helz and Chauvel2021a, b; Huang et al., Reference Huang, Teng, Rudnick, Chen, Hu, Liu and Wu2020; Liu et al., Reference Liu, Wang, Sun, Xiao, Xue and Tuller-Ross2020, Reference Liu, Xue, Wang, Sun and Wang2021; Santiago Ramos et al., Reference Santiago Ramos, Coogan, Murphy and Higgins2020; Sun et al., Reference Sun, Teng, Hu, Chen and Pang2020; Ionov and Wang, Reference Ionov and Wang2021; Wang and Ionov, Reference Wang and Ionov2023; Parendo et al., Reference Parendo, Jacobsen, Kimura and Taylor2022; Pan et al., Reference Pan, Xiao, Su, Robinson, Li, Wang and Liu2024; Su et al., Reference Su, Bai, Tang, Xiao, Li, Zhao and Moynier2025).

In comparison to MORBs, intra-continental basaltic lavas and arc lavas, both oceanic island basalts and kimberlites originate from the deep asthenospheric mantle (> 150 km), with the involvement of recycled materials, and exhibit relatively narrow δ⁴¹K ranges (Fig. 5). The uniformity of K isotopes in these two rock types, originating from similar mantle depths but beneath different settings (ocean vs. craton), suggests a homogeneous K isotope composition within the deep mantle. This may result from efficient mixing and homogenization processes, such as mantle convection. On one hand, K may readily achieve homogeneity due to its high mobility relative to other elements. On the other hand, K in subducted slabs might become exhausted after a long subduction journey, leading to dilution of light K isotope features, which occurs more rapidly than in the metasomatized shallow mantle.

5.d. Implication for the destruction of North China Craton

Geophysical and geochemical studies have extensively documented that the lithospheric thickness in the eastern North China Craton has decreased from ∼200 km during the Palaeozoic to the present 60–80 km (Menzies et al., Reference Menzies, Fan and Zhang1993; Zhu et al., Reference Zhu, Chen, Wu and Liu2011). This lithospheric destruction has been attributed to the circular subduction of the Palaeo-Tethyan, Palaeo-Asian and Pacific oceans since the Mesozoic (Zhu, Reference Zhu2023), with a peak destruction age identified at ∼125 Ma (Zhu et al., Reference Zhu, Chen, Wu and Liu2011). These events are well-constrained by compositional variations observed in igneous rocks within the North China Craton (Zhang et al., Reference Zhang, Zhu, Santosh, Ying, Su and Hu2013). Non-traditional stable isotopes, such as those of Li, Fe, Mg and Ca, have emerged as powerful tools for understanding lithospheric processes in this region (e.g. Tang et al., Reference Tang, Zhang, Deloule, Su, Ying, Xiao and Hu2012; Su et al., Reference Su, Hu, Teng, Xiao, Zhou, Sun, Zhou and Chang2017). These well-documented processes provide an excellent opportunity to evaluate the application of K isotopes in tracing secular geological events.

Recent studies have reported K isotope data for Mesozoic to Cenozoic basaltic lavas in the North China Craton (Su et al., Reference Su, Bai, Tang, Xiao, Li, Zhao and Moynier2025). These data, along with findings from this study, are illustrated in Fig. 6. There is a notable increase in δ⁴¹K values from Palaeozoic kimberlites to Mesozoic basalts (up to 0.126 ‰). The elevated δ⁴¹K values in the Mesozoic basalts overlap with the ranges observed in igneous rocks formed during initial subduction and typical arcs (Parendo et al., Reference Parendo, Jacobsen, Kimura and Taylor2022; Pan et al., Reference Pan, Xiao, Su, Robinson, Li, Wang and Liu2024; Rodney et al., Reference Rodney, Tacail, Lewis, Andersen and Elliott2024; Fig. 5), indicating a significant addition of isotopically heavy melts/fluids from the subduction zone to the magma sources. Since 125 Ma, the δ⁴¹K values have decreased with age, down to −0.926 ‰ in Cenozoic basalts (Fig. 6). This decline is likely due to the incorporation of melts from dehydrated (eclogitized) slabs, as these Cenozoic basalts were generated in a big mantle wedge setting (Su et al., Reference Su, Hu, Teng, Xiao, Zhou, Sun, Zhou and Chang2017; Zhu, Reference Zhu2023). This temporal variation in δ⁴¹K values of mantle-derived magmas correlates with the timing of lithospheric destruction in the North China Craton. Consequently, K isotope systematics can be utilized to elucidate the influence of subduction, mantle dynamics and the complexities of the region’s geological history.

Figure 6.

Variation of K isotope compositions of kimberlites (this study) and basaltic lavas (Su et al., Reference Su, Bai, Tang, Xiao, Li, Zhao and Moynier2025) in the North China Craton through geological time.