The subcontinental lithospheric mantle (SCLM) is generally metasomatized by intra-plate or arc magmatism, making them distinct geochemical reservoirs from mid-ocean ridge basalts (MORBs) and ocean island basalt (OIB) sources. Higher ³He/²²Ne is observed in mantle-derived xenoliths from the SCLM in Patagonia, South America (Jalowitzki et al., EPSL 2016) compared to MORBs and OIBs, which reflect the composition of the convecting mantle and plume source, respectively. Based on this ³He/²²Ne difference, SCLM is expected to be a distinct geochemical reservoir that has evolved differently from the convecting mantle and plume sources in terms of noble gases (Dygert et al., EPSL 2018). The average ³He/⁴He of SCLM-derived peridotite samples is about 6 Ra (Gautheron & Moreira, EPSL 2002), where 1 Ra = 1.4 x 10^-6 represents atmospheric ³He/⁴He, suggesting that the contribution of radiogenic ⁴He derived from the decay of U and Th to SCLM is more significant than that to the convecting mantle with ³He/⁴He of ca 8 Ra. In addition, Ne isotopic compositions of the SCLM samples from Patagonia in South America have been confirmed to have a more significant contribution of nucleogenic ²¹Ne from ²⁴Mg[n,α]²¹Ne and ¹⁸O[α,n]²¹Ne reactions compared to MORBs. If the SCLM is a globally homogeneous reservoir, these features are expected to be observed in SCLMs in other regions. Therefore we analyzed noble gases and halogens in SCLM-derived samples from the Lunar Crater volcanic field, Toroweap flow, the Mendocino Mountains, and Mount Emma in southwestern North America, and Beni Bousera peridotite body in northwestern Africa.

The samples from southwestern North America have ³He/⁴He that fall within the range of the convecting mantle. On the other hand, the ³He/⁴He ratios of the Beni Bousera peridotite samples are low, ranging from 0.3 Ra to 0.7 Ra. The Ne isotope ratios of the southwestern North America samples are also accounted for by mixing between air and convecting mantle endmembers. In contrast, those of the Beni Bousera peridotite samples suggest the addition of nucleogenic Ne to the atmospheric compositions. These results indicate that the SCLM is not a homogeneous geochemical reservoir in terms of noble gases.

The MORB-like He and Ne feature of the samples from southwestern North America differs from those of other SCLMs. This result suggests that the SCLMs beneath these regions were incorporated into the mantle convection by delamination, resulting in compositional overwriting with the convecting mantle component.

The contribution of nucleogenic ²¹Ne correlates with that of radiogenic ⁴He and is substantial in the Beni Bousera peridotite body samples. The sample was reported to have experienced deformation and dynamic recrystallization, which may have resulted in the loss of mantle-derived noble gases. Based on the U abundance obtained by heating analyses of the neutron-irradiated samples and that of total radiogenic ⁴He abundance determined by heating analyses of unirradiated samples, the time when the accumulation of radiogenic ⁴He began was estimated to be approximately 13-17 Ma. This is consistent with the exhumation age of the Beni Bousera peridotite body in the early Miocene (ca. 23-16 Ma).

In contrast to the noble gas features, the Br/Cl and I/Cl ratios of the samples from southwestern North America and northwest Africa share similar characteristics in which Br/Cl and I/Cl range 1.2-7.8 ×10^-3 mol/mol and 61-860 ×10^-6 mol/mol, respectively, while I/Br showed fewer variations (0.031-0.110 mol/mol). Both samples are from the back-arc regions of the subduction zones, and a similar feature was observed for mantle-derived xenoliths in Takashima, northwestern Kyushu, Japan, which is also in the back-arc region. Therefore, it is possible that this feature is common in the back-arc regions of subduction zones and may result from Cl depletion in the mantle wedge having higher I/Cl due to the addition of iodine-rich subducted halogen component.