Rock-magnetic properties

The low frequency initial magnetic susceptibility of the Cava Danesi Loess section varies between ~150 and ~1500×10^-6 SI units with generally higher values in the Mn-Fe-enriched lower parts of units PL1–PL4 (Fig. 3b). The mean susceptibility of the underlying fluvial/alluvial silts varies between ~3×10^-6 SI at the Cava Danesi Fluvial section (unit PL5) and ~900×10^-6 SI at the Cascina Braga section. Rock-magnetic experiments reveal the occurrence of variable mixtures of magnetite and hematite in the Cava Danesi Loess section and a dominant hematite signal associated with magnetite/maghemite in the fluvial/alluvial silts of the underlying sections. Thermal demagnetization of three component IRM of samples 10 and 84 from the Cava Danesi Loess section (Fig. 4; stratigraphic position of samples in Fig. 3a) shows a signal carried by the 0.12 T curves with a maximum unblocking temperature of ~575°C interpreted as due to the presence of magnetite. The 1.5 T and 0.4 T curves are instead characterized by maximum unblocking temperatures up to ~680°C, signaling the presence of hematite. The 1.5 T curve of sample 10 also shows a drastic drop at ~100°C, which is interpreted as goethite. Backfield IRM acquisition experiments on samples 10 and 84 confirm the occurrence of two magnetic phases with contrasting coercivities compatible with magnetite and hematite (Fig. 4, right panels) and characterized by median destructive fields (B1/2) of 10–50 mT and ~1000 mT calculated according to the Gaussian analysis of Kruiver et al. (Reference Kruiver, Dekkers and Heslop2001). Hysteresis loops of samples 10 and 84 are wasp-waisted with values of J_r/J_s of ~0.10–0.14 and of B_r/B_c of ~4.5–6.8 that are plotted on a modified Day diagram (Dunlop, Reference Dunlop2002) (Fig. 5). Similar hysteresis ratio values characterize samples 1, 2, 6, and 15 from the Cava Danesi Loess section. Low-resolution FORC diagrams of samples 10 and 84 (Fig. 5) show asymmetric peaks centered at B_u ≈ 0 and extending to B_c ≈ 0.02 T coexisting with higher coercivity tails, which suggests a mixture of single domain (SD) magnetite and high coercivity hematite/goethite. Divergence from the central ridge could reflect superparamagnetic contributions. A second cluster of samples from the Cava Danesi Loess section displays lower J_r/J_s values on the Day diagram (Fig. 5, samples 23, 33, 49, 65, 87). Sample 23 has a wasp-waisted hysteresis with a FORC slightly more divergent along the vertical B_u axis and with a less developed high coercivity tail along the central ridge, interpreted as signaling the dominance of coarser grained magnetite.

Figure 4. Thermal decay of a three component IRM acquired in fields of 1.5 T, 0.4 T, and 0.12 T, and isothermal remanent magnetization (IRM) backfield acquisition curves, of representative samples from the Cava Danesi Loess section (10 and 84) and Cascina Braga fluvial sediments (CB7 and CB20). Unblocking temperatures and IRM coercivities are consistent with the occurrence of variable mixtures of essentially magnetite and hematite, as testified also by the wasp-waisted shapes of the hysteresis loops obtained on the same samples (Fig. 5).

Figure 5. Hysteresis loops, corrected for paramagnetic components, and FORC diagrams of selected samples from the Cava Danesi Loess section (10, 23, and 84) and the Cascina Braga fluvial sediments (CB7 and CB20). The central-right panel represents a modified Day plot (Dunlop, Reference Dunlop2002) of J_r/J_s versus B_r/B_c for 12 samples from the Cava Danesi Loess sequence (black dots) and the Cascina Braga fluvial sediments (black diamonds). The theoretical curves of Dunlop (Reference Dunlop2002) for single domain-10 nm superparamagnetic (SD-SP) magnetite mixtures, single domain-multidomain (SD2-MD2) magnetite mixtures, and multidomain (MD) magnetite are also reported for reference together with the magnetite-hematite (mh) mixing curve of Liu et al. (Reference Liu, Hirt, Schüler, Uebe, Zhu, Liu and Zhang2019) (in blue). See text for discussion.

Samples CB7 and CB20 from fluvial silts of the Cascina Braga section show a dominant hematite signal in which the 1.5 T and 0.4 T curves are characterized by maximum unblocking temperatures >600°C (Fig. 4). There are also inflections in the 0.12 T and 0.4 T curves between ~250°C and ~450°C tentatively interpreted as due to maghemite (CB7) and magnetite (CB20). This interpretation is confirmed by the backfield IRM acquisition curves that show an initial low coercivity component (magnetite/maghemite) followed by a higher coercivity component (hematite) (Fig. 4). Hysteresis loops of these samples are less wasp-waisted in shape. Sample CB7 displays J_r/J_s and B_r/B_c values close to values expected for pure hematite (mh 100% on the Day plot of Fig. 5; data from Liu et al., Reference Liu, Hirt, Schüler, Uebe, Zhu, Liu and Zhang2019) and a low-resolution FORC with an asymmetric central ridge elongated towards high coercivities that could be compatible with dominant hematite, coexisting with pronounced vertical divergence along the B_u axis that could be due to superparamagnetic contributions. Instead, sample CB20 shows lower J_r/J_s and higher B_r/B_c values, and a FORC central asymmetric swell restricted to low coercivities, more compatible with coarse-grained magnetite/maghemite, in substantial agreement with the IRM experiments.

Magnetostratigraphy

Thermal demagnetization analyses of the natural remanent magnetization show the presence of a viscous overprint component A of normal polarity, oriented northerly and down, which has been removed between room temperature and a maximum of ~250°C. The characteristic remanent magnetization (ChRM) component, interpreted as the primary magnetic signal, was detected in 139 samples up to ~580–675°C (Fig. 6; demagnetization data in Tab. S1), suggesting that both magnetite and hematite contribute to the ChRM, in agreement with the rock-magnetic experiments. The ChRM component directions are oriented with northerly declinations and downward inclinations, representing normal magnetic polarity, or southerly declinations and upward inclinations representing reverse polarity (Fig. 6). In general, ChRM component directions are well resolved in samples from the Cava Danesi Loess section, where they trend linearly to the origin of the demagnetization axes (8, 53, and 75; Fig. 6), whereas in the other fluvial-dominated sections they tend to be more scattered, sometimes forming clusters before final unblocking at high temperatures (e.g., F1 from Cava Danesi Fluvial; MNTC05 from Top Colle; MNS04 from Salita; CSA01, CSB05, CSC02 from Cascina Santus; and CB23, CB27 and CB3 from Cascina Braga; Fig. 6). Standard Fisher statistics yielded an overall mean ChRM component direction for the Cava Danesi Loess section at Dec = 1.3°E, Inc = 51.5° (k = 25, α₉₅ = 3.1°, n = 88) (Fig. 7a, upper stereonet) and for the fluvial (pre-loess) sequence (Cava Danesi Fluvial, Top Colle, Salita, Cascina Santus, and Cascina Braga) at Dec = 5.9°E, Inc = 49.7° (k = 13, α₉₅ = 5.7°, n = 51) (Fig. 7b). No tectonic correction was applied because bedding attitudes in all sampled sections appear close to horizontal.

Figure 6. Vector end-point demagnetization diagrams of representative samples from Monte Netto indicating characteristic remanent magnetization (ChRM) component directions of normal polarity, with northernly declinations and positive (downward) inclinations, or reverse polarity, with southernly declinations and negative (upward) inclinations. Closed symbols are projections onto the horizontal plane and open symbols are projections onto the vertical plane in geographic coordinates. No tilt correction has been applied because bedding is sub-horizontal. Demagnetization steps are expressed in °C.

Figure 7. Equal-area projections of the characteristic remanent magnetization (ChRM) component directions for (a) all samples from the Cava Danesi Loess sequence as well as a selection of 20 ChRM directions for the base and top of the same loess sequence showing differential tectonic rotations; and (b) samples from the underlying fluvial/alluvial (pre-loess) sequence from sections Cava Danesi Fluvial, Top Colle, Salita, Cascina Santus, and Cascina Braga. Closed symbols are projections onto the lower hemisphere while open symbols are projections onto the upper hemisphere. The stars represent the Fisher mean directions and associated cones of 95% confidence.

The normal polarity ChRM record of the Cava Danesi Loess section shows high-frequency variability in declination and inclination (Fig. 3c, d) that is relatively well defined, with maximum angular deviation (MAD) errors generally <10° (Fig. 3e). Notably, the declination values oscillate along a long-term trend of 0.091°/cm with easterly declinations in the lower part of the section, northerly declinations in the mid part, and westerly declinations in the upper part (red line with 95% error envelope in Fig. 3c). The inclination values show instead a more modest long-term increase trend of 0.025°/cm moving up-section (Fig. 3d). We interpret these trends as mainly due to tectonic deformation (declination trend) and compaction (inclination trend).

The ChRM component directions have been used to calculate virtual geomagnetic pole (VGP) latitudes (Tab. S2). These results have been used to determine the position in the overall Monte Netto sequence of the Brunhes-Matuyama boundary and the top of the Jaramillo (Fig. 2). These data were used in conjunction with OSL dates and PSV analysis for sedimentation age modeling and assessments of rates of tectonic uplift and deformation of the Monte Netto structure.

Long-term uplift of the Monte Netto structure

The long-term deformation history of the Monte Netto structure due to activity of the Capriano del Colle Backthrust can be investigated comparing the elevations of levels that registered the Brunhes-Matuyama boundary and the top of the Jaramillo in sections from the study area and in two drill cores from the surrounding Po Plain (RL2 Pianengo and RL1 Ghedi; Muttoni et al., Reference Muttoni, Carcano, Garzanti, Ghielmi, Piccin, Pini, Rogledi and Sciunnach2003; Scardia et al., Reference Scardia, Muttoni and Sciunnach2006) that are not associated with tectonic deformation (Fig. 11; for locations of cores, see Fig. 1a). Vertical displacement of the Brunhes-Matuyama boundary between Monte Netto and RL1 is 68.5 ± 4.8 m, and between Monte Netto and RL2 is 78 ± 10.3 m. Similarly, the displacement of the top Jaramillo at Monte Netto is 130.9 ± 2.6 m relative to RL1 and 129.4 ± 2.1 m relative to RL2 (Fig. 11). Neglecting the relatively minor differences, which could be due to local and undetected variations in sediment accumulation rates, such displacements indicate an average rate of vertical tectonic uplift of the Monte Netto hillock relative to the surrounding plain of 11.3 ± 1.5 cm/ka since the Brunhes-Matuyama boundary (773 ka; terminus post quem). This long-term tectonic uplift is related to activity of the buried Capriano del Colle Backthrust, which has been observed in seismic profiles at a depth of 2–3 km (Livio et al., Reference Livio, Berlusconi, Michetti, Sileo, Zerboni, Trombino and Cremaschi2009) under the Monte Netto uplifted stratigraphic sequence (CCB in Fig. 11, depth not to scale; see also Livio et al., Reference Livio, Berlusconi, Michetti, Sileo, Zerboni, Trombino and Cremaschi2009, fig. 4).

Figure 11. Magnetostratigraphic correlations between Monte Netto and nearby drill cores RL2 Pianengo and RL1 Ghedi (Muttoni et al., Reference Muttoni, Carcano, Garzanti, Ghielmi, Piccin, Pini, Rogledi and Sciunnach2003; Scardia et al., Reference Scardia, Muttoni and Sciunnach2006) plotted in a common topographic-altimetric reference frame. The Monte Netto structure appears to have undergone a tectonic uplift relative to RL1 and RL2 of 11.3 ± 1.5 cm/ka since 773 ka (terminus post quem) due to the activity of the buried Capriano del Colle Backthrust (CCB), located at a depth of 2–3 km (not to scale in figure) under the uplifted Monte Netto stratigraphy. In addition, core RL1 was previously shown to be characterized by a regional isostatic uplift of ~8 cm/ka relative to sea level, which is similar to other cores from the Po Plain (Scardia et al., Reference Scardia, Muttoni and Sciunnach2006, Reference Scardia, De Franco, Muttoni, Rogledi, Caielli, Carcano, Sciunnach and Piccin2012). The total uplift rate of the Monte Netto structure relative to sea level is therefore of ~19.3 cm/ka.

This rate of local tectonic uplift is superposed on a rate of regional uplift of the northern Po Plain relative to sea-level as observed in several Pleistocene drill cores (RL1–RL7, Fig. 1a). Scardia et al. (Reference Scardia, Muttoni and Sciunnach2006, Reference Scardia, De Franco, Muttoni, Rogledi, Caielli, Carcano, Sciunnach and Piccin2012) used magnetochronology from these cores to assess the age of transitional marine (beach, shoreface) facies marking sea level, which were found to punctuate the stratigraphic record repeatedly between 1240 ka (MIS 37) and 850 ka (MIS 21). After applying a simple Airy isostatic correction to account for sediment loading, Scardia et al. (Reference Scardia, Muttoni and Sciunnach2006, Reference Scardia, De Franco, Muttoni, Rogledi, Caielli, Carcano, Sciunnach and Piccin2012) found that in all analyzed cores (except for core RL2 Pianengo, see below), these transitional facies presently lie ~70–120 m above maximum Pleistocene sea levels of corresponding ages, implying a generalized phase of uplift of the northern Po Plain relative to sea level that occurred since deposition of the youngest displaced transitional deposits of late Early Pleistocene age (Scardia et al., Reference Scardia, Muttoni and Sciunnach2006, Reference Scardia, De Franco, Muttoni, Rogledi, Caielli, Carcano, Sciunnach and Piccin2012). In core RL1 Ghedi, this uplift relative to sea level was estimated at ~8 cm/ka since ca. 870 ka, while core RL2 Pianengo required no uplift correction to restore the transitional facies on the reference sea level curve, possibly because of a preceding phase of local subsidence that resulted in a final null net difference (Scardia et al., Reference Scardia, Muttoni and Sciunnach2006, Reference Scardia, De Franco, Muttoni, Rogledi, Caielli, Carcano, Sciunnach and Piccin2012, for additional information). In any case, assuming coherence between Monte Netto and core RL1 Ghedi, the total uplift rate of Monte Netto relative to sea level since the late Early Pleistocene (sum of local tectonic uplift plus regional isostatic uplift) is ~19.3 cm/ka (Fig. 11), which is in substantial agreement with previous assessments (Livio et al., Reference Livio, Berlusconi, Michetti, Sileo, Zerboni, Trombino and Cremaschi2009).

Rotational deformation of the loess sequence

A close inspection of the ChRM component directions reveals that the Cava Danesi Loess section was affected by a recent phase of complex rotational deformation that presumably was related to surface faulting and folding. Recall that the undetrended (i.e., as measured) ChRM declination record of the Cava Danesi Loess section oscillates around a long-term trend that is displaced relative to the true north direction (Fig. 3c, red line), with ChRM directions pointing on average 13.2°E (=13.2° east of north) at the base of the sequence and 348°E at the top. A statistically significant difference of ~25 ± 11° is revealed by Fisher statistics applied to 20 ChRM directions from the lowermost 60 cm of the loess sequence relative to 20 directions from the uppermost 60 cm of the same sequence (Fig. 7a, lower stereonet). Considering that both these 60 cm-thick subsections should cover ~10 ka of sedimentation according to the age model shown in Figure 10, the observed difference in mean declination cannot be explained as due to PSV alone, thus leaving tectonic rotation as the only plausible contributing factor to explain the observed declination trend. Instead, the Cava Danesi Fluvial section, stratigraphically below the loess, is characterized by six north-pointing ChRM declinations (Fig. 3c, d). No statistically significant rotation was observed in the other pre-loess fluvial sections (Top Colle, Salita, Cascina Santus, Cascina Braga; Fig. 7b). Recall also that the Cava Danesi Loess section is located immediately to the south of a fault-propagation fold (Figs. 12A, S1) (Livio et al., Reference Livio, Berlusconi, Zerboni, Trombino, Sileo, Michetti, Rodnight and Spötl2014, Reference Livio, Ferrario, Frigerio, Zerboni and Michetti2020), where some deformation is expected during fold growth. Conversely, the (non-rotated) Cava Danesi Fluvial section is located in the backlimb of the same fault system, where simple translation is expected (Fig. S1).

We applied the age model described above to transform the undetrended ChRM declination values of the Cava Danesi Loess section (Fig. 3c) from depth (cm) to time (ka) coordinates, and we attempted to explain this dated record using a simple two-stage rotational deformation model. According to our model, the loess sequence experienced an initial long-term phase of syn-depositional vertical-axis clockwise (cw) tectonic rotation at rates of 0.43 ± 2.5°/ka (error bound on rotation rate derived from error bound on declination trend in Fig. 3c) from ca. 72 ka (age of the oldest ChRM directions) up to ≤11 ka (age of the youngest ChRM directions). Consequently, the oldest ChRM directions should have been affected by maximum eastward displacements and the youngest directions should be non-rotated (Fig. 12b). We cannot assess precisely when this rotation ended in the 11–0 ka interval (Fig. 12b). This rotational phase appears progressive (syn-depositional), at least within the observed time scale, and is mainly due to a diverse tendency of the fault to propagate upwards, as also attested in Livio et al. (Reference Livio, Ferrario, Frigerio, Zerboni and Michetti2020). According to observations on two profiles of the same fault-propagation fold exposed along the eastern and western walls of the Monte Netto mound (Fig. 12a), the fault tip propagation was more inhibited in the east, resulting in a more pronounced folding and tilting of the front-limb sector that, as a consequence, generated the observed progressive clockwise rotation of the Cava Danesi Loess section.

Figure 12. Tectonic model to explain the rotated ChRM declination record of the Cava Danesi Loess section. (a) Aerial view of the outcrop area and geological profiles along wall exposures showing the loess and fluvial/alluvial sediments affected by faulting, as described in detail in Livio et al. (Reference Livio, Berlusconi, Zerboni, Trombino, Sileo, Michetti, Rodnight and Spötl2014, Reference Livio, Ferrario, Frigerio, Zerboni and Michetti2020). (b) Modeling of Phase 1 of the deformation history of the Cava Danesi Loess section. The ChRM declination record from Figure 3c is transformed from depth to time according to the age model shown in Figure 10 and translated in order to attain 0° mean declination at either t = 11 ka (end of observed record; yellow line) or t = 0 (red line). This implies 0.43 ± 2.5°/ka of syndepositional clockwise rotation of the sequence ending anytime between 11 ka and modern times (gray area with question mark). The block diagram in (b) shows the fault kinematics considered responsible for the observed rotation. (c) Modeling of Phase 2 of the deformation history of the Cava Danesi Loess section. Sometime after 11 ka, the ChRM declination record experienced a rigid-body counterclockwise (ccw) rotation of 15–19° to attain the present-day geometry (green line, same as in Fig. 2c). Also depicted is a block diagram showing the fault kinematics during Phase 2. See text for discussion.

Subsequently, we have recorded a second phase of deformation resulting in a single pulse of rigid-body rotation of the entire Cava Danesi Loess section around a vertical axis to yield the actual configuration (Fig. 12c). This latter deformation phase could be associated with the surface emergence of the fault, to the west, while in the eastern sector fault tip propagation was still inhibited (Fig. 12c). The lack of distributed deformation from emergence of the fault onwards resulted in a more pronounced front advancement to the west, and, in turn, an anticlockwise cumulative rotation of 15–19° (Fig. 12c). According to the available record, this phase of rotation occurred after 11 ka. It is noteworthy that a similar age for the fault emergence was supposed by Livio et al. (Reference Livio, Ferrario, Frigerio, Zerboni and Michetti2020) based on the age constraints available at that time.

Alternative mechanisms to explain the Cava Danesi Loess declination record involving deeper deformation and rotation (e.g., due to the deep Capriano del Colle Backthrust) are excluded, so far, by considering that the Cava Danesi Fluvial section, as well as the other fluvial sections from the Monte Netto stratigraphy (Top Colle, Salita, Cascina Braga, Cascina Santus), located outside the expected deformation zone of the shallow fault-propagation fold, appear non-rotated.