Optically stimulated luminescence (OSL) dating

For optically stimulated luminescence (OSL) chronology, four sandy-to-silty samples (Fig. 2, Table 1) were dated by the Wadia Institute of Himalayan Geology, Dehradun (WIHG). The fundamental presumption behind OSL dating is that sand loses its stored luminescence when exposed to sunlight during erosion and transit, a process known as ‘zeroing.’ Due to radioactive exposure from ambient U, Th, K, and gamma radiation, the same sediment resumes accumulating luminescence after sedimentation and burial. The laboratory equivalent of the luminescence thus accumulated is called equivalent dose (ED). By dividing the ED by the dose rate, the age of the sediment can be determined. Due to turbulence, zeroing can be difficult in fluvially produced sediments, and fresh feldspar contamination can frequently obscure the OSL signal. These issues are resolved by 1) utilizing a minimum age model (MAM) to treat data with overdispersion (OD) of less than 20% and the mean ages for the data with a larger OD (Galbraith et al., Reference Galbraith, Roberts, Laslett, Yoshida and Olley1999), and 2) observing the infrared stimulated luminescence (IRSL) signal for feldspar, which should have fewer than 150 counts.

Figure 2. Age-depth model showing optically stimulated luminescence (OSL) dates and sedimentation rates (r) derived from the Pratappura section. Mod: modern; see Figure 1c for sample locations.

Table 1. Optically stimulated luminescence (OSL) chronology of Pratappura profile. Least represents the minimum age. The wide spread in the paleodose data suggests inhomogeneous bleaching of geological luminescence signal, which prompted us to use the least 20% of the paleodoses of final age calculation.

The samples were chemically treated using H₂O₂ and HCl in the laboratory to remove organic matter and carbonate coatings. Subsequently, the dried sediment was sieved to 125–150 μm. A density separation technique using sodium polytungstate (density = 2.59 gm/cc) was applied for quartz and feldspar separation. First, HF was used to remove the alpha-affected skin from the separated quartz grains, and then HCl was used to dissolve the fluoride crystals. The quartz grains were then mounted on 9.8 mm stainless steel discs after being washed, dried, and cleaned. For measuring the ED, a Riso TL/OSL-20 system equipped with arrays of blue LEDs and infrared LEDs as a source for stimulation at 125°C for 40 s was employed. For each sample, 35 aliquots were used. Photons were counted for paleodose estimation using a combination of Schott BG-39 and Hoya U-340 optical filters in front of an EMI 9235 QA photomultiplier tube. A 5-point single aliquot regeneration (SAR) technique was employed for the measurement, with a preheat of 220°C/10 s and a cut heat of 160°C (Murray and Wintle, Reference Murray and Wintle2000). IRSL measurements on natural samples were used to track feldspar contamination. Using photon counts from the shine-down curves of the initial 5 channels (1 channel = 0.16 s), the paleodose for 30–35 discs was determined. U, Th, and K concentrations were measured using X-ray fluorescence (XRF) and inductively coupled plasma mass spectrometry (ICP-MS) for dose rate calculations. These samples were considered to have a moisture content of 10 ± 5% and a cosmic dose rate of 150 ± 30 μGyr⁻¹ (Prescott and Stephan, Reference Prescott and Stephan1982).

Digital elevation model (DEM)

With a resolution of 90 m, a digital elevation model (DEM) was produced using data from the Shuttle Radar Topographic Mission (SRTM; https://srtm.csi.cgiar.org) as inputs for Spatial Analyst in ArcGIS 10.3 (Fig. 3). Based on symmetry, channels and stream lineaments were recovered from the DEM to create a drainage map. The ROSE diagram was prepared in RockWare 16 (Wells, 1999), a useful tool for visually representing two-dimensional orientation and other data (Potter and Pettijohn, Reference Potter and Pettijohn1963; Wells 1999; Sanderson and Peacock, Reference Sanderson and Peacock2020), and the azimuths were calculated for all the escarpments in the study area using ArcGIS 10.3. The azimuths of the channel and stream lineaments were also then calculated using ArcGIS 10.3 (ESRI, 2011). Using the Rose module in RockWare, the azimuths were then plotted as a rose diagram to organize the lineament association according to their direction of propagation. The resulting rose diagram shows how lineaments repeat at regular intervals (Moore et al., Reference Moore, Grayson and Ladson1991; Reddy, Reference Reddy1991).

Figure 3. Digital elevation model (DEM), subsurface lineament, escarpment, and rose diagram for the Pratappura profile area, showing the structurally controlled drainage pattern.

Textural (grain-size) and loss-on-ignition (LOI) analyses

For grain-size analysis, 35 sediment samples were chosen from the measured profile (Supplementary Table S1). Following the methods of Jackson (Reference Jackson1956) and Kunze (Reference Kunze and Black1965), 10 g of bulk, air-dried samples were treated with CH₃COONa, H₂O₂, NaHCO₃, and Na₂S₂O₄ to remove carbonate, organic carbon, salts, and iron-manganese oxide coatings on the sediment grains. A 53-μm sieve was used to separate the sand fraction from silt and clay. After that, distilled water was added to the silt and clay fraction and transferred into a 1-L cylinder to separate the silt and clay fraction by the pipette method (Tanner and Jackson, Reference Tanner and Jackson1948; Day, Reference Day and Black1965). A ternary diagram was then created that plotted the percentages of sand, silt, and clay in the samples.

A total of 104 sediment samples were evaluated for moisture, organic carbon (C_org), and inorganic carbon (CO₃⁻²) percentages. Five g of 75-μm powder samples were cooked in quartz crucibles at 110°C, 550°C, and 950°C, and weight loss was measured to quantify moisture, C_org, and CO₃⁻² (weight loss at 950°C is multiplied by a factor of 1.36 to covert weight loss from CO₂ to CO₃), in the samples, respectively (Dean, Reference Dean1974; Bengtsson and Enell, Reference Bengtsson, Enell and Berglund1986).

Magnetic susceptibility (χ_lf) analysis

Magnetic susceptibility (χ_lf) is a concentration-dependent parameter of ferrimagnetic and paramagnetic content in the sediment. The χ_lf is used as a proxy to infer climatic variations (Maher and Thompson, Reference Maher and Thompson1992; Evans and Heller, Reference Evans and Heller1994; Sangode and Mazari, Reference Sangode and Mazari2007; Phartiyal et al., Reference Phartiyal, Srivastava and Sharma2009). Higher values of χ_lf imply a close relationship between erosional processes and increasing concentration of detrital input from the catchment (Williamson et al., Reference Williamson, Jackson, Banerjee, Marvin, Merdaci, Thouveny, Decobert, Gibert-Massault, Massault, Mazaudier and Taieb1999). Samples were analyzed using low field mass-specific susceptibility (χ_lf). For these analyses, ~10-g samples were (Supplementary Table S2) was taken in non-magnetic sample holders and analyzed using a MS-2 Bartington susceptibility meter at WIHG, Dehradun.

Stable carbon isotope analysis

Stable carbon isotope analysis was performed on 48 sediment samples (Supplementary Table S3). Samples were air-dried, powdered, and then 1.5 g per sample was repeatedly treated with 5% HCl and heated on a water bath for 2 hours to dissolve the carbonates. Acid-treated samples were then rinsed in Milli-Q water and centrifuged at 3000 round per minute (rpm) to remove the acid and soluble salts. After complete neutralization, the samples were dried in a hot air oven at 50°C. The treated dry samples were then powdered, weighed, and properly packed into tin capsules. The samples were analyzed in a mass spectrometer (FLASH-EA 1112 Series Thermo made) at the Indian Institute of Tropical Meteorology (IITM), Pune. Isotopic results are given using delta (δ) notation using the international standard Vienna PeeDee Belemnite (VPDB; Coplen, Reference Coplen1994). Measurement error was ± 0.1‰ based on repeated analysis of a laboratory standard.

Bulk and clay mineral X-ray diffraction (XRD) analyses

For bulk mineralogical studies, six samples were selected from the profile. The air-dried samples were crushed to 75 μm and analyzed using an XPERT-PRO diffractometer system with continuous scanning at 25°C (2θ of 4.0–79.9). For clay mineralogy, eight samples were selected from the profile. The clay fraction (<2 μm) was separated, and oriented slides were prepared using a standard smear technique (Tanner and Jackson, Reference Tanner and Jackson1948; Day, Reference Day and Black1965). The clay slides were analyzed (2θ of 4.0–40.0) using a XPERT-PRO diffractometer at WIHG. The identification of clay minerals was done by glycolation, then heating samples at 250°C and 300°C. Mineral identification was done using X'pert high score software (https://www.malvernpanalytical.com) and the ICDD pdf 4 mineral database (Gates-Rector and Blanton, Reference Gates-Rector and Blanton2019).

Geochemical analysis

For bulk geochemical analysis, 16 sediment samples were chosen from the entire profile (Table 2). The bulk samples were initially homogenized using the coning and quartering method, and ~25 g sample was crushed to 75 μm using a Retsch (PM 100 CM) disc mill. For major oxide analysis, 6 g of powdered sample and 4 g of boric acid were mixed, and pressed pellets were prepared for XRF analysis (Stork et al., Reference Stork, Smith and Gill1987; Saini et al., Reference Saini, Mukherjee, Rathi and Khanna2000; Khanna et al., Reference Khanna, Saini, Mukherjee and Purohit2009). The pellets were analyzed for major and minor oxides using a standard wavelength-dispersive X-ray fluorescence spectrometer (WD-XRF) technique on a sequential XRF spectrometer (Siemens SRS-30 0 0) at WIHG, Dehradun. Several international sediment sample standards (GXR-2, SO-1, GSS-1, SCO-1, SGR-1, MAG-1, and GSD-9) were used to check the precision and accuracy of the sample preparation and instrumental performance. The accuracy and the precision of measurement were better than 2–5% and <2%, respectively. For a few trace elements including rare earth element (REE) analysis, samples were digested in a mixture of super-pure acids (HF + HNO₃ + HClO₄) using the ‘B-solution’ method (Shapiro and Brannock, Reference Shapiro and Brannock1962) in Teflon™ crucibles. All samples were analyzed by ICP-MS (PerkinElmer, Elan-DRCe) at WIHG, Dehradun. Several USGS international (MAG-1, SGR-1, SCo-1) and in-house (WIHG, Dehradun) standards were used for instrument calibration. The precision for ICP-MS analyses obtained was ≤5%.

Table 2. Major, trace, and rare earth element (REE) compositions of samples from the Pratappura profile with calculated chemical index of alteration (CIA) and index of chemical variability (ICV) values; ppm: parts per million.

Chemical index of alteration (CIA) calculations were carried out by using the molar proportion of Al₂O₃, CaO*, Na₂O and K₂O. CaO* was taken in silicate form only (Nesbitt and Young, Reference Nesbitt and Young1989), and calculated by the method proposed by McLennan (Reference McLennan1993) because we had no direct method available to distinguish and quantify the amount of CaO belonging to the silicate and non-silicate fractions. The CIA was calculated as:

(Eq. 1)$${\rm CIA\ } = {\rm A}{\rm l}_2{\rm O}_3/( {{\rm A}{\rm l}_2{\rm O}_3 + {\rm CaO}\ast{ + } {\rm N}{\rm a}_2{\rm O} + {\rm K}_2{\rm O}} ) \ast 100$$

and in a generalized A (Al₂O₃)–CN (CaO* + Na₂O)–K (K₂O) triangular plot, the average upper continental crust (UCC) composition is ~50 (CIA = ~50).

The index of chemical variability (ICV) was also calculated to understand the index of recycling and compositional maturity in sediments (Cox et al. Reference Cox, Lowe and Cullers1995; Armstrong-Altrin, Reference Armstrong-Altrin2015), where

(Eq. 2)$$\eqalign{\rm ICV &= ( {{\rm F}{\rm e}_2{\rm O}_3 + {\rm K}_2{\rm O\ } + {\rm N}{\rm a}_2{\rm O\ } + {\rm CaO\ } + {\rm MgO\ }} \cr &+ {\rm MnO\ } + {\rm TiO_2} ) /{\rm A}{\rm l}_2{\rm O}_3}$$

and an ICV < 1 indicates sediment recycling and that the sediment is highly mature, whereas ICV > 1 shows a first cycle of sediment deposition, and that the sediment is immature in nature.

Phytolith studies

Phytoliths are microscopic opaline silica bodies present in almost all plants, and their major function is to provide mechanical support to the plant. In the grasses, phytoliths are very distinct and their morphology is easily distinguishable between summer and winter grasses. After the decay of plants, phytoliths remain in the soil and sediment as a relic of an earlier ecosystem (paleovegetation; Fredlund and Tieszen, Reference Fredlund and Tieszen1994).

For phytolith analysis, 5 g of sediment sample (Supplementary Table S4) was kept in 10% sodium hexametaphosphate (Calgon™ solution) overnight, and suspended clay was siphoned out. The samples were subsequently treated with 10% HCl and heated in a sand bath for 10–20 minutes for carbonate removal. The organic content was removed by heating 30% H₂O₂ in a sand bath for 20–30 minutes. The remaining residue was washed twice with distilled water. Phytolith extraction was done by adding the residue to a heavy liquid solution of cadmium iodide (CdI₂) and potassium iodide (KI) with a specific gravity of 2.3 that was centrifuged at 1000 rpm for 5 minutes. The lighter fraction containing phytoliths were then washed, dried, and weighed. Dried phytoliths were mounted on slides using Canada balsam. A few slides were also mounted in immersion oil to view 3-D images of phytoliths. The phytoliths were identified at 100× magnification using a Leitz LABORLUX-D light microscope and a minimum of 300 counts were taken and classified according to Twiss et al. (Reference Twiss, Suess and Smith1969) and Mulholland and Rapp (Reference Mulholland, Rapp, Mulholland and Rapp1992).