3.2.1. Ice thickness modeling

The distributed glacier ice thickness was estimated using the GlabTop model (Linsbauer and others, Reference Linsbauer, Paul and Haeberli2012; Paul and Linsbauer, Reference Paul and Linsbauer2012). The model uses glacier boundaries, glacier branch lines and a DEM as inputs to simulate glacier ice-thickness. The glacier boundaries and branch lines were manually digitized from the satellite images and the Digital Elevation Model, whereas the mean glacier slope was estimated from the ASTER GDEM. The GlabTop model is based on the parameterization scheme presented by Hoelzle and Haeberli, (Reference Hoelzle and Haeberli1995) using a constant value for the basal shear stress (τ_b). The GIS implementation of the GlabTop model (Paul and Linsbauer, Reference Paul and Linsbauer2012) used in the present study estimates the value for the basal shear stress τ_b as a function of elevation relief to derive ice-thickness along branch lines as follows:

(1)$$h = \displaystyle{{\tau _b} \over {\,f\rho gsin\alpha }}$$

where, h is the ice-thickness along the central branch lines, the shape factor f accounts for the friction of glacier body with the valley walls and is computed as the ratio of glacier cross sectional area and the product of its perimeter and the centre-line thickness, ρ is density of glacier ice (900 kg m⁻³), g is acceleration due to gravity (9.8 m s⁻²) and α is the mean glacier surface slope along the branch lines (α ≠ 0). In the present study we used a constant value of f = 0.8 and τ _b = 120 kPa (Zou and others, Reference Zou2021). The technical details of the GlabTop model and its implementation in GIS are described in detail by Paul and Linsbauer (Reference Paul and Linsbauer2012) and Linsbauer and others (Reference Linsbauer, Paul and Haeberli2012), and are therefore only briefly summarized here. The GlabTop model calculates the ice-thickness at the points along the branch lines. The ice-thickness values between the base points were interpolated to produce a continuous thickness along the branch lines. The ice-thickness was calculated along 26 and 10 branch lines for the Kolahoi and Machoi glaciers, respectively. Spatial interpolation of the ice-thickness values along the branch lines was performed in ArcGIS (ESRI, 2008) using the ANUDEM interpolation scheme (Hutchinson, Reference Hutchinson1989) to generate spatially distributed ice thickness maps of both glaciers.

3.2.2. Field measurements

The field-based glacier ice-thickness measurements were carried out using 8 MHz Ground Penetrating Radar, a turnkey system developed by Blue System Integration Ltd (Mingo and Flowers, Reference Mingo and Flowers2010; https://www.bluesystem.about/ice-penetrating-radar.html). The system comprises of radar receiving unit, a set of antenna (Transmitter and Receiver), rigging components, and collapsible antenna protection tubing together with a ski-based sled system (Mingo and Flowers, Reference Mingo and Flowers2010). The IceRadar Embedded Processing Unit (EPU) is equipped with data acquisition electronics, GPS unit and a touch-screen embedded computer. The radar and GPS data are acquired and logged continuously at user defined intervals, besides, the radar data acquired is displayed real time in 1-D and 2-D radargrams. All the components are fitted within a water- and dust-proof rugged enclosure (Fig. 2).

Fig. 2.

Ground Penetrating Radar (GPR) operation during glacier field survey; (a) Deployment of the ground penetrating ice-radar for surveys on the Kolahoi glacier; (b) The receiver, digitizer and embedded computer system are housed in a rugged water- and dust-proof enclosure. The receiving antenna is connected to the digitizer through a port drilled into the back of the case and (c) Transmitter and battery are housed in another case and mounted on skis during field survey. The transmitting antenna is threaded through ports drilled into case.

The mono pulse transmitter (Narod and Clarke, Reference Narod and Clarke1994) delivers 1100 V (±550 V) into a 50Ω resistively loaded dipole antenna at a rate of 512 Hz (Mingo and Flowers, Reference Mingo and Flowers2010). In the present study, 4 m half-length antenna i.e., 8 m each for receiving and transmitting, with a central frequency of 8 MHz, was used for glacier ice thickness measurements. With a wave speed of 168 m μs⁻¹ in glacier ice and air speed of 300 m μs⁻¹, the ice depth D is calculated as follows:

(2)$$D = \displaystyle{{\;1} \over 2}\left[{{168}^2\left({t + \displaystyle{d \over {300}}} \right)-d^2} \right]^{( 1/2) }\;, \;$$

where, d is the antenna separation and t is the two-wave travel time.

The IceRadar uses the National Instruments NI-5133 digitizer with a sampling rate up to 250 MSs⁻¹, 100 MHz bandwidth, and 512 Hz PRF with 12-bit resolution (Mingo and Flowers, Reference Mingo and Flowers2010). A small, waterproof, rugged and USB-powered GARMIN NMEA 18 ×  GPS on-board is used for recording the coordinates at each measurement point. The GPR measurements were recorded once every five seconds. In this study, several glacier transects on the two glaciers were surveyed for the ice thickness (Fig. 1). IceRadar Analyzer version 4.2.6 software, as part of the IceRadar system, was used for data viewing, picking, analysis and export for generation of the ice-thickness data from the radargrams. The software allows applications of Dewow, Detrend, gain control and filtering of the radargram data.

3.2.3. Validation of the simulated ice thickness

The GPR measurements are stored as point features with the associated geolocation coordinates. Using the ‘Extract Multi Values to Points’ function in ArcGIS, ice-thickness values from the spatially distributed rasters were extracted for every GPR point measurement.

In order to ascertain the accuracy of the simulated ice-thickness estimates, statistical tests including Correlation Coefficient (CC, Benesty and others, Reference Benesty, Chen, Huang and Cohen2009), Relative Bias (RB) (Gumindoga and others, Reference Gumindoga, Rientjes, Haile, Makurira and Reggiani2016) and the Nash–Sutcliffe Coefficient (NSC, Nash and Sutcliffe, Reference Nash and Sutcliffe1970) were used. A CC value of +1 indicates a perfect positive fit, −1 value indicates a perfect negative fit whereas 0 value indicates no correlation at all. The CC is calculated as follows:

(3)$$CC = \displaystyle{{\mathop \sum \nolimits^ \left({Obs-\mathop {Obs}\limits^{{\_}{\_}{\_}{\_}{\_}{\_}} } \right)\left({Sim-\mathop {Sim}\limits^{{\_}{\_}{\_}{\_}{\_}} } \right)} \over {\sqrt {\mathop \sum \nolimits_i^n \left({Obs-\mathop {Obs}\limits^{{\_}{\_}{\_}{\_}{\_}{\_}} } \right)} \sqrt {\mathop \sum \nolimits_{i = 1}^n \left({Sim-\mathop {Sim}\limits^{{\_}{\_}{\_}{\_}{\_}{\_}} } \right)} }}\;, \;$$

The performance of a model, on the basis of RB, is generally categorized into three basic classes: underestimation (bias ≤10%), overestimation (bias >10%), and approximately equal (−10 to 10%) (Brown, Reference Brown2006). RB is calculated by using the following equation:

(4)$$RB = \left[{\displaystyle{{\mathop \sum \nolimits_{i = 1}^n ( {Sim_i-Obs_i} ) } \over {\mathop \sum \nolimits_{i = 1}^n Obs_i}}} \right]\times 100\;, \;$$

The Nash–Sutcliffe Coefficient (NSC) (Nash and Sutcliffe, Reference Nash and Sutcliffe1970), also known as the coefficient of efficiency, is a good indicator for predicting efficiency of a model and varies from minus ∞ to 1, with 1 being the perfect skill and values close to 1 indicate high model efficiency. The NSC is calculated as follows:

(5)$$NSC = 1-\displaystyle{{\mathop \sum \nolimits_{i = 1}^n {( {Obs_i-Sim_i} ) }^2} \over {\mathop \sum \nolimits_{i = 1}^n {( {Obs_i-\overline {Obs} } ) }^2}}\;, \;$$

where, n is the total number of pairs of simulated (Sim) and observed (Obs) ice thickness values, i is the i ^th value of the simulated and observed ice thickness values, $\overline {Sim}$ and $\overline {Obs\;}$ are mean values of modeled and observed glacier ice thickness, respectively.

3.2.4. Error estimation

We estimated uncertainty in the glacier-area estimates, field observed ice-thickness measurements, simulated ice-thickness estimates and glacier-volume estimates using various approaches. The uncertainty in glacier area was found to be equal to 0.2 and 0.1 km² for Kolahoi and Machoi glaciers, respectively, obtained using the following equation (Braun and others, Reference Braun2019):

(6)$$\delta A = \displaystyle{{Rp/A} \over {Rp/A_P}}\;\;\times \;0.03\;, \;$$

where, Rp/A is the glacier perimeter–area ratio and Rp/A _P is a constant equal to 5.03 km^–1 (Paul and others, Reference Paul2013). Several other studies have used the same approach to determine uncertainty in glacier area delineation from remote sensing data (Malz and others, Reference Malz2018; Farías-Barahona and others, Reference Farías-Barahona2020). The uncertainty observed in glacier area in this study is in line with the error estimates reported in previous studies over the region (Abdullah and others, Reference Abdullah, Romshoo and Rashid2020; Romshoo and others, Reference Romshoo, Fayaz, Meraj and Bahuguna2020b, Reference Romshoo, Abdullah, Rashid and Bahuguna2022a).

For determining uncertainty of the GlabTop simulated ice thickness, we relied on the error estimation analysis done by Linsbauer and others (Reference Linsbauer, Paul and Haeberli2012) who calculated the model uncertainty by systematic variation in the values of the input parameters including shear stress (τ: ± 30%), glacier slope (α: ± 10%) and shape factor (f: ± 12.5%). The study reported an uncertainty of ±30%, and the same has been considered in other studies like Paul and Linsbauer (Reference Paul and Linsbauer2012) and Ramsankaran and others (Reference Ramsankaran, Pandit and Azam2018).

Similarly, we considered an overall uncertainty of ±5% for the GPR measurements (Fischer and Kuhn, Reference Fischer and Kuhn2013), which is due to the uncertainty of the signal velocity in a glacier, uncertainty in the antenna separation, uncertainty in the interpretation of multiple reflections, the accuracy of the oscilloscope readings (Fischer and Kuhn, Reference Fischer and Kuhn2013), and errors caused by off-nadir reflections as we did not perform off-nadir reflection corrections (Plewes and Hubbard, Reference Plewes and Hubbard2011; Björnsson and Pálsson, Reference Björnsson and Pálsson2020).

The uncertainty in the total glacier volume u(V)/V depends on the ice-thickness (h) and glacier area (A) and was calculated using the error propagation method (Ramsankaran and others, Reference Ramsankaran, Pandit and Azam2018), which is described as follows:

(7)$$\displaystyle{{u( V ) } \over V} = \sqrt {{\left[{\displaystyle{{u( A ) } \over A}} \right]}^2 + {\left[{\displaystyle{{u( h ) } \over h}} \right]}^2} , \;$$

where, u(A) and u(h) are uncertainties in glacier area and ice thickness, respectively.