Transpressional uplift domains of inverted Pliocene–Pleistocene basin fill along the San Andreas fault zone in Coachella Valley, southern California (USA), are characterized by fault linkage and segmentation and deformation partitioning. The Indio Hills wedge-shaped uplift block is located in between two boundary fault strands, the Indio Hills fault to the northeast and the main San Andreas fault to the southwest, which merge to the southeast. Uplift commenced about or later than 0.76 million years ago and involved progressive fold and faulting stages caused by a change from distributed strain to partly partitioned right-slip and reverse/thrust displacement on the bounding faults when approaching the fault junction. Major fold structures in the study area include oblique, right-stepping, partly overturned en echelon macro-folds that tighten and bend into parallelism with the Indio Hills fault to the east and become more open towards the main San Andreas fault to the west, indicating an early and close relationship of the macro-folds with the Indio Hills fault and a late initiation of the main San Andreas fault. Sets of strike-slip to reverse step-over and right- and left-lateral cross faults and conjugate kink bands affect the entire uplifted area, and locally offset the en echelon macro-folds. Comparison with the Mecca Hills and Durmid Hills uplifts farther southeast along strike in Coachella Valley reveals notable similarities, but also differences in fault architectures, spatial and temporal evolution, and deformation mechanisms. The present work contributes to better understand the structure and tectonic history of a major fault system along a transform plate boundary.
This paper describes and evaluates structural patterns of the Indio Hills uplift in the northwestern part of Coachella Valley along the San Andreas fault zone (SAFZ) in California, southwestern USA (Fig. 1), where the fold–fault architecture, evolution, and partitioning of deformation compared to Mecca Hills and Durmid Hills are not well understood (e.g., Keller et al., 1982; Dibblee and Minch, 2008). The main goal of this study is to analyze internal macro- and meso-scale folds and related faults and to outline the kinematic evolution in relation to major SAFZ-related fault strands in the area (Fig. 1: Keller et al., 1982; Guest et al., 2007). These include the Indio Hills fault in the northeast (Allen, 1957; Tyley, 1974) and the main San Andreas fault along the southwest flank of the Indio Hills and of the Mecca Hills, and along the northeast flank of the Durmid Hills (Janecke et al., 2018; Fig. 1). The progressive tectonic evolution model for the Indio Hills uplift is then compared and correlated with other major uplifts and SAFZ-related fault strands along strike in the Mecca Hills and Durmid Hills (Sylvester and Smith, 1987; McNabb et al., 2017; Janecke et al., 2018; Bergh et al., 2019). We also briefly discuss the potential northwestward continuation of the Indio Hills fault into the eastern California shear zone and its role as a possible transfer fault (Dokka and Travis, 1990a, b; Thatcher et al., 2016). The variable fault and fold architectures and associated ongoing seismic activity in these uplift areas underline the need for persistent along-strike studies of the SAFZ to characterize the fundamental geometry, resolve the kinematic development, and correlate regionally major fault strands (see Janecke et al., 2018). Such studies are essential to explain the observed lateral variations in fold and fault architectures and to resolve mechanisms of transpression, fault linkage, and areal segmentation in continental transform settings.
The Coachella Valley segment of the SAFZ in southern California is expressed as multiple, right-lateral fault strands, which uplifted blocks in the Indio Hills, Mecca Hills, and Durmid Hills (Fig. 1; Sylvester, 1988). These domains comprise thick successions of Pliocene–Pleistocene sedimentary strata uplifted and deformed in Pleistocene–Holocene time due to oblique convergence of the Pacific and North American plates and movement along the SAFZ and related faults (e.g., Atwater and Stock, 1998; Spotila et al., 2007; Dorsey et al., 2011). Recent structural studies in the Mecca Hills (McNabb et al., 2017; Bergh et al., 2019), and Durmid Hills at the southern termination of the SAFZ (Janecke et al., 2018), show that individual fault strands are linked and that the deformation splits into abruptly changing fold and fault geometries (Fuis et al., 2012, 2017). These recent works call for further characterization of the understudied Indio Hills segment in order to compare its structural development with other uplifted features along a major transform plate boundary fault zone. Below we summarize local and regional fault nomenclature, distribution, and fault movement history (Table 1) throughout the greater Coachella Valley region (Fig. 1), the stratigraphy of the Indio Hills area, and previous structural work in the main Indio Hills, Mecca Hills, and Durmid Hills uplift areas.
Summary of the timing of the main events in the Coachella Valley and Gulf of California. Note the presumed timing phases (1–3) of fold-faulting and uplift events in the Indio Hills (this work). The stratigraphy is common to the Mecca Hills and Indio Hills, although some features are only observed in one area (e.g., unconformities 1 and 2 in the Mecca Hills but not in the Indio Hills).
The southeastern Indio Hills are a WNW–ESE-trending tectonic uplift situated in a small restraining bend northeast of the main San Andreas fault (Figs. 1 and 2 and S1 in the Supplement). The studied uplift is located along strike about 25–50 km northwest of the Mecca Hills and Durmid Hills and to the southeast of the major left bend in the SAFZ trace near San Gorgonio Pass (Matti et al., 1985, 1992; Matti and Morton, 1993; Dair and Cooke, 2009).
Interpreted Google Earth image in the southeastern part of the
Indio Hills uplift area. Three main SAFZ-oblique macro-folds (northwestern,
central, southeastern) are mapped in between the bounding Indio Hills and
main San Andreas faults, whereas one SAFZ-parallel anticline is present
close to the Indio Hills fault. More detailed figures are numbered and
framed. Structural datasets are plotted in lower hemisphere Schmidt
stereonets via the Orient software (Vollmer, 2015). Note that faults are
also included as fractures in the stereonets. Bedding surfaces are shown as
pole to plane with frequency contour lines, with average
The main faults in the southeastern Indio Hills include the Indio Hills fault in the northeast (Allen, 1957; Tyley, 1974) and the main San Andreas fault in the southwest (we refrain from using the name “Indio strand” ascribed to this fault by Gold et al., 2015, to avoid confusion with the Indio Hills fault). Regionally, the Indio Hills fault possibly merges with the Landers–Mojave Line and the eastern California shear zone in the north (Dokka and Travis, 1990a, b; Nur et al., 1993a, b; Thatcher et al., 2016). The Landers–Mojave Line is believed to be the locus of several recent earthquakes aligned in a NNW–SSE trend, including the 1992 Joshua Tree earthquake (Fig. 1b; Nur et al., 1993a, b). These earthquakes were tentatively ascribed to movement along a through-going NNW–SSE-striking fault, possibly the west-dipping Quaternary West Deception Canyon fault (Sieh et al., 1993; Rymer, 2000). This fault is thought to crosscut the E–W- to ENE–WSW-striking, left-lateral, Holocene Pinto Mountain fault, which merges with the main strand of the San Andreas fault in the west at the intersection of the right-lateral Mission Creek and Mill Creek strands (Allen, 1957; Bryant, 2000; Kendrick et al., 2015; Blisniuk et al., 2021). The former is thought to correspond to the continuation of the main San Andreas fault to the northwest (Gold et al., 2015) and may have accommodated ca. 89 km of right slip in the past 4 million years, whereas the latter accommodated about 8 km right slip at 0.5–0.1 Ma and is offset ca. 1 km by the Pinto Mountain fault (Kendrick et al., 2015).
The main San Andreas fault continues to the southeast where it bounds the Mecca Hills to the southwest. The Painted Canyon fault, a previous (late Miocene?–) Pliocene southwest-dipping normal fault reactivated as a right-lateral-reverse oblique-slip fault in the Pleistocene–present day, bounds the Mecca basin to the northeast (Sylvester and Smith, 1987; McNabb et al., 2017; Bergh et al., 2019). Farther southeast, the main San Andreas fault proceeds along the northeast flank of the Durmid Hills opposite the Pleistocene (ca. 1 Ma) right-lateral East Shoreline fault (Babcock, 1969, 1974; Bürgmann, 1991; Janecke et al., 2018). There, the main San Andreas fault merges with the Brawley seismic zone (Lin et al., 2007; Hauksson et al., 2012; Lin, 2013) and, together with the right-lateral San Jacinto fault zone, they merge into the right-lateral Imperial fault (Rockwell et al., 2011). In the north, the main San Andreas fault splays into the Banning strand and the Mission Creek fault in the northwestern part of the Indio Hills (Keller et al., 1982; Gold et al., 2015). The Banning strand is much younger than the Mission Creek fault and may have accommodated approximately 3 km of right slip in the past 0.1 million years (Kendrick et al., 2015).
Northwest and west of the Coachella Valley, Miocene–Pleistocene sedimentary strata are structurally bounded by the San Bernardino and San Jacinto fault strands of the SAFZ (Bilham and Williams, 1985; Matti et al., 1985; Morton and Matti, 1993; Spotila et al., 2007). To the southwest, Miocene–Pleistocene strata are bounded by the West Salton Detachment fault (Dorsey et al., 2011). The San Jacinto fault is typically believed to have slipped ca. 25 km right-laterally in the past 1.5 million years (Matti and Morton, 1993; Kendrick et al., 2015), whereas the West Salton Detachment fault is a low-angle normal fault that accumulated ca. 8–10 km of normal-oblique movement starting in the mid-Miocene and is related to the opening of the Gulf of California (Prante et al., 2014, and references therein).
The Indio Hills uplift is an inverted Pliocene–Pleistocene sedimentary basin lying upon Mesozoic granitic basement rocks, which we regard as an analog to the inverted Mecca basin farther southeast (Keller et al., 1982; Damte, 1997; McNabb et al., 2017; Bergh et al., 2019). In the Mecca basin, alluvial, fluvial, and lacustrine deposits of the Mecca and Palm Spring formations are truncated unconformably by the middle to upper Pleistocene Ocotillo Formation (Dibblee, 1954; Sylvester and Smith, 1976, 1987; Boley et al., 1994; Rymer, 1994; Sheridan et al., 1994; Sheridan and Weldon, 1994; Winker and Kidwell, 1996; Kirby et al., 2007; McNabb et al., 2017; Table 1). Similar uplifted strata at Durmid Hills (Fig. 1) belong to the Pliocene–Pleistocene Borrego Formation and are overlain by middle to upper Pleistocene deposits of the Brawley and Ocotillo formations (Dibblee, 1997; Herzig et al., 1988; Lutz et al., 2006; Kirby et al., 2007; Dibblee and Minch, 2008).
Leuco-granitic rocks crop out near gently SW-dipping conglomerates along the northeastern flank of the Indio Hills, near the trace of the Indio Hills fault (Fig. 2). Despite proximity of the conglomerates to segmented granite outcrops, the contact itself is not exposed. The conglomerates are the lowermost stratigraphic unit exposed in the Indio Hills and are characterized by a succession of meter-thick beds of very coarse, poorly sorted blocks of gneissic and granitic rocks more than a meter in size. Previous mapping in the area (Dibblee, 1954; Lancaster et al., 2012) considered the conglomerates to be stratigraphic equivalents to the middle to upper Pliocene Mecca Formation in the Mecca Hills (Sylvester and Smith, 1987; McNabb et al., 2017; Bergh et al., 2019), and at least part of the clasts are from the leuco-granitic rocks, which must correspond to basement rocks of the inverted Indio Hills basin. Up-section toward the southwest, the conglomerate gradually is succeeded by coarse-grained sandstone, which defines the transition from the Mecca Formation to the lower Palm Spring Formation.
The Palm Spring Formation in the Indio Hills consists of moderately to well-consolidated alluvial fan deposits (Dibblee and Minch, 2008), with some interbedded gypsum layers and red-colored calcareous mudstone, as in the Mecca Hills (Sylvester and Smith, 1987). The main rock types include beds of light-colored, medium- to coarse-grained sandstone, gray–brown silty sandstone, and dark biotite-rich mudstone. The southwestwards increase in silt–clay toward the main San Andreas fault (also recorded in the Mecca Hills; Bergh et al., 2019) may indicate a gradual transition from the lower to the upper member of the Palm Spring Formation. By contrast, the transition between the lower and upper members of the Palm Spring Formation in the Mecca Hills is marked by two angular unconformities that signal further steps in uplift and inversion of the Mecca basin (Table 1; McNabb et al., 2017; Bergh et al., 2019).
Ages of 3.0–2.3 Ma (latest Pliocene–early Pleistocene) and 2.6–0.76 Ma (earliest Pleistocene to earliest late Pleistocene) were obtained respectively for the lower and upper member of the Palm Spring Formation in the Mecca Hills based on reversed magnetic polarity data (Chang et al., 1987; Boley et al., 1994; McNabb, 2013; McNabb et al., 2017; Table 1). We infer a similar age range for the Palm Spring Formation in the southern Indio Hills.
In contrast to other uplift areas in Coachella Valley, the Ocotillo Formation has not been mapped in the Indio Hills in the present study. However, based on the occurrence of the Bishop Ash at the northwestern edge of the study area and the occurrence of the volcanic deposit within the uppermost Palm Spring Formation or at the base of the overlying Ocotillo Formation in the Mecca Hills, it is likely that the Ocotillo Formation is present just northwest of the area mapped (Fig. 2). In addition, it is deposited on the flank northeast of the Indio Hills fault, and southwest of the main San Andreas fault (Figs. 1 and 2), indicating that this unit was either not deposited or eroded in the area that recorded the most uplift in Indio Hills.
Additional dating constraints on transpressional uplift in the Coachella Valley include tephrochonology of the 0.765-million-year-old Bishop Ash layer (Sarna-Wojcicki et al., 2000; Zeeden et al., 2014; Table 1). This volcanic deposit is found within the upper member of the Palm Spring Formation (which is unconformably overlain by the Ocotillo Formation) in the hanging wall of the Painted Canyon fault away from the fault, and within the base of the Ocotillo Formation in the hanging wall of the Painted Canyon fault near the fault (Ocotillo and uppermost Palm Spring formations interfingering near the fault) and in the footwall of the fault (McNabb et al., 2017; Bergh et al., 2019). The unconformable contact between the Palm Spring and Ocotillo formations away from the Painted Canyon fault towards the southwest and their interfingering relationship near the fault suggest that uplift had already initiated prior to deposition of the Ocotillo Formation (i.e., before 0.76 Ma, in the mid-Pleistocene), possibly during the formation of the lower unconformity between the lower and upper members of the Palm Spring Formation (McNabb et al., 2017; Table 1). Complementarily, the involvement of the Bishop Ash in deformation suggests that deformation continued past 0.76 Ma (in the late Pleistocene).
The southeastern end of the Indio Hills is an uplifted domain of deformed strata of the Mecca and Palm Spring formations situated in between the main San Andreas and Indio Hills fault (Fig. 2). The main San Andreas fault corresponds to a major oblique strike-slip fault segment at the eastern end of San Gorgonio Pass (Matti et al., 1985; Morton et al., 1987). It is easily traced to Indio Hills (Figs. 1 and 2) since its main trace provides preferential pathways for groundwater flow and growth of wild palm trees along strike.
The Indio Hills fault was mapped north of the study area (Dibblee and Minch, 2008) extending into the Landers–Mojave Line (Nur et al., 1993a, b), a NNW–SSE-striking right-lateral fault system extending hundreds of kilometers northward from the southeastern Indio Hills into the eastern California shear zone and related fault segments such as the Calico and Camp Rock faults (Fig. 1; Dokka et al., 1990a; Nur et al., 1993b). The Indio Hills fault may correspond to a major fault splay of the SAFZ (Dokka and Travis, 1990a, b; Thatcher et al., 2016). Southeast of the Indio Hills, however, the geometry of the Indio Hills fault remains elusive, and the fault either dies out or merges with structures like the main San Andreas fault, the Skeleton Canyon fault, and/or the Painted Canyon fault in the Mecca Hills (Fig. 1).
The transpressional character of the Indio Hills uplift was suggested by
Sylvester and Smith (1987). However, detailed structural analyses
documenting this hypothesis for the uplift as a whole have not been
conducted. Gold et al. (2015) explore tectonogeomorphic evidence for
dextral-oblique uplift, and Keller et al. (1982) and Blisniuk et al. (2021)
focus on landscape evolution near the intersection of the Banning strand and
Mission Creek fault (northwest of the study area), which merge into the main
San Andreas fault (Fig. 1). In addition to investigating soil profiles,
offset drainage systems, and recent (a few thousand years old) displacement
along the SAFZ, Keller et al. (1982) called attention to a strong dominance
of gently plunging and upright macro-folds in bedrock strata along the
Mission Creek fault and at the southeastern end of the Banning strand where
these faults merge. Their study showed that bends and steps along the main
fault traces were consistently located near brittle fault segments and zones
of uplift. The study also showed that drainage systems were offset recently
(at ca. 0.03–0.02 Ma) and indicate relatively high slip rates along the
Mission Creek fault on the order of 23–35 cm yr
Farther south, the Mecca Hills uplift was previously defined as a classic flower structure (Sylvester and Smith, 1976, 1987; Sylvester, 1988), in which all folds and faults formed synchronously and merged at depth. Recent analyses (Bergh et al., 2014, 2019) indicate a modified flower-like structure, consisting of a steep SAFZ fault core zone to the southwest, a surrounding approximately 1–2 km wide damage zone expressed by en echelon folds and faults oblique to the SAFZ (including left-slip cross faults), steeply plunging folds, and SAFZ-parallel fold and thrust belt features (including right- and left-slip and oblique-reverse faults) formed in kinematic succession. In addition to the steep shallow portion of the SAFZ (Fuis et al., 2012, 2017), two other major NW–SE-striking faults occur in the Mecca Hills (Fig. 1). One is the Skeleton Canyon fault, which initiated as a steep SAFZ-parallel strike-slip fault and was reactivated as a reverse fault dipping gently northeastwards in the late kinematic stages (Sylvester and Smith, 1976, 1979, 1987; Bergh et al., 2019). The other is the Painted Canyon fault, which is a former Miocene–Pliocene basin-bounding normal fault (McNabb et al., 2017) and is now reactivated as a NE-directed thrust fault with dip to the southwest (Bergh et al., 2019; Table 1). The polyphase evolution and reactivation of internal oblique, step-over faults, and SAFZ-parallel faults were explained by a series of successive–overlapping events involving a change from distributed and locally partitioned into fully partitioned strain in a changing oblique-plate convergence regime (Bergh et al., 2019).
The Durmid Hills are an elongate ridge that parallels the main strand of the SAFZ at the south edge of the Salton Sea in Imperial Valley (Fig. 1). Farther south, this deformation zone and the SAFZ project towards the Brawley seismic zone, an oblique transtensional rift area with particularly high seismicity (Lin et al., 2007; Hauksson et al., 2012; Lin, 2013). The main San Andreas fault (mSAF) is located on the northeast side of the Durmid Hills and has been thoroughly studied (Dibblee, 1954, 1997; Babcock, 1969, 1974; Bilham and Williams, 1985; Bürgmann, 1991; Sylvester et al., 1993; Lindsey and Fialko, 2013; Janecke et al., 2018). The rocks southwest of the mSAF consist of highly folded Pliocene–Pleistocene deposits (Babcock, 1974; Bürgmann, 1991; Markowski, 2016; Janecke et al., 2018) bounded to the southwest by the subsidiary East Shoreline fault strand of the SAFZ. Northeast of the mSAF, the formations are much less deformed (Janecke et al., 2018). The overall structure (Fig. 1) resembles a right-lateral strike-slip duplex (Sylvester, 1988), but the geometry is not fully consistent with a duplex model due to abundant left-lateral cross faults and internal block rotations. Instead, the Durmid Hills structure was interpreted as a ladder structure (Janecke et al., 2018), as defined by Davis (1999) and Schultz and Balasko (2003), where overlapping, E–W- to NW–SE-striking step-over faults rotated along multiple connecting cross faults. The 1–3 km wide Durmid ladder structure consists of multiple internal clockwise-rotating blocks bounded by major en echelon folds and right- and left-lateral cross faults in between the right-slip mSAF and East Shoreline fault strand, indicating a complex termination of the SAFZ around the Brawley Seismic Zone to the southeast (Fig. 1).
In our investigation of the Indio Hills, we used Google Earth images and aerial photographs (© Google Earth 2011) as a basis for detailed field and structural analyses (Fig. 2). We mapped and analyzed individual macro- and meso-scale folds and associated faults in Miocene–Pliocene strata both in the field and via imagery analysis. Key horizons of light-colored quartz sandstone and carbonate rocks in the Palm Spring Formation provide structural markers, notably to correlate bed displacement and fault–fold geometries and kinematics. We address crosscutting relations of the main San Andreas and Indio Hills faults and nearby fold structures. Structural orientation data are obtained from meso-scale folds and faults and are integrated between the areal segments to link a prevalent pattern of deformation into a wider structural architecture (Fig. 2).
The study area comprises three major SAFZ-oblique, asymmetric, E–W-trending, moderately west-plunging fold systems having multiple smaller-scale parasitic folds (Fig. 2). The main folds affect most of the Palm Spring Formation in a zone approximately 2 km wide between the main San Andreas and Indio Hills faults (Fig. 2). The northeastern flank of the Indio Hills is structurally different by consisting of a sub-horizontal, NW–SE-trending, open, upright anticline, which trends parallel to the Indio Hills fault (Fig. 2). Similarly, close to the main San Andreas fault, tilted strata of the Palm Spring Formation are folded into a tight, steeply plunging shear fold (folds involving shearing along a plane that is parallel to subparallel to the fold's axial plane; Groshong, 1975; Meere et al., 2013; Fig. 2). At a smaller scale, several subsidiary reverse faults and mostly right-slip step-over faults having orientations both parallel (E–W to NW–SE) and perpendicular (NNE–SSW) to the bounding faults exist within the macro-folded domain. Most of these faults truncate individual SAFZ-oblique folds.
SAFZ-oblique macro-folds are consistently asymmetric and mostly
south-verging, and their axial surfaces are arcuate and right-stepping (Fig. 2). Fold geometries change from open and nearly upright near the main San
Andreas fault to kink/chevron styles in the middle part to very tight
(isoclinal) and overturned fold styles adjacent to the Indio Hills fault
(Figs. 3a–c and S2a–c). These changes in geometry correspond to
a change in obliquity of the fold axial surface trace from approximately
60–70
Detailed structural maps showing the architecture and outline of
anticline–syncline pairs, traces of bedding and strike and dip orientation,
axial surface traces, and fold-related faults in
The northwestern and central macro-folds define two major compound and
arcuate fold systems that affect the entire Palm Spring Formation between
the main San Andreas and Indio Hills faults (Fig. 3a–b). They consist of
eight subsidiary Z- and S-shaped south-verging anticline–syncline pairs
and show fold axes plunging variably but mostly about 30
Another feature of the central macro-fold is that it is offset by a system of both layer-parallel and bed-truncating faults (Fig. 3b). Strata east of the fault system are affected by a large shear fold having thickened hinges and thinned limbs. The next fold to the north-northeast changes from open to tight, overturned, and locally isoclinal (Fig. S4a–c) and merges with the inverted NE-dipping back limb of the southeastern macro-fold (Fig. 3c). Notably, the consistent eastward tightening of fold hinges occurs within the lower stratigraphic parts of the Palm Spring Formation, whereas conglomerates of the underlying Mecca Formation are only weakly folded (see Sect. 4.4). Furthermore, beds in tighter folds (especially in relatively weak clayish–silty dark mudstone layers) are commonly accompanied by disharmonic folds and internal structural disconformities. By contrast, more rigid and thicker sandstone beds are more commonly fractured.
The southeastern macro-fold is expressed as a kilometer-wide, Z-shaped, open
to tight, south-verging syncline–anticline pair showing moderately
west-plunging axes and steeply north-dipping axial surfaces (Fig. 3c). Most
of the Palm Spring Formation strata on the back-limb trend parallel to the
Indio Hills fault and dip about 50–70
A macro-folded siltstone layer of the lower Palm Spring Formation more than
200 m southwest of the Indio Hills fault (Fig. 4a) contains
centimeter-scale upright (sub-horizontal) and disharmonic folds having E–W
trend and western plunge (Fig. 4b). These intra-layer folded strata are cut
by low-angle reverse faults yielding a NE-directed sense of shear. The
upright geometry and the sub-horizontal fold axes (about 5
Meso-scale folds and related faults on the back limb of the
southeastern macro-fold. See location in Fig. 3c.
About 100–200 m southwest of the trace of the Indio Hills fault, the
conglomerates of the Mecca Formation are folded into a major open anticline,
whose axis is parallel to slightly oblique (
A couple of major synclines showing axial traces parallel to the main San Andreas fault are also well displayed on Google Earth images (Figs. 5 and S6). These folds affect WSW-dipping strata of the Palm Spring Formation on the broadened western part of the northwest and central macro-folds. Fold geometries are tight and asymmetric, with wavelengths less than 200 m, and presumably steep NW-plunging axes. The local appearance and sheared geometry of these folds contrast both with the broad SAFZ-oblique folds near the main San Andreas fault and with that of the upright SAFZ-parallel anticline near the Indio Hills fault.
Interpreted SAFZ-parallel macro-folds (synclines) adjacent to the main San Andreas fault, which affect the southern limb of earlier (en echelon) macro-folded and tilted strata of the Palm Spring Formation. Note shear fold geometry in the inset map with a thickened hinge zone and thinned limb to the south, steeply plunging axis, and axial trace parallel to the main San Andreas fault. See Fig. 2 for location. Uninterpreted version of the image available as Fig. S4. © Google Earth 2011.
Fold-related brittle faults exist both in granitic basement and in sedimentary rocks of the Mecca and Palm Spring formations in the study area. Such faults display narrow damage zones less than 1 m wide and are geometrically related to either SAFZ-oblique or SAFZ-parallel macro- and meso-scale folds, or they are orthogonal to the SAFZ and related faults. With the exception of the main San Andreas and Indio Hills faults, brittle faults are generally difficult to trace laterally, but, where preserved, they display centimeter- to meter-scale strike-slip and/or reverse dip-slip displacement. Macro-scale fault orientations and kinematics in sedimentary rocks are more variable than in basement rocks but commonly strike WNW–ESE to N–S and show moderate–steep dips to the northeast (Fig. 2). Subsidiary meso-scale faults include high-angle SW- and SE-dipping strike-slip faults and low-angle SW-dipping thrust faults. We describe the Indio Hills and main San Andreas faults, strike-slip faults, and thrust faults in sedimentary strata, and fractures in basement rocks northeast of the Indio Hills fault.
Along the Indio Hills fault, poor exposures make it difficult to measure fault strike and dip directly, but Google Earth images suggest a rectilinear geometry in map view relative to the uplifted sedimentary strata to the southwest (Fig. 2). The fault strikes mainly NW–SE and is subparallel to the northeastern flank of the Indio Hills. Farther southeast, it probably merges with the main San Andreas fault (Fig. 1; Tyler, 1974). In the southeastern part of the study area (Fig. 2), the Indio Hills fault is most likely located between an outcrop of basement granite and the first outcrops of overlying strata of the Palm Spring Formation. The granite there is highly fractured and cut by vein and joint networks (see description below), as may be expected in the damage zone of a major brittle fault.
Like the Indio Hills fault, fault-plane dip and strike of the main San Andreas fault must be inferred indirectly. The main San Andreas fault in the study area strikes WNW–ESE and is sub-vertical based on its consistent rectilinear surficial trace and because it truncates both back- and fore-limb strata on most of the SAFZ-oblique macro-folds (Fig. 2). Thus, the main San Andreas fault does not seem to have had major impact on the initial geometry and development of the macro-folds in the Indio Hills. However, notable exceptions include displacement by the main San Andreas fault of the two shear folds on the southern flank of the macro-folds (Fig. 5), and a consistent counterclockwise bend of most axial traces of the macro-folds (Fig. 2).
One major brittle fault set striking NW–SE and dipping steeply to the northeast has developed on the central macro-fold (Figs. 3b and 6). The faults splay out from a bedding-parallel core zone subparallel to steeply SW-dipping mudstone–siltstone layers on the southern limb of the central macro-fold and then proceed to truncate NW-dipping sedimentary strata and offset the hinge of a macro-fold by ca. 70 m right-laterally before dying out (Fig. S7a–b). The fault damage zone is traceable for more than 1 km along strike as a right-slip fault which displaces the hinge of a major, tight, asymmetric, shear-like (similar style) fold (Figs. 6 and S8). The shear-folded sedimentary strata bend clockwise toward the main fault, thus supporting dominant right-lateral slip (Fig. 6). Minor faults branch out from the fault core zone and either die out in the macro-fold hinge and/or persist as bedding-parallel faults for some distance on the southern limb of the macro-fold (Fig. 6).
Interpreted satellite image of the central macro-fold showing right-lateral offset of the entire fold hinge/axial surface (upper left dashed blue line) by a NNW–SSE-trending, NE-dipping strike-slip fault (red lines). Note that the fault merges out from a layer in the southern limb of the macro-fold (black lines) and continues as a right-lateral fault. Offset geological markers include thick sandstone beds (yellow, white, light brown lines) and the fold axial surfaces of a second syncline fold farther south (lower right, dashed blue lines). Note that the syncline axial trace dies out to the southwest and that kink bands acting as cross faults crop out in the eastern part of image (dashed pink lines). Uninterpreted version of the image available as Fig. S8. © Google Earth 2011.
At a smaller scale, the folded and tilted strata of the Palm Spring Formation are commonly truncated by sets of steep NW–SE-striking right-lateral and NNE–SSW-striking left-lateral faults, displaying meter- to centimeter-scale offsets (Fig. S7b–d). These minor faults generally dip steeply to the northeast to east-northeast, i.e., opposite to most bedding surfaces, which dip southwest (Fig. 3b) and, in places, develop reddish fault gouge along strike. Furthermore, these minor faults typically cut sandstone beds and flatten, and/or die out within, mudstone beds, which restricts their lateral extent to a few decimeters–meters. Kinematic indicators, such as offset of bedding surfaces and fold axial surfaces, yield mostly right-slip displacements, in places with minor reverse components. In some localities, on fold limbs within thick and competent sandstone beds, such minor right- and left-slip faults appear to form conjugate sets (Fig. S7b and d) that may have developed simultaneously. In addition, NNE–SSW-striking, ESE-dipping faults and/or semi-brittle kink bands sub-orthogonal to the SAFZ are well displayed in the southeastern macro-fold (Figs. 3c and S7e) and cut bedding surfaces at high angles with left-slip displacement, therefore potentially representing cross faults between segments/splays of the SAFZ system.
Reverse and thrust faults are common and traceable on the back limb of the central and southeastern macro-folds near the SAFZ-parallel anticline and the Indio Hills fault, but not recorded in areas close to the main San Andreas fault. Reverse faults strike mainly NW–SE and dip gently to the southwest, although subsidiary gently NE-dipping faults exist. An example is the low-angle reverse fault that propagates out of the syncline on the southeastern macro-fold (Fig. 4) and yields a NE-directed sense of shear. This thrust fault may continue westward into the central macro-fold (Fig. 3b), where reverse offset of SW-dipping strata of the Palm Spring Formation constrains vertical displacement from about 10–15 m (Fig. S5a), though offset is only a few centimeters in the southeast (Fig. 4). This fault system has a listric geometry, and internal splay faults die out in thick silt- to mudstone layers. The low-angle faults seem to develop almost consistently near major fold hinge zones and propagate northeastward as out-of-the-syncline thrusts (Figs. 4 and S5a).
In sandstone beds on the north-dipping limb of the major syncline, minor-scale thrust faults offset asymmetric fold hinges (Fig. S7c) and yield down-to-the-north (normal) sense of shear if the strata are rotated to a horizontal position (Fig. S9). An opposite effect is apparent for a conjugate set of minor normal faults in a small-scale graben structure on the steep, north-dipping layer, which defines a set of reverse faults when rotating the sedimentary strata to horizontal (Figs. S7d and S9).
Basement-rock exposures in the Indio Hills are limited to a single, approximately 50 m long chain of outcrops located in the southeasternmost part of the study area (Fig. 2). These outcrops of massive granite are heavily fractured with mostly steep to sub-vertical sets that strike dominantly NE–SW to ENE–WSW and subsidiary NW–SE to NNW–SSE (see stereoplot in Fig. 2). Kinematic indicators are generally lacking, but in highly fractured areas, centimeter-thick lenses of unconsolidated reddish gouge are present, comparable to fault rocks observed in Palm Spring Formation sedimentary rocks and corresponding to similar small-scale strike-slip and reverse faults in the basement granite. The fault sets in granitic basement rocks trend parallel to fault sets in sedimentary strata southeast of the Indio Hills fault (see stereoplots in Fig. 2) and are therefore suggested to have formed due to similarly oriented stress.
We mapped and analyzed three macro-scale fold systems between the Indio
Hills and main San Andreas faults. In map view (Fig. 2), the folds are
right-stepping, and each fold set is increasingly asymmetric (Z-shaped) and
sigmoidal towards the Indio Hills fault in the northeast. Based on these
properties, we interpret the fold sets as modified SAFZ-oblique en echelon
macro-folds. Various investigators (Babcock, 1974; Miller, 1998; Titus et
al., 2007; Janecke et al., 2018; Bergh et al., 2019) describe similar fold
geometries in sedimentary strata from many other segments of the SAFZ and
are interpreted as structures formed by right-lateral displacement between
two major fault strands. However, the present fold-orientation data in the
Indio Hills (Fig. 2) do not correspond with a uniform simple shear model in
between two active strike slip faults because the long axis of the strain
ellipse is not consistently about 45
The moderate–steep westward plunge of all three macro-folds (
We propose a progressive model that changes from distributed (en echelon folding) to partly partitioned, i.e., pure shear (shortening) plus simple shear (strike-slip) deformation (Fig. 7), as inferred for other parts of the SAFZ, e.g., in the Mecca Hills (Bergh et al., 2019). In this model, the tight to isoclinal fold geometries to the northeast (Fig. 3b) may account for progressively more intense shortening near the Indio Hills fault, whereas coeval strike-slip faulting affected the already folded and steeply dipping strata of the lower Palm Spring Formation (Fig. 6). This model would favor shortening to have evolved synchronously with renewed strike-slip shearing adjacent to the Indio Hills fault and/or on a blind fault below the contact between the Mecca Formation and overlying Palm Spring Formation, because the Mecca Formation is much less deformed (Fig. 3c). Alternatively, the more mildly deformed character of the Mecca Formation conglomerate may arise from its homogeneity, which contrasts with alternating successions of mudstone–siltstone and sandstone of the Palm Spring Formation prone to accommodating large amounts of deformation and to strain partitioning. Regardless, such reshaping of en echelon folds is supported by analog modeling (McClay et al., 2004; Leever et al., 2011a, b), suggesting that partly partitioned strain may lead to a narrowing of fold systems near a major strike-slip fault (i.e., Indio Hills fault), whereas widening away from the fault indicates still ongoing distributed deformation. Partly partitioned deformation is supported by the tight to isoclinal and consistent Z-like geometry of smaller-scale folds present on the back limb of the central and southeastern macro-folds (Fig. 3b–c), indicating that they are all parasitic folds and related to the same partly partitioned shear-folding event. Where S- and Z-like fold geometries are present, these minor folds may have formed by buckling in an early stage of en echelon folding. An alternative interpretation is that the tight, reshaped parasitic folds are temporally linked to the SAFZ-parallel macro-fold south of the Indio Hills fault (Fig. 3c; see next section).
Model illustrating the progressive uplift/inversion history of the
Indio Hills presuming a narrow time interval between formation of all
structures in the area, except for the main San Andreas fault and associated
folds.
The SAFZ-parallel anticline differs significantly in geometry from the en echelon
macro-folds and associated parasitic folds by having an upright and
symmetric geometry
Progressive NE–SW-oriented contraction may have triggered formation of the
upright SAFZ-parallel anticline adjacent to the Indio Hills fault (Figs. 2
and 3c). The fault then acted as a SW-dipping thrust fault with top-NE
displacement. The oblique shortening then led to a certain amount of uplift
near the Indio Hills fault and possibly also accomplished the overturning
of folds on the northeastern back limb of the central and southeastern
macro-fold. A similar mode of advanced partitioned shortening was proposed
for SAFZ-parallel fold structures in central and southern California (Mount
and Suppe, 1987; Titus et al., 2007; Bergh et al., 2019). Our results are
supported by stress orientation data acquired by Hardebeck and Hauksson (1999) along a NE–SW-trending profile across the Indio Hills. They recorded
an abrupt change in the maximum horizontal stress direction from about
40
In this section we use the geometry and kinematics of folds and faults in
the southern Indio Hills to reconstruct the tectonic history of the area,
not only of the inverted late Cenozoic basin but also about strike-slip and
dip-slip faults that bound the basin. Essential tectonic events include (1) extensional normal faulting along the Indio Hills fault in the
mid-Miocene–Pliocene (ca. 15–3.0 Ma), (2) reactivation of the Indio Hills
fault as a right-lateral to oblique-reverse fault in the (earliest?) late
Pleistocene to present day (
Prior to inversion and uplift of the Indio Hills, the Indio Hills fault most likely acted as a SW-dipping, extensional, basin-bounding normal fault. Indications of an early-stage episode of extension are shown by micro-fault grabens in steeply dipping layers (Figs. S5d and S6); by the deposition and preservation of sedimentary strata of the Palm Spring and Mecca formations southwest of the Indio Hills, whereas they were eroded or never deposited northeast of the fault; and by fining upwards of the stratigraphic units from conglomerates in the Mecca Formation to coarse-grained sandstone in the lower parts of the Palm Spring Formation. In addition, the flat geometry of micro thrust faults (e.g., Fig. S5b–c) suggests that they were rotated during macro-folding. Restoration of all micro faults in their initial position prior to macro-folding shows that some of these faults exhibit normal kinematics with associated syn-tectonic growth strata (Figs. S5d and S9). Alternatively, the Indio Hills fault dips northeast and uplifted the granitic basement rocks in the hanging wall to the northeast, followed by erosion of the overlying Mecca, Palm Spring, and Ocotillo formations there (Fig. 1). We favor a basin geometry and formation similar to that of the Mecca Hills, where down-SW slip along the Painted Canyon fault was inferred in the (Miocene?–) Pliocene (McNabb et al., 2017), and of the transtensional Ridge Basin though having opposite vergence (Crowell, 1982; Ehman et al., 2000) with a steep SW-dipping normal fault that was progressively reactivated as an oblique-slip reverse/thrust fault during basin inversion. Formation of the Indio Hills fault as a normal fault probably occurred in mid-Miocene times during extension related to the opening of the Gulf of California (Stock and Hodges, 1989; Stock and Lee, 1994) as proposed for the Salton Trough (Dorsey et al., 2011, and references therein).
Right-lateral to right-lateral-reverse movement along the Indio Hills fault
that led to the formation of the SAFZ-oblique en echelon macro-folds also supports a
steeply dipping character for the precursory Indio Hills fault. The change
to a right-lateral-reverse fault is further supported by the presence of
both meso-scale strike-slip and thrust faults having similar NW–SE strikes
(Figs. 4, S4c, and S5a). The increased reverse (and decreasing
right-lateral) component of faulting may have triggered rotation of the en echelon
macro-fold axes to a steeper plunge, reshaped the open asymmetric folds into
tight overturned folds, and caused gentle buckling of strata in the nearby
SAFZ-parallel anticline. Hence, the Indio Hills fault ultimately functioned
as an oblique-slip thrust oblique to the transform plate boundary in the
late Pleistocene, which is supported by oblique maximum horizontal stress
near the Indio Hills fault (ca. 70
By contrast, the last episode of movement along the main San Andreas fault clearly postdates en echelon folding, from its truncating attitude (Fig. 2). In addition, the counterclockwise bending of the axial traces into an ENE–WSW trend towards the southwest suggests that a distributed component of off-fault deformation affected the area around the main San Andreas fault in its early kinematic stages in the late Pleistocene. The refolding of the southwest limb of the central macro-fold near the main San Andreas fault (Fig. 5) also favors a late-stage activation of this fault in the late Pleistocene (i.e., after the initial transpressional slip events along the Indio Hills fault in the – earliest? – late Pleistocene). Possibly as a consequence of a longer period of activity, and as suggested by relatively higher topographic relief and more intensely folded sedimentary strata in the vicinity of and along the Indio Hills fault than along the main San Andreas fault, the former probably accommodated significantly larger amounts of uplift than the latter. This implies a southwest-tilted geometry for the Indio Hills uplift.
Minor faults in the Indio Hills provide additional input to resolve the spatial, temporal, and kinematic relations between macro-fold and fault interaction. We analyzed minor fault-related folds (Fig. S5c), which, in their current position on steep north-dipping beds, define down-to-the-north displacement. However, when rotating the sedimentary strata to horizontal (Fig. S9), the fault-related folds define a low-angle fold-and-thrust system. These geometric relationships suggest that the minor folds and faults (other than right-slip faults) pre-date (or were coeval with) the SAFZ-oblique macro-folding event and that they formed initially as internal fractures due to N–S-oriented shortening when the sedimentary strata were still horizontal. This implies that some partitioning (e.g., SAFZ-parallel small-scale thrust faults) occurred simultaneously with distributed deformation (e.g., SAFZ-oblique en echelon macro-folds).
Further, our field data suggest that minor right-slip faults evolved synchronously and parallel with the E–W-trending en echelon fold limbs, propagating through rheologically weaker mudstone beds that flowed plastically and acted as slip surfaces during distributed deformation. Later or simultaneously, these faults escaped from the mudstone beds and propagated as NW–SE-striking right-slip faults adjacent to tightened shear folds during partly partitioned deformation and finally ended up with truncation of the SAFZ-oblique folds (Figs. 6 and S7a–c).
The presence of out-of-the-syncline reverse/thrust faults relative to the reshaped and tightened SAFZ-oblique macro-folds (Figs. 4 and S5a and d), where SW-dipping thrust faults formed (sub-) parallel to the Indio Hills fault, and the related upright anticline (Fig. 3c) suggests successive distributed and partly partitioned strain in the study area. The proximity and superimposed nature of reverse/thrust faults relative to the reshaped en echelon folds suggest that they utilized modified fold hinges and steeply tilted limbs as preexisting zones of weakness. Despite the uncertainty around the crosscutting relationship between the SAFZ-parallel anticline and the SAFZ-oblique en echelon macro-folds, the low-angle thrust and intra-detachment folds in the southeastern macro-fold (Fig. 4) indicate that such thrust detachments may have already formed during (early?) distributed deformation, i.e., that distributed and partitioned deformation occurred simultaneously and/or progressively (see phases 1 and 2 in Table 1).
The conjugate WNW–ESE- to NNW–SSE-striking right-slip and
NNE–SSW-striking left-slip faults and kink band feature truncate strata on
both macro-fold limbs (Fig. 3b–c) with an acute angle perpendicular to the
macro-folded and tilted Palm Spring Formation strata (e.g., Fig. S7e).
Thus, they formed together with or after the en echelon macro-folding (
In this section we use detailed structural analysis of folds and faults in the southeastern Indio Hills to outline the structural history of the tectonic uplift itself, evaluate it in terms of what is known about strain budgets within the southern San Andreas fault system, link it to nearby structures (eastern California shear zone and Landers–Mojave Line), and integrate the local structural history into a structural synthesis for the southern San Andreas fault zone in the past 4 Myr.
Our field and structural data support inversion and uplift of the Indio Hills involving progressive or stepwise stages of folding and faulting, incorporating a switch from distributed to partly partitioned transpression (Fig. 7). Prior to inversion in late Pleistocene time, the Indio Hills fault may have been a steep SW-dipping normal fault that downthrew (Miocene?–) Pliocene sedimentary strata against granitic basement rocks in its footwall to the northeast. These basement rocks were partly eroded in the footwall of the fault. In the hanging wall of the fault, strata of the Mecca Formation were deposited in the Pliocene, most likely at 3.7–3.0 Ma, and the lower and upper members of the Palm Spring Formation respectively at 3.0–2.3 and 2.6–0.76 Ma, as suggested from paleomagnetic studies in the Mecca Hills (Chang et al., 1987; Boley et al., 1994; McNabb et al., 2017).
Early inversion involved distributed transpressional strain triggered by
right-lateral slip along the Indio Hills fault (Fig. 7a). Three macro-scale
upright en echelon folds and associated parasitic folds formed in loosely consolidated
sedimentary rocks of the Mecca and Palm Spring formations after the latter
was deposited (
Further deformation in the late Pleistocene led to gradual change from
mostly distributed with minor partitioned deformation to partly partitioned
shortening and right-lateral faulting and folding (Fig. 7b), probably since
the Indio Hills fault started to accommodate an increasing amount of reverse
slip, thus acting as an oblique-slip right-lateral-reverse fault, and where
the main San Andreas fault did not yet play a major role. The main result
was tightening of the macro-folds toward the Indio Hills fault and clockwise
rotation of fold axes to a steeper westerly plunge due to increased shear
folding, whereas en echelon upright folding continued in the southwest (Fig. 7b).
Increased shortening and shearing reshaped the macro-folds and their
back limb folds to tight, isoclinal, and partly overturned folds with
consistent Z-style and sigmoidal axial-surface traces near the Indio Hills
fault (Fig. 7b). The sigmoidal pattern of the WNW–ESE-trending en echelon macro-folds
formed at a much lower angle with the Indio Hills fault (
We favor a progressive evolution from distributed to partly partitioned
deformation as presented in Fig. 7a–c, although overlapping and synchronous
formation of various structures may have occurred (overlapping of phases 1
and 2 in Table 1), at least locally (except for the late-stage main San
Andreas fault and related shear folds; phase 3 in Table 1). The overlapping
and synchronous formation of structures is based on uncertainties in our
field data, e.g., variable cross-cutting relations of early
bedding-parallel strike-slip and thrust faults and en echelon macro-folds (Figs. 4,
6, and S5c–d and S7), and also based on the spatial variations in the
direction of maximum horizontal stress across the Indio Hills at present,
from 40
Our observations of mostly lateral movement along the main San Andreas fault (i.e., southeastern continuation of the Mission Creek fault) and the proposed late Pleistocene to present-day age for deformation in the southeastern Indio Hills are consistent with work by Keller et al. (1982). A major difference between the northwestern and southeastern Indio Hills is the relatively tighter macro-folding over a narrower area and more intense character of deformation in between the two bounding faults in the southeastern Indio Hills (Figs. 2 and 3; Keller et al., 1982; Lancaster et al., 2012).
The right-lateral-reverse character of the Indio Hills fault and its role in
our kinematic model for basin inversion in the southern Indio Hills are
further supported by the relationship of the Indio Hills fault with the
eastern California shear zone, which merge together north of the study area
where the Indio Hills fault bends into a NNW–SSE strike along the
Landers–Mojave Line (Dokka and Travis, 1990a, b; Nur et al., 1993a,
b; Thatcher et al., 2016). Recent activity along the Landers–Mojave
Line recorded as six–seven earthquakes with
Farther southeast along strike, the Indio Hills and main San Andreas faults
merge along a dextral freeway junction, i.e., a junction of three dextral
fault branches (sensu Platt and Passchier, 2016, and Passchier and Platt,
2017), which may have enhanced wedge-shaped transpressional uplift of the
Indio Hills after the late formation of the main San Andreas fault in the
late Pleistocene (Fig. 8a–c and Table 1). However, counterclockwise rotation
of the Indio Hills block and related structures in map view as predicted in
a dextral freeway junction (Platt and Passchier, 2016; Passchier and Platt,
2017) were not recorded by our field data (except along the main San Andreas
fault due to localized right-slip along the fault; see sub-vertical shear
fold in Fig. 5). This may be due in part to the late formation of the main
San Andreas fault (
Kinematic evolution, timing, and along-strike correlation of the
Indio Hills, Mecca Hills, and Durmid Hills uplift domains and bounding
master faults in the Coachella Valley, southern California. We present a
progressive kinematic evolution from
The proposed progressive tectonic model for the Indio Hills uplift has wide implications when compared and correlated with other fault strands of the SAFZ bounding uplifted domains along strike in the Coachella and Imperial valleys (Fig. 8a–c) and in explaining lateral variations in fault architectures, kinematic evolution and timing, deformation mechanisms, and areal segmentation (Sylvester and Smith, 1987; McNabb et al., 2017; Janecke et al., 2018; Bergh et al., 2019). Here we compare and contrast the structural evolution of the southeastern Indio Hills with that of nearby tectonic uplifts (Mecca Hills and Durmid Hills).
Previous studies of SAFZ-related uplifts between the Indio Hills and Durmid Hills in Coachella Valley suggest that the Indio Hills and main San Andreas faults link up in the southeasternmost Indio Hills and proceed as the main San Andreas fault in the Mecca Hills (Fig. 8c), which then, together with the subsidiary Skeleton Canyon and Painted Canyon faults, bound a much wider flower-like uplift area than in the Indio Hills (Fig. 8c; Sylvester and Smith, 1976, 1987; Sylvester, 1988; McNabb et al., 2017; Bergh et al., 2019). In contrast to the Indio Hills fault, however, the main San Andreas fault in Mecca Hills has an anastomosing geometry with thick (10–500 m) red-stained fault gouge. Regardless, we consider these faults to be correlative and infer the lack of fault gouge along the Indio Hills fault to be due to more localized strain on the Indio Hills fault than on the SAFZ in Mecca Hills. This is supported by a more rectilinear geometry and lack of fold–fault linkage in Indio Hills, which may have allowed initial lubrication of the fault surface in basement rocks with high contrasting rheology (e.g., Di Toro et al., 2011; Fagereng and Beall, 2021), and which hampered fluid circulation and extensive cataclasis. Another possible explanation may be the presence of coarse-grained deposits of the Mecca Formation, which may have partitioned/decoupled deformation along the Indio Hills fault from that in overlying Palm Spring sedimentary strata.
Both the Indio Hills and Mecca Hills uplift areas are bounded to the northeast by a presumed Miocene–Pliocene SW-dipping normal fault (Fig. 8a), which later acted as major SAFZ-parallel oblique-reverse faults and which significantly contributed to the uplift of these areas in (late) Pleistocene time (Sylvester and Smith, 1976, 1987; McNabb et al., 2017; Bergh et al., 2019). In the Mecca Hills (Fig. 8c), the Painted Canyon fault is flanked in the hanging wall to the southwest by a basement-cored, macro-fold (Mecca anticline), which is similar to the upright anticline that parallels the Indio Hills fault and adjacent minor thrust faults (Figs. 2, 3c, and S5a). Similar folds appear adjacent to the Hidden Springs–Grotto Hills fault (Sheridan et al., 1994; Nicholson et al., 2010), a NW–SE-striking, now reverse splay fault of the main SAFZ between the Mecca Hills and Durmid Hills (Fig. 8c). It is, however, unlikely that these marginal faults link up directly along strike. Rather, they merge or splay with the SAFZ and SAFZ-oblique faults.
The inversion and main uplift history of the Mecca Hills segment of the SAFZ (Bergh et al., 2019) initiated with right-lateral slip on a steep SAFZ, from where SAFZ-oblique en echelon folds and dominantly right-slip faults splayed out in a 1–2 km wide damage zone on either side of the SAFZ (Fig. 8a). The subsidiary Skeleton Canyon fault initiated as a steep right-lateral and SAFZ-parallel strike-slip fault along a small restraining bend (Fig. 8b). Successive lateral shearing reshaped the en echelon folds into steeply plunging folds with axial traces parallel to the SAFZ. The final kinematic stage generated SW-verging fold and thrust structures parallel to the SAFZ (Fig. 8c), which truncated the en echelon folds and the NE-dipping Skeleton Canyon fault. The resulting wedge-like flower structure thus records a polyphase kinematic evolution from distributed, through locally partitioned, to fully partitioned strain (Bergh et al., 2019).
Based on the geometric similarities, we consider that the en echelon macro-folds in both Indio Hills and Mecca Hills formed coevally, but not on the same regional right-lateral fault strand (Fig. 8a). In both areas, the en echelon folds and faults are strongly reworked and tightened into sigmoidal shapes where they merge with the Indio Hills and Skeleton Canyon faults, respectively (Fig. 8b; Bergh et al., 2019), and SAFZ-parallel thrust faults formed early (i.e., prior to macro-folding) both in the Indio Hills (Fig. S5c–d) and in the Mecca Hills (Rymer, 1994), thus supporting continuous, partly partitioned strain field in both areas. Strain partitioning caused major uplift of the Mecca Hills block along the Skeleton Canyon, Painted Canyon, and Hidden Springs–Grotto Hills faults (Fig. 8c), all acting as SAFZ-parallel oblique-slip thrust faults (Sheridan et al., 1994; Bergh et al., 2019). The partitioned right-slip component was partly transferred to the main San Andreas fault in Indio Hills, and/or to an unknown hidden fault southwest of the SAFZ (e.g., in Mecca Hills; Hernandez Flores, 2015; Fuis et al., 2017), possibly the East Shoreline fault (Janecke et al., 2018).
Based on paleomagnetic and structural field studies, uplift of the SAFZ-related Mecca basin started at ca. 2.6–0.76 Ma (i.e., earliest to mid-Pleistocene) with partial and local erosion of the Palm Spring Formation (see lower and upper unconformities in McNabb et al., 2017) and culminated after 0.76 Ma (see unconformity between the uppermost Palm Spring Formation and base of the Ocotillo Formation southwest of the Painted Canyon fault in McNabb et al., 2017), i.e., after deposition of the whole Palm Spring Formation (McNabb et al., 2017; Janecke et al., 2018). Uplift is still ongoing at present (Fattaruso et al., 2014; Janecke et al., 2018). Fault activity and tectonic uplift of the Mecca Hills therefore most likely initiated earlier (earliest Pleistocene) than in the Indio Hills (earliest late Pleistocene; Table 1), where the transition from the lower to the upper member of the Palm Spring Formation is gradual and does not show any major unconformity.
The Durmid ladder structure along the southern 30 km of the SAFZ in
Imperial Valley defines a similar but oppositely merging, 1–3 km wide wedge-shaped uplift as in Indio Hills, bounded by the
right-lateral and reverse East Shoreline fault to the southwest and the main
SAFZ to the northeast (Fig. 8c; Janecke et al., 2018). Internally, the
ladder structure comprises en echelon folds (Babcock, 1974; Bürgmann, 1991) that
merge in a sigmoidal pattern with the main SAF and subsidiary sets of
conjugate SAFZ-parallel right-lateral and SAFZ-oblique E–W-striking
left-slip cross faults, which accommodated clockwise rotation of internal
blocks (Janecke et al., 2018). The en echelon folds formed at a comparable time, i.e.,
A significant difference between the Indio Hills–Mecca Hills and the Durmid Hills, however, is the large number of cross faults in the Durmid ladder structure. Such faults are interpreted as early-stage (ca. 1 Ma – early or mid-Pleistocene), NE–SW-striking, left-lateral faults (Fig. 8a), which were rotated clockwise by progressive right-lateral motion into sigmoidal parallelism with the SAFZ and East Shoreline fault (Fig. 8b–c; Janecke et al., 2018). In contrast, cross faults in Indio Hills are much less common and, where present, probably formed late, but prior to the main San Andreas fault (i.e., in the earliest or middle part of the late Pleistocene). Thus, in the Indio Hills, there is no evidence of clockwise rotation of early-stage cross faults as in the Durmid Hills, but rather clockwise rotation of fold axial traces is common, which may be a first step in the formation of ladder-like fault blocks (e.g., Davis, 1999; Schultz and Balasko, 2003).
A major outcome of the comparison with Durmid Hills is that the wedge-shaped uplift block between the Indio Hills and main San Andreas faults may represent a failed uplift and/or the early stage of formation of a ladder structure. This idea is supported by the presence of similar master faults and structures with comparable kinematics in both the Indio Hills and Durmid Hills, including oblique en echelon macro-folds, strike-slip faults acting as step-over faults, and reverse faults. Younger non-rotated, conjugate cross faults exist in the Indio Hills but not in the Durmid Hills where such faults are more evolved features due to larger strain and more advanced stage of ladder structure formation. From these observations, one should expect to find ladder structures operating at different evolution stages among the many, yet unexplored, uplifts in Coachella Valley.
The Indio Hills fault likely initiated as a SW-dipping, basement-seated normal fault during the opening of the Gulf of California in the mid-Miocene and was later inverted as a right-lateral reverse, oblique-slip fault in the (earliest?–) late Pleistocene due to transpression along the transform plate boundary, whereas the main San Andreas fault initiated probably as a dominantly right-slip fault during the later stages of uplift in the late Pleistocene.
The Indio Hills segment of the SAFZ in Coachella Valley, southern California, evolved as a wedge-shaped uplift block between two major SAFZ-related fault strands, the Indio Hills and main San Andreas faults, which merge in a dextral freeway junction of a transitional nature to the southeast.
Transpressive deformation triggered uplift and inversion of the Indio Hills through a progressive change from distributed en echelon folding to partly partitioned right-slip thrusting. We favor a progressive rather than stepwise model in which the main uplift was related to late shortening at the freeway junction where the Indio Hills and main San Andreas faults merge.
The Indio Hills fault is a splay fault of the SAFZ that merges to the north with the Landers–Mojave Line and contributes to transfer slip from unsuitably oriented faults of the eastern California shear zone to the main San Andreas fault in the southeast.
A significant difference of the Indio Hills from the Durmid Hills is that left-lateral step-over and cross faults in the Durmid Hills rotated subparallel with the mSAF, whereas in Indio Hills, all cross faults are oblique with the SAFZ and, thus, may reflect an earlier stage of a still evolving ladder structure.
The initiation of right-lateral to right-lateral-reverse slip along major SAFZ-parallel faults and the main San Andreas fault in the Coachella Valley is younger towards the northwest (Pliocene in the Durmid Hills, early Pleistocene in the Mecca Hills, and late Pleistocene in the Indio Hills). The onset of uplift, however, appears to be coeval in all tectonic uplifts (late to latest) Pleistocene.
The structural dataset and field photographs used in the present study are
available on DataverseNO (Open Access repository) at
The supplement related to this article is available online at:
All authors contributed to collect structural measurements in the Indio Hills. JBPK wrote the first draft of the manuscript and designed half the figures and Supplement (35 % workload). SGB made major revision to the initial draft and designed half the figures and Supplement (35 % workload). AGS also revised the manuscript and provided major input about the local geology (30 % workload).
The contact author has declared that none of the authors has any competing interests.
Publisher’s note: Copernicus Publications remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
The staff at the University of California–Santa Barbara and San Diego State University provided great hospitality during Steffen G. Bergh's sabbatical leaves in 2011–2012 and 2016–2017 while working with the San Andreas fault. We thank all the persons from these institutions that were involved in this project. The authors thank Arild Andresen (University of Oslo) and Holger Stunitz (UiT) for helpful comments and Jack Brown (San Diego State University) for fieldwork collaboration. Susanne Janecke (Utah State University) and Miles Kenney (Kenney Geoscience) provided fruitful discussion. We thank the reviewers (Jonathan Matti and the anonymous reviewer) for their extended helpful comments on the manuscript.
The present study is part of the CEED (Centre for Earth Evolution and Dynamics) and ARCEx projects (Research Centre for Arctic Petroleum Exploration), which are funded by grants from UiT The Arctic University of Norway in Tromsø and the Research Council of Norway (grant nos. 223272 and 228107) together with eight academic and six industry partners, and part of the ArcTec project funded by the European Union's Horizon 2020 research and innovation program under the Marie Skłodowska-Curie grant (agreement no. 101023439).
This paper was edited by Stefano Tavani and reviewed by Jonathan Matti and one anonymous referee.