Fact-checked by Grok 2 weeks ago

Principle of lateral continuity

The principle of lateral continuity, also known as Steno's law of lateral continuity, is a foundational concept in stratigraphy that posits sedimentary rock layers originally extend horizontally in all directions from their point of deposition, forming continuous sheets until they thin to a feather edge, terminate against a depositional barrier, or are interrupted by basin margins.^[1] This principle assumes that any observed discontinuities in rock layers result from later geological processes such as erosion, faulting, or folding, rather than the initial depositional conditions.^[2] Formulated by Danish anatomist and geologist Nicolaus Steno in his 1669 treatise De solido intra solidum naturaliter contento dissertationis prodromus, the principle emerged from Steno's observations of rock formations in Tuscany, Italy, where he noted how strata appeared to be truncated by valleys or cliffs but were likely once connected.^[1] Alongside Steno's other principles—such as superposition (younger layers overlie older ones) and original horizontality (sediments deposit in horizontal layers)—lateral continuity provided early insights into the sequential formation of Earth's crust, challenging prevailing views of rocks as static or divinely created.^[2] Steno's work laid the groundwork for modern geology by emphasizing empirical observation and uniformitarian processes in interpreting rock histories.^[1] In geological practice, the principle enables correlation of rock units across vast distances, aiding in the reconstruction of ancient depositional environments and basin geometries.^[3] For instance, geologists use it to match laterally equivalent strata separated by erosional features, such as river valleys, inferring that these layers were once continuous before uplift or incision occurred.^[2] It also highlights sedimentary facies changes, where grain size or composition varies laterally (e.g., coarser sands near shorelines grading to finer muds offshore), revealing details about sediment transport and energy gradients during deposition.^[3] While applicable primarily to sedimentary rocks, the principle informs broader applications in resource exploration, such as identifying oil-bearing reservoirs that extend laterally within sedimentary basins.^[2]

Definition and Principles

Core Statement

The principle of lateral continuity states that sedimentary layers originally extend laterally in all directions, forming continuous sheets until they thin to a feather edge or abut a depositional barrier, such as a basin margin.^[4]^[5] This foundational stratigraphic concept assumes that deposition occurs under relatively uniform conditions across the basin, ensuring initial continuity before tectonic disruptions or erosion alter the layers.^[6] Originally formulated by Nicolaus Steno in 1669 as one of three key principles in his De solido intra solidum naturaliter contento, the principle underpins the interpretation of rock sequences by emphasizing their pre-disruption extent.^[7]^[8] In ideal cross-sectional diagrams, the principle is depicted through horizontal, unbroken bedding planes that traverse the entire section, highlighting the uniform lateral spread of strata in their depositional state.^[9]^[5]

Relation to Sedimentary Processes

The principle of lateral continuity arises from the horizontal spreading of sediments during deposition in various environments, where particles settle out from transporting agents like water or wind to form extensive, sheet-like layers across sedimentary basins. In fluvial settings, rivers deposit clastic sediments such as silts and sands across floodplains during overbank flooding, creating laterally continuous sheets that can extend tens of kilometers perpendicular to the channel, as observed in modern systems like the Mississippi River alluvial plain. Marine environments facilitate even broader continuity, with ocean currents distributing fine-grained clastics and biogenic materials like carbonate shells over continental shelves, forming uniform layers that span hundreds of kilometers until reaching basin margins. Aeolian processes similarly produce continuous dune sands in desert basins, where wind transports grains horizontally until energy diminishes.^[10]^[11] This lateral extension applies to diverse sediment types, including clastic deposits from mechanical weathering and erosion, chemical precipitates like evaporites in restricted basins, and biogenic accumulations such as limestone from marine organisms. For instance, clastic floodplain silts in alluvial systems often maintain continuity over 10-50 kilometers laterally before thinning, reflecting steady sediment input from upstream sources. Chemical sediments, such as gypsum layers in sabkha environments, form planar sheets across arid coastal basins due to evaporation gradients, extending uniformly until salinity or topography changes. Biogenic deposits, like chalk formed from planktonic foraminifera, exhibit remarkable lateral persistence, as seen in Cretaceous strata spanning the Anglo-Paris Basin over 200 kilometers. These processes contrast with non-sedimentary rocks, where igneous intrusions or metamorphic foliation lack the initial horizontal bedding characteristic of sedimentation.^[12]^[4] Several factors influence the degree of continuity, primarily basin geometry, which defines the depositional limits where layers thin or pinch out against barriers like faults or paleotopography. Sediment supply rates determine layer thickness and extent; high rates from proximal sources promote thicker, more continuous sheets, while low rates lead to rapid lateral thinning. Subsidence plays a critical role by creating accommodation space, allowing ongoing deposition to maintain horizontality, but differential subsidence can cause subtle thickening variations without disrupting overall continuity. In steady-state conditions, where supply balances subsidence and basin infilling, sediments form planar bedding with minimal vertical aggradation, underscoring the principle's reliance on equilibrium depositional dynamics.^[13]

Historical Development

Nicolaus Steno's Contribution

Nicolaus Steno, originally Niels Steensen, was a Danish anatomist and natural philosopher who transitioned into geological studies after relocating to Italy in the 1660s. Born in Copenhagen in 1638, Steno initially gained prominence for his anatomical dissections, including a notable 1667 examination of a shark's head in Livorno, which sparked his interest in fossils and rock formations.^[14] Between 1666 and 1669, while based in Florence under the patronage of the Medici family, he conducted extensive field observations of sedimentary strata in Tuscany, mapping layered rocks and marine remnants in inland settings.^[15] These investigations, centered around areas like Volterra and the Arno Valley, provided the empirical foundation for his geological insights. In his seminal 1669 publication, De solido intra solidum naturaliter contento dissertationis prodromus, published in Florence, Steno articulated the principle of lateral continuity as one of three foundational stratigraphic concepts, alongside the principles of superposition and original horizontality.^[1] This Latin treatise, intended as a preliminary discourse to a larger unfinished work, drew directly from his Tuscan fieldwork to argue that sedimentary layers originally extended continuously across the Earth's surface until interrupted by barriers or erosion.^[7] Steno illustrated this with diagrams of strata, emphasizing how uniform depositional processes formed broad, uninterrupted sheets of sediment. Steno's evidence for lateral continuity stemmed from his studies of marine fossils embedded in inland strata, which he interpreted as remnants of vast, continuous ancient seabeds.^[1] In Tuscany, he documented shells and other marine organisms preserved in hilltop rocks far from modern coasts, such as those near Volterra, concluding that these deposits had once spanned wide areas before tectonic or erosional forces altered their extent. For instance, he noted fossilized shells in layered stones, suggesting sedimentation in a submerged landscape that covered much of the region. These observations challenged contemporary views that fossils formed spontaneously within rocks, instead supporting a historical sequence of marine inundations.^[7] Steno's work marked an intellectual shift from strictly biblical interpretations of Earth's history—such as the catastrophic Noachian flood as the sole explanation for geological features—to a more empirical approach grounded in direct observation. In an era dominated by Archbishop James Ussher's timeline placing creation at 4004 BCE, Steno reconciled his findings with scripture by proposing phased geological events, including a deluge, but prioritized measurable evidence over dogmatic assumptions.^[7] This methodological innovation, though still framed within a young-Earth paradigm, laid the groundwork for modern stratigraphy by demonstrating how strata could reveal a dynamic, sequential history independent of theological constraints.^[1]

Evolution in 19th-Century Geology

In the early 19th century, English canal engineer and geologist William Smith (1769–1839) significantly advanced the application of the principle of lateral continuity through his pioneering work in biostratigraphic mapping. Observing strata during canal excavations across Britain, Smith recognized that sedimentary layers extended laterally over wide regions and could be correlated using characteristic fossils, allowing him to construct the first comprehensive geological map of England and Wales in 1815. This map, titled A Delineation of the Strata of England and Wales with Part of Scotland, depicted the lateral distribution of rock units at a scale of 5 miles to the inch, demonstrating how individual strata thinned or terminated at basin edges while maintaining continuity elsewhere.^[16]^[17] Abraham Gottlob Werner's neptunist theory, developed in the late 18th century but influential into the 19th, initially supported the principle by positing that all rocks formed through precipitation from a receding universal ocean, implying uniform lateral deposition across continents. Werner classified rocks into sequential formations—such as Primitive, Transition, and Flötz—each representing global sedimentary layers deposited horizontally over vast extents during distinct stages of ocean retreat. Although later critiqued for overemphasizing aqueous origins and ignoring volcanic processes, neptunism encouraged early geologists to view strata as laterally extensive units rather than purely local phenomena.^[18]^[19] Charles Lyell's Principles of Geology (1830–1833) further integrated and reinforced the principle within his uniformitarian framework, arguing that sedimentary layers formed gradually through ongoing processes like river deposition and marine transgression, extending laterally until environmental changes caused thinning or pinch-out. Lyell critiqued catastrophic interpretations by emphasizing observable modern analogies, such as deltaic sediments spreading across basins, to explain ancient strata continuity without invoking sudden global floods. His work standardized the view of lateral continuity as a key tool for reconstructing Earth's history, influencing subsequent stratigraphic studies.^[20]^[21] Key debates in 19th-century geology centered on reconciling vertical succession (superposition of layers) with lateral extent in defining rock formations, particularly as mapping revealed regional variations. Werner's global, time-transgressive sequences clashed with observations of lithologic and faunal changes over distance, prompting figures like Smith and Lyell to advocate for practical correlations based on both vertical order and horizontal tracing. These discussions resolved toward standardized stratigraphic columns by mid-century, where lateral continuity enabled the integration of local sections into broader frameworks, as seen in the Geological Society of London's emerging classifications.^[22]^[19]

Applications in Stratigraphy

Layer Correlation and Mapping

Layer correlation in stratigraphy relies on the principle of lateral continuity to match rock layers across separated exposures by comparing shared characteristics that indicate original depositional extent. Geologists primarily use lithostratigraphy, which involves identifying similarities in rock type (lithology), such as composition, texture, and sedimentary structures, to correlate layers; biostratigraphy, which matches fossil assemblages indicative of contemporaneous environments; and measurements of layer thickness to confirm continuity despite variations. These methods assume that originally continuous layers can be traced laterally until they thin or terminate at basin margins, enabling the construction of regional correlation charts that link disparate sections.^[23]^[24] Key tools for applying this principle include stratigraphic sections, which are detailed vertical profiles describing lithology, thickness, and fossil content at specific sites, allowing visual alignment of layers across distances. Isopach maps further delineate layer extents by contouring thickness variations, revealing depositional patterns and aiding in the interpolation of missing data between measured points. These techniques facilitate the mapping of layer boundaries and the identification of continuous units over large areas, often integrated with geophysical data for subsurface correlation.^[25]^[26] A primary challenge in layer correlation is accounting for erosional gaps or unconformities, where periods of non-deposition or surface erosion interrupt the record, creating apparent discontinuities that must be reconciled with the assumption of original lateral spread. Geologists address this by recognizing angular or disconformable contacts and using marker beds—distinctive layers like volcanic ash or fossil-rich horizons—to bridge gaps and maintain correlation integrity. Such interruptions require careful integration of multiple criteria to avoid misaligning layers that were once continuous.^[4]^[27] In resource exploration, the principle of lateral continuity is essential for constructing geological timelines in sedimentary basins, particularly for hydrocarbon reservoirs, where it helps predict the lateral extent of porous sandstones or source rocks. For instance, in the San Juan Basin, correlation of continuous Mesozoic strata has guided oil and gas assessments by mapping reservoir continuity across the province, informing drilling strategies and resource estimates. This application underscores how the principle transforms scattered data into coherent basin models for economic geology.^[28]

Identifying Structural Deformations

The principle of lateral continuity posits that sedimentary layers originally extend laterally in all directions until they thin out or terminate, providing a baseline for recognizing post-depositional disruptions.^[29] Deviations from this expected continuity, such as abrupt terminations, lateral offsets, or angular discordances in layer geometry, serve as primary indicators of structural deformation caused by tectonic forces after sediment deposition.^[30] These disruptions signal movement along faults or warping into folds, distinguishing them from depositional edges where layers gradually pinch out.^[29] Common types of structures revealed by such deviations include faults and folds. Normal and reverse faults manifest as sharp truncations or offsets in otherwise continuous layers, where the fault plane cuts across and displaces the strata, indicating brittle deformation under tectonic stress.^[30] Anticlines and synclines appear as undulating or arched beds that deviate from planar continuity, resulting from ductile compression that warps the layers without complete severance.^[29] These structures disrupt the original lateral extent, with faults typically producing vertical or oblique separations and folds creating curved trajectories in the rock sequence. Diagnostic criteria for confirming deformation rely on cross-cutting relationships, where the disrupting feature intersects and alters older layers, establishing relative timing. For instance, if a fault offsets continuous strata or a fold axis bends them, the deformation must postdate deposition, as the layers were initially unbroken and laterally extensive.^[29] This criterion, integrated with lateral continuity, proves the sequence of tectonic events by showing how younger structures modify pre-existing beds.^[30] Quantitative analysis involves measuring deviations in dip and strike from the expected near-horizontal orientation to quantify and date tectonic episodes. Dip, the angle of maximum slope of a bed from horizontal, and strike, the compass direction of the horizontal line on the bed plane, reveal tilting or rotation caused by deformation; higher dip angles often indicate more intense deformation such as folding or fault-related block rotation.^[31] Variations in these measurements across an outcrop, such as abrupt changes in dip angle along a fault trace, allow geologists to map deformation intensity and constrain the timing of tectonic activity relative to layer deposition.^[31]

Illustrative Examples

Classic Outcrop Observations

One of the earliest and most influential applications of the principle of lateral continuity is found in Nicolaus Steno's 17th-century observations of sedimentary strata in Tuscany, Italy. While examining layered rocks in the hilly terrains around Florence and extending into the northern Apennines, Steno noted continuous sequences of strata containing marine fossils, such as shellfish, far inland from the modern Tyrrhenian Sea. These layers, containing marine fossils such as shellfish far inland, which modern geology identifies as ancient marine deposits from various periods including the Miocene, demonstrated how sediment beds originally extended laterally across broad areas until impeded by topographic barriers or depositional limits, rather than forming isolated patches. Steno illustrated this by comparing the strata to layers of sediment settling in a basin, spreading uniformly until reaching an edge, thereby explaining the apparent inland migration of ancient seabeds.^[1] In the 19th century, geologists documented the lateral transitions in Jurassic limestone sequences exposed in the European Alps from deep marine basin centers to shallower marginal environments. Thick, fossil-rich limestones of the Lias and Dogger stages, deposited in the Tethyan seaway, transitioned laterally over tens of kilometers from basinal radiolarites and shales in the central Helvetic zones to platform carbonates on the margins, as seen in outcrops of the Glarus and Aar massifs. These observations, made through direct fieldwork in rugged alpine valleys, highlighted the pre-orogenic continuity of the layers before tectonic folding disrupted their extent during the Alpine orogeny. The consistent lithological and faunal markers across these exposures confirmed the original lateral spread of the sediments during the Jurassic period (approximately 201–145 million years ago). Similarly, classic outcrops of Devonian sandstones in the Appalachian Mountains of eastern North America provided compelling evidence for lateral continuity across structurally complex terrains. In the mid-19th century, geologists traced the lateral equivalence of sandstone units within the Venango Group (Upper Devonian, about 382–359 million years ago) across valleys and ridges from Pennsylvania to West Virginia. These coarse-grained sandstones, representing ancient deltaic and shallow marine deposits, could be followed for over 100 kilometers despite interruptions by erosion and folding, demonstrating their pre-erosional extension as continuous sheets pinching out at basin margins. Such tracing revealed how the layers maintained identifiable characteristics, like cross-bedding and fossil content, underscoring the principle's role in reconstructing the Appalachian foreland basin's depositional history.^[32] Prior to the advent of modern instrumentation, geologists verified lateral continuity through manual observational methods, including detailed field sketching and stratigraphic profiling of outcrops. These techniques, employed since the 18th century, involved drawing precise two- and three-dimensional representations of rock faces to capture layer thicknesses, contacts, and lithological variations across exposed sections. Sketching allowed for the documentation of subtle lateral changes, such as thinning or facies shifts, while profiling—creating measured vertical and horizontal cross-sections—enabled the projection of layer extensions between separated outcrops, confirming continuity without advanced surveying tools. This hands-on approach was essential for building comprehensive maps of strata in remote or dissected landscapes.

Modern Geological Surveys

In modern geological surveys, geophysical methods such as seismic reflection profiling and ground-penetrating radar (GPR) are essential for imaging the subsurface lateral continuity of sedimentary layers in basins. Seismic reflection profiling generates high-resolution images of stratigraphic units, allowing geologists to trace reflector continuity across large areas and identify depositional patterns without direct exposure. For instance, continuous seismic profiling has confirmed the lateral extent of older sediments in hydrogeologic settings, enabling the mapping of basin-wide layers that inform resource exploration. Similarly, GPR provides near-continuous, high-resolution profiles of shallow sedimentary structures, revealing the geometry and lateral variability of facies in environments like fluvial and coastal deposits, as demonstrated in studies of sand-body continuity in river systems and barrier beaches.^[33]^[34]^[35] Global applications of the principle of lateral continuity are prominent in mapping major sedimentary basins for hydrocarbon resources, where it guides the prediction of reservoir extent and seal integrity. In the North Sea, seismic data reveal the great lateral continuity of Triassic sedimentary sequences south of the Mid-North Sea High, including evaporite facies that act as regional seals for hydrocarbons, facilitating cross-border petroleum system assessments. Likewise, in the Permian Basin, the principle underpins surveys of carbonate platforms, where extensive lateral continuity of build-ups and clinoforms—preserved in 3D exposures—supports seismic facies analysis for resource delineation, highlighting the basin's unique scale in carbonate reservoir modeling.^[36]^[37] Integration with geographic information systems (GIS) enhances digital modeling of layer continuity, supporting 3D reconstructions and hazard assessments. GIS platforms process data from digital outcrop models (DOMs) and digital elevation models (DEMs) to project 2D lineaments onto 3D surfaces, interpolating subsurface continuity for stratigraphic and structural interpretations, as seen in modeling fault zones and sedimentary channels in complex terrains. This enables virtual well extraction and volume reconstructions, such as pre-collapse topography in landslide-prone areas, aiding hazard evaluation by quantifying uncertainties in layer extrapolation.^[38] Recent advancements since 2000, including drone (UAV) surveys and satellite data, have expanded verification of lateral continuity in remote regions like Antarctica. Unmanned aerial vehicles equipped with structure-from-motion photogrammetry produce detailed 3D stratigraphic models of outcrops, mapping layer continuity in low-gradient exposures and complementing traditional methods for basin-scale analysis. In Antarctica, the GeoMAP dataset leverages sub-meter satellite imagery (e.g., Landsat mosaics) and LiDAR to compile continent-wide geological maps at 1:250,000 scale, verifying sedimentary exposures and glacial sequences across ice-covered areas through GIS-integrated remote sensing.^[39]^[40]

Connections to Broader Concepts

Comparison with Original Horizontality

The principle of original horizontality, also formulated by Nicolaus Steno in 1669, posits that layers of sediment are deposited in a nearly horizontal orientation under the influence of gravity, resulting in flat-lying strata that may later be tilted or folded due to tectonic forces.^[14] Deviations from this horizontal position thus indicate post-depositional disturbances rather than initial conditions of formation.^[1] In contrast to the principle of lateral continuity, which emphasizes the horizontal extent of sedimentary layers across a depositional basin until they thin out or encounter barriers, original horizontality specifically addresses the initial vertical orientation of those layers during deposition.^[41] While lateral continuity focuses on the widespread, continuous spread of strata to facilitate correlation over distances, horizontality explains why observed inclinations in rock sequences must result from subsequent geological processes, such as uplift or faulting.^[2] These distinctions highlight how horizontality pertains to the geometry in a vertical plane, whereas continuity operates in the horizontal plane. Both principles complement each other by assuming uniform physical conditions during sedimentation—gravity-driven settling for horizontality and fluid dynamics for lateral spread—enabling geologists to reconstruct basin-wide depositional environments and identify disruptions.^[1] Lateral continuity extends the applicability of horizontality by underscoring that layers, once horizontally deposited, originally formed continuous sheets across basins, aiding in the interpretation of fragmented outcrops.^[2] Historically, both principles originated in Steno's De solido intra solidum naturaliter contento dissertationis prodromus (1669), where they formed part of his foundational framework for stratigraphy.^[14]

Integration with Superposition

The principle of superposition, first articulated by Nicolaus Steno in 1669, states that in undisturbed sequences of sedimentary rock layers, the oldest layers are at the bottom and the youngest at the top, reflecting the chronological order of deposition.^[4] This vertical ordering provides a foundational timeline for stratigraphic analysis, allowing geologists to establish relative ages within a single column of strata.^[12] When integrated with the principle of lateral continuity, which posits that sedimentary layers originally extended laterally in all directions until they thinned or terminated, these two concepts enable a more robust reconstruction of geological history across spatial scales.^[42] Lateral continuity facilitates the tracing of individual layers between separated outcrops, while superposition ensures that the relative ages observed in one location apply to correlated layers elsewhere, creating a cohesive stratigraphic framework.^[4] This synergy is particularly valuable in regional mapping, where continuous layers confirm the temporal sequence established by superposition, aiding in the identification of depositional patterns and environmental changes over time.^[12] In practice, geologists apply these principles together to construct conformable stratigraphic series, where laterally continuous beds maintain their superposed order, allowing for the delineation of time-equivalent units without absolute dating.^[42] This combined methodology involves first identifying vertical sequences via superposition, then extending those sequences horizontally using continuity to correlate units across basins, often supplemented by lithologic or fossil markers for precision.^[4] Such approaches underpin sequence stratigraphy, where bounding surfaces and facies transitions are interpreted within this chronological-spatial context to model sea-level fluctuations and sediment supply dynamics.^[42] However, both principles have limitations in complex geological settings, such as overturned folds, thrust faults, or intrusive igneous bodies, where superposition may be inverted and lateral continuity disrupted, necessitating additional criteria like cross-cutting relationships or paleomagnetic data to restore the original sequence.^[4] In these cases, the assumptions of undisturbed deposition fail, and integrated analysis requires careful evaluation of structural deformations to avoid misinterpreting relative ages.^[12] Unconformities further complicate application by indicating erosional gaps that interrupt both vertical order and horizontal extent.^[42]

References

[1]
Nicolaus Steno - NASA Earth Observatory
Jul 20, 2004 · Steno's final principle is the “principle of lateral continuity,” which says that sediment layers spread out until they reach an obstacle ...
[2]
SEPM Strata
### Summary of Principle of Lateral Continuity
[3]
https://geo.libretexts.org/Bookshelves/Geology/Introduction_to_Historical_Geology_(Johnson_et_al.)/09:_Geologic_Time_and_Relative_Dating/9.01:_Lateral_Continuity_Superposition_and_Inclusions
[4]
7 Geologic Time - OpenGeology
Principle of Lateral Continuity: Within a depositional basin, strata are continuous in all directions until they thin out at the edge of that basin.
[5]
9.1: Lateral Continuity, Superposition, and Inclusions
Aug 24, 2024 · The principle of lateral continuity states that layers of sediment initially extend laterally in all directions; in other words, they are laterally continuous.
[6]
The Principle of Lateral Continuity - Geology In
The principle of lateral continuity states that layers of sediment initially extend laterally in all directions; in other words, they are laterally continuous.
[7]
Nicolaus Steno and the problem of deep time - GeoScienceWorld
In De Solido, he laid down the foundations for historical geology in the form of his principles of superposition, original horizontality, and lateral continuity ...
[8]
Steno's Laws or Principles - Geology - ThoughtCo
Aug 24, 2018 · Steno's Principle of Lateral Continuity links identical rocks, explaining the history of separation by events. In 1669, Niels Stensen (1638-1686) ...
[9]
SEPM Strata
The third was the principle of lateral continuity, that layers of sediment are continuous, unless a barrier prevents the sediments from spreading during ...
[10]
https://geo.libretexts.org/Bookshelves/Geology/Book%3A_An_Introduction_to_Geology_(Johnson_Affolter_Inkenbrandt_and_Mosher)/05%3A_Weathering_Erosion_and_Sedimentary_Rocks/5.05%3A_Depositional_Environments
[11]
5 Weathering, Erosion, and Sedimentary Rocks - OpenGeology
Deposition happens when friction and gravity overcome the forces driving sediment transport, allowing sediment to accumulate. Compaction occurs when material ...
[12]
Chapter 1 Concepts of Sedimentary Basins - ScienceDirect
The primary control on sediment accumulation is subsidence (assuming sediment supply) because sediment accumulation without subsidence is vulnerable to ...
[13]
https://www.sciencedirect.com/science/article/pii/S0376736108700852
[14]
The development and evolution of the William Smith 1815 ...
Smith realized that an understanding of the “ordering of strata” was essential in geological mapping, and it was the application of his stratigraphic method ...Missing: lateral continuity
[15]
https://earthobservatory.nasa.gov/features/Steno/steno4.php
[16]
On Sir Charles Lyell's Alleged Distortion of Abraham Gottlob Werner ...
Nov 3, 2023 · However, Werner is now best remembered for his advocacy of the aqueous origin of all rocks that allegedly precipitated from a universal ocean ...Missing: extent | Show results with:extent
[17]
[PDF] 18th and 19th Century Geology Debates about the age of the earth ...
By the mid 1700s, naturalists were broadly convinced that the earth was what they considered to be very old, and that geological strata could be used to set out ...Missing: vertical lateral extent
[18]
The Project Gutenberg eBook of Principles of Geology by Sir ...
The Project Gutenberg EBook of Principles of Geology, by Charles Lyell. This eBook is for the use of anyone anywhere at no cost and with almost no restrictions ...
[19]
Geologic Principles—Uniformitarianism (U.S. National Park Service)
Sep 27, 2018 · Charles Lyell sets forth the uniformitarian argument: processes now visibly acting in the natural world are essentially the same as those that have acted ...Missing: lateral continuity
[20]
A timeline of stratigraphic principles; 19th C-1950
Jul 13, 2020 · This is the second of three posts that look briefly at the development of stratigraphic principles and the characters responsible for them.Missing: debates | Show results with:debates
[21]
Stratigraphic Correlation - an overview | ScienceDirect Topics
Stratigraphic correlation is a tool for identifying strata units and subsequent flow units. Stratigraphic boundaries generally separate rocks belonging to ...
[22]
Principles of stratigraphy and correlation | Intro to Geology Class Notes
Methods of rock unit correlation. Lithostratigraphy is correlation based on the physical characteristics of rock units (lithology, thickness, sedimentary ...
[23]
[PDF] Preliminary Correlation and Isopach Map of Navajo-Aztec-Nugget ...
An isopach map and a series of stratigraphic cross-sections were created to display the lateral and horizontal extent of the correlated formations. The goal was ...
[24]
[PDF] Isopach maps
An isopach map shows the areal variation in the thickness of a stratigraphic unit. To construct an isopach map from borehole logs, one locates.
[25]
Stratigraphic correlation | Research Starters - EBSCO
Stratigraphic correlation is a geological process that establishes the equivalence of age or position of rock layers (strata) found in different locations.
[26]
[PDF] Total Petroleum Systems and Geologic Assessment of ...
... Oil and Gas Resources in the San Juan Basin Province basin assessments. The ... lateral continuity of an accumulation over a large area (Law, 2002 ...
[27]
7.1: Relative Dating - Geosciences LibreTexts
Aug 25, 2025 · Principle of Cross-Cutting Relationships: Deformation events like folds, faults and igneous intrusions that cut across rocks are younger than ...
[28]
19.2 Relative Dating Methods – Physical Geology – H5P Edition
The principle of lateral continuity states that sediments are deposited ... Later deformation may cause the dyke to be pulled apart into small pieces ...
[29]
12.3: Strike and Dip - Geosciences LibreTexts
Sep 10, 2019 · As you think about how rocks have changed through the process of deformation, it is useful to remember how they deposited in the first place.
[30]
Inherited Territories: The Glarus Alps, Knowledge Validation, and ...
Sep 1, 2009 · During the nineteenth century, a genealogy developed connecting two fathers and two sons: Hans Conrad and Arnold Escher, Albert and Arnold Heim.
[31]
[PDF] geology of the lowermost venango group (upper devonian)
Jun 16, 1984 · At almost any given time interval in the Late Devonian of the central Appalachians these five lithosomes can be traced as lateral equivalents.
[32]
[PDF] The (Forgotten?) Art of Geological Field Sketches; #41853 (2016)
Aug 15, 2016 · The use of geological field sketches to illustrate geological concepts dates back almost as far as geology itself.
[33]
[PDF] continuous seismic reflection profiling of hydrogeologic features
The survey results confirmed the lateral continuity of older sediments throughout the study area. These sediment reflectors were easily traced on either ...
[34]
Continuous Seismic Profiling | US EPA
May 27, 2025 · Continuous seismic profiling (CSP) is a waterborne seismic reflection technique that can be employed on a variety of waterbodies.
[35]
An introduction to ground penetrating radar (GPR) in sediments
In sedimentary geology, ground penetrating radar. (GPR) is used primarily for stratigraphic studies where near-continuous, high-resolution profiles aid.
[36]
[PDF] Kimmeridgian Shales Total Petroleum System of the North Sea ...
South of the Mid-. North Sea High, Triassic sedimentary sequences display great lateral continuity and abundant evaporite facies. Bundsandstein. (equivalent ...
[37]
Seismic Expression of Carbonate Platforms - Applied Stratigraphix
So what makes the Permian Basin unique? it is not only the scale and lateral continuity but the well preserved carbonate build-ups, some of which have 3D ...
[38]
[PDF] 3D Digital Geological Models
3D geological models are 3D reconstructions of the sub- surface geology ... ties, the grids were turned into polygon layers with a GIS software, where ...
[39]
3-D stratigraphic mapping using a digital outcrop model derived ...
Oct 2, 2018 · This study suggests that UAV-SfM DOMs can complement traditional field-based methods by providing detailed 3-D views of topographically complex outcrop ...
[40]
A continent-wide detailed geological map dataset of Antarctica
May 18, 2023 · GeoMAP is the first detailed geological map dataset covering all of Antarctica. It depicts 'known geology' of rock exposures rather than 'interpreted' sub-ice ...Missing: continuity | Show results with:continuity
[41]
Nicholas Steno
Thus Steno's principle of original horizontality states that rock layers form in the horizontal position, and any deviations from this position are due to the ...
[42]
CHAPTER 9 (Stratigraphy)
Principle of original lateral continuity: Strata originally extended in all directions until they thinned to zero or terminated against the edges of the ...
[43]
LEONARDO DA VINCI'S AND NICOLAUS STENO'S GEOLOGY
Oct 1, 2021 · Steno has been credited with codifying the first three principles of geology: 'original horizontality', 'original continuity', and ' ...
[44]
Introduction to Sequence Stratigraphy - SEPM Strata
Dec 8, 2017 · principle of superposition recognized that older sedimentary ... lateral continuity proposed contemporaneous layers of sediment are ...