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Nicholas (Nick) M Beeler

Nick Beeler is a scientist in the Earthquake Science Center.

Science and Products

map of Alaska area with 2020-2021 earthquakes, showing circles for earthquake locations

External Grants - Overview

The U.S. Geological Survey (USGS) provides support for research that will assist in achieving the goals of the Earthquake Hazards Program. The goal is to mitigate earthquake losses that can occur in many parts of the nation by providing earth science data and assessments essential for land-use planning, engineering design, and emergency preparedness decisions.
By
Natural Hazards Mission Area, Earthquake Hazards Program
External Grants - Overview

External Grants - Overview

The U.S. Geological Survey (USGS) provides support for research that will assist in achieving the goals of the Earthquake Hazards Program. The goal is to mitigate earthquake losses that can occur in many parts of the nation by providing earth science data and assessments essential for land-use planning, engineering design, and emergency preparedness decisions.
Learn More

Slide-hold-slide experiments on Westerly Granite at temperatures up to 250 °C Slide-hold-slide experiments on Westerly Granite at temperatures up to 250 °C

Laboratory slide-hold-slide tests were conducted in a conventional triaxial deformation configuration on 1-inch diameter cylindrical cores of Westerly granite bisected by a sawcut oriented at 30 degrees from vertical. Tests were conducted at a constant confining pressure of 30 MPa with a 10 MPa pore fluid pressure. The pore fluid was deionized water. Experiments were conducted at...
By
Earthquake Hazards Program

Data from the manuscript: Direct evidence for fluid pressure, dilatancy, and compaction affecting slip in isolated faults Data from the manuscript: Direct evidence for fluid pressure, dilatancy, and compaction affecting slip in isolated faults

Earthquake instability occurs as a result of strength loss during sliding on a fault. It has been known for over 50 years that fault compaction or dilatancy may cause significant weakening or strengthening by dramatically changing the fluid pressure trapped in faults. Despite this fundamental importance, we have no real understanding of the exact conditions that lead to compaction or...
By
Earthquake Hazards Program
Filter Total Items: 58

Time-dependent weakening of granite at hydrothermal conditions Time-dependent weakening of granite at hydrothermal conditions

The evolution of a fault's frictional strength during the interseismic period is a critical component of the earthquake cycle, yet there have been relatively few studies that examine the time-dependent evolution of strength at conditions representative of seismogenic depths. Using a simulated fault in Westerly granite, we examined how frictional strength evolves under hydrothermal...
Authors
Tamara Nicole Jeppson, David A. Lockner, Nicholas M. Beeler, Diane E. Moore
By
Natural Hazards Mission Area, Earthquake Hazards Program, Earthquake Science Center

Strength recovery in quartzite is controlled by changes in friction in experiments at hydrothermal conditions up to 200°C Strength recovery in quartzite is controlled by changes in friction in experiments at hydrothermal conditions up to 200°C

The rate of fault zone restrengthening between earthquakes can be influenced by both frictional and cohesive healing processes. Friction is dependent on effective normal stress while cohesion is independent of normal stress, potentially explaining—in part—the lack of depth dependence of earthquake stress drops. Although amenable to laboratory testing, few studies have systematically...
Authors
Tamara Nicole Jeppson, David A. Lockner, Nicholas M. Beeler, Stephen H. Hickman
By
Natural Hazards Mission Area, Earthquake Hazards Program, Earthquake Science Center

Effect of thermal and mechanical processes on hydraulic transmissivity evolution Effect of thermal and mechanical processes on hydraulic transmissivity evolution

Fracture healing is a critical component of enhanced geothermal systems, the earthquake cycle, and induced seismicity. Accordingly, there is significant interest in understanding the process of healing and its effects on fluid transport. The creation, reactivation, and sustainability of fracture networks depend on complex coupling among thermal, hydraulic, mechanical, and chemical...
Authors
Tamara Nicole Jeppson, David A. Lockner, Joshua M. Taron, Diane E. Moore, Brian D. Kilgore, Nicholas M. Beeler, Stephen H. Hickman
By
Natural Hazards Mission Area, Earthquake Hazards Program, Earthquake Science Center, Geology, Minerals, Energy, and Geophysics Science Center

On the scale-dependence of fault surface roughness On the scale-dependence of fault surface roughness

Defining roughness as the ratio of height to length, the standard approach to characterize amplitudes of single fault, joint and fracture surfaces is to measure average height as a function of profile length. Empirically, this roughness depends strongly on scale. The ratio is approximately 0.01 at a few mm but 10× smaller at a few tens of meters. Surfaces are rougher at small scales...
Authors
Nicholas M. Beeler
By
Natural Hazards Mission Area, Earthquake Hazards Program, Earthquake Science Center

Brittle faulting at elevated temperature and vanishing effective stress Brittle faulting at elevated temperature and vanishing effective stress

If brittle fault strength depends only on friction, slip instability is discouraged at low effective normal stress, σ. Stress drop and the critical stiffness necessary for unstable sliding both vanish with σ; small earthquakes cannot occur. Very low σ is inferred in the source region of low-frequency earthquakes (LFEs) on the San Andreas fault (SAF). Moreover, if pore pressure, p, is...
Authors
Nicholas M. Beeler
By
Natural Hazards Mission Area, Earthquake Hazards Program, Earthquake Science Center

The evolution of rock friction is more sensitive to slip than elapsed time, even at near-zero slip rates The evolution of rock friction is more sensitive to slip than elapsed time, even at near-zero slip rates

For many decades, frictional strength increase at low slip rates has been ascribed to time-dependent contact-area growth across the sliding interface. As a result, phenomenological models that correctly predict contact-area growth, as observed in laboratory experiments, have also been widely assumed to be appropriate descriptors of frictional strength evolution. We present experiments...
Authors
Pathikrit Bhattacharyaa, Allan Rubin, Terry Tullis, Nicholas M. Beeler, Keishi Okazaki
By
Natural Hazards Mission Area, Earthquake Hazards Program, Earthquake Science Center

Science and Products

map of Alaska area with 2020-2021 earthquakes, showing circles for earthquake locations

External Grants - Overview

The U.S. Geological Survey (USGS) provides support for research that will assist in achieving the goals of the Earthquake Hazards Program. The goal is to mitigate earthquake losses that can occur in many parts of the nation by providing earth science data and assessments essential for land-use planning, engineering design, and emergency preparedness decisions.
By
Natural Hazards Mission Area, Earthquake Hazards Program
External Grants - Overview

External Grants - Overview

The U.S. Geological Survey (USGS) provides support for research that will assist in achieving the goals of the Earthquake Hazards Program. The goal is to mitigate earthquake losses that can occur in many parts of the nation by providing earth science data and assessments essential for land-use planning, engineering design, and emergency preparedness decisions.
Learn More

Slide-hold-slide experiments on Westerly Granite at temperatures up to 250 °C Slide-hold-slide experiments on Westerly Granite at temperatures up to 250 °C

Laboratory slide-hold-slide tests were conducted in a conventional triaxial deformation configuration on 1-inch diameter cylindrical cores of Westerly granite bisected by a sawcut oriented at 30 degrees from vertical. Tests were conducted at a constant confining pressure of 30 MPa with a 10 MPa pore fluid pressure. The pore fluid was deionized water. Experiments were conducted at...
By
Earthquake Hazards Program

Data from the manuscript: Direct evidence for fluid pressure, dilatancy, and compaction affecting slip in isolated faults Data from the manuscript: Direct evidence for fluid pressure, dilatancy, and compaction affecting slip in isolated faults

Earthquake instability occurs as a result of strength loss during sliding on a fault. It has been known for over 50 years that fault compaction or dilatancy may cause significant weakening or strengthening by dramatically changing the fluid pressure trapped in faults. Despite this fundamental importance, we have no real understanding of the exact conditions that lead to compaction or...
By
Earthquake Hazards Program
Filter Total Items: 58

Time-dependent weakening of granite at hydrothermal conditions Time-dependent weakening of granite at hydrothermal conditions

The evolution of a fault's frictional strength during the interseismic period is a critical component of the earthquake cycle, yet there have been relatively few studies that examine the time-dependent evolution of strength at conditions representative of seismogenic depths. Using a simulated fault in Westerly granite, we examined how frictional strength evolves under hydrothermal...
Authors
Tamara Nicole Jeppson, David A. Lockner, Nicholas M. Beeler, Diane E. Moore
By
Natural Hazards Mission Area, Earthquake Hazards Program, Earthquake Science Center

Strength recovery in quartzite is controlled by changes in friction in experiments at hydrothermal conditions up to 200°C Strength recovery in quartzite is controlled by changes in friction in experiments at hydrothermal conditions up to 200°C

The rate of fault zone restrengthening between earthquakes can be influenced by both frictional and cohesive healing processes. Friction is dependent on effective normal stress while cohesion is independent of normal stress, potentially explaining—in part—the lack of depth dependence of earthquake stress drops. Although amenable to laboratory testing, few studies have systematically...
Authors
Tamara Nicole Jeppson, David A. Lockner, Nicholas M. Beeler, Stephen H. Hickman
By
Natural Hazards Mission Area, Earthquake Hazards Program, Earthquake Science Center

Effect of thermal and mechanical processes on hydraulic transmissivity evolution Effect of thermal and mechanical processes on hydraulic transmissivity evolution

Fracture healing is a critical component of enhanced geothermal systems, the earthquake cycle, and induced seismicity. Accordingly, there is significant interest in understanding the process of healing and its effects on fluid transport. The creation, reactivation, and sustainability of fracture networks depend on complex coupling among thermal, hydraulic, mechanical, and chemical...
Authors
Tamara Nicole Jeppson, David A. Lockner, Joshua M. Taron, Diane E. Moore, Brian D. Kilgore, Nicholas M. Beeler, Stephen H. Hickman
By
Natural Hazards Mission Area, Earthquake Hazards Program, Earthquake Science Center, Geology, Minerals, Energy, and Geophysics Science Center

On the scale-dependence of fault surface roughness On the scale-dependence of fault surface roughness

Defining roughness as the ratio of height to length, the standard approach to characterize amplitudes of single fault, joint and fracture surfaces is to measure average height as a function of profile length. Empirically, this roughness depends strongly on scale. The ratio is approximately 0.01 at a few mm but 10× smaller at a few tens of meters. Surfaces are rougher at small scales...
Authors
Nicholas M. Beeler
By
Natural Hazards Mission Area, Earthquake Hazards Program, Earthquake Science Center

Brittle faulting at elevated temperature and vanishing effective stress Brittle faulting at elevated temperature and vanishing effective stress

If brittle fault strength depends only on friction, slip instability is discouraged at low effective normal stress, σ. Stress drop and the critical stiffness necessary for unstable sliding both vanish with σ; small earthquakes cannot occur. Very low σ is inferred in the source region of low-frequency earthquakes (LFEs) on the San Andreas fault (SAF). Moreover, if pore pressure, p, is...
Authors
Nicholas M. Beeler
By
Natural Hazards Mission Area, Earthquake Hazards Program, Earthquake Science Center

The evolution of rock friction is more sensitive to slip than elapsed time, even at near-zero slip rates The evolution of rock friction is more sensitive to slip than elapsed time, even at near-zero slip rates

For many decades, frictional strength increase at low slip rates has been ascribed to time-dependent contact-area growth across the sliding interface. As a result, phenomenological models that correctly predict contact-area growth, as observed in laboratory experiments, have also been widely assumed to be appropriate descriptors of frictional strength evolution. We present experiments...
Authors
Pathikrit Bhattacharyaa, Allan Rubin, Terry Tullis, Nicholas M. Beeler, Keishi Okazaki
By
Natural Hazards Mission Area, Earthquake Hazards Program, Earthquake Science Center
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