J. Samuel Sooter Data-verified
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Researcher
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Biography and Research Information
OverviewAI-generated summary
J. Samuel Sooter's research investigates the dynamics of brain activity, particularly focusing on the concept of criticality in neural systems. His work explores how the brain's complexity relates to states of wakefulness and sleep, utilizing computer simulations and neurological models. Sooter has published on the low-dimensional criticality embedded in high-dimensional awake brain dynamics, examining deviations from criticality during action and deep sleep through a temporal renormalization group approach. His recent publications also address the definition and measurement of proximity to criticality and its prevalence in brain dynamics. Collaborating with researchers from the University of Arkansas at Fayetteville, including Srimoy Chakraborty and Woodrow L. Shew, Sooter has contributed to studies on motor cortex function and emergent critical oscillations in Parkinson's patients. His scholarship metrics include an h-index of 3, with 35 citations across 6 publications.
Metrics
- h-index: 3
- Publications: 6
- Citations: 39
Selected Publications
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Decomposing the modulation of interactions between neuronal populations (2026)
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Emergent critical oscillations in motor cortex of Parkinson's patients (2026)
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Is critical brain dynamics more prevalent than previously thought? (2025)
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Defining and measuring proximity to criticality (2025)
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Cortex deviates from criticality during action and deep sleep: a temporal renormalization group approach (2024)
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Low-dimensional criticality embedded in high-dimensional awake brain dynamics (2024)
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Low dimensional criticality embedded in high dimensional awake brain dynamics (2023)
Collaboration Network
Top Collaborators
- Low-dimensional criticality embedded in high-dimensional awake brain dynamics
- Cortex deviates from criticality during action and deep sleep: a temporal renormalization group approach
- Defining and measuring proximity to criticality
- Low dimensional criticality embedded in high dimensional awake brain dynamics
- Is critical brain dynamics more prevalent than previously thought?
Showing 5 of 6 shared publications
- Low-dimensional criticality embedded in high-dimensional awake brain dynamics
- Cortex deviates from criticality during action and deep sleep: a temporal renormalization group approach
- Low dimensional criticality embedded in high dimensional awake brain dynamics
- Is critical brain dynamics more prevalent than previously thought?
- Cortex deviates from criticality during action and deep sleep: a temporal renormalization group approach
- Defining and measuring proximity to criticality
- Is critical brain dynamics more prevalent than previously thought?
- Emergent critical oscillations in motor cortex of Parkinson’s patients
- Cortex deviates from criticality during action and deep sleep: a temporal renormalization group approach
- Defining and measuring proximity to criticality
- Is critical brain dynamics more prevalent than previously thought?
- Low-dimensional criticality embedded in high-dimensional awake brain dynamics
- Low dimensional criticality embedded in high dimensional awake brain dynamics
- Low-dimensional criticality embedded in high-dimensional awake brain dynamics
- Low dimensional criticality embedded in high dimensional awake brain dynamics
- Defining and measuring proximity to criticality
- Defining and measuring proximity to criticality
- Is critical brain dynamics more prevalent than previously thought?
- Emergent critical oscillations in motor cortex of Parkinson’s patients
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