Paul C. Millett Source Confirmed

Affiliation confirmed via AI analysis of OpenAlex, ORCID, and web sources.

High Impact

Associate Professor

University of Arkansas at Fayetteville

faculty

34 h-index 111 pubs 3,463 cited

Research Areas

Congenital Heart Disease Studies Fluid Dynamics and Turbulent Flows Computational Drug Discovery Methods Nanoparticles: synthesis and applications Health and Medical Research Impacts Biomedical and Engineering Education Meta-analysis and systematic reviews

Links

ORCID Google Scholar Lab Website

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OverviewAI-generated summary

Paul C. Millett's research investigates the behavior of fluids and materials, with a focus on complex systems and their applications in biomedical contexts. His work includes numerical and computational studies of fluid dynamics, particularly in biological systems. Recent publications explore hemodynamic flow in aortic vessels, the phase behavior of colloidal particles, and the rheology of elastic capsule suspensions. He has also contributed to the understanding of membrane formation processes through phase inversion.

Millett's research extends to nanoscale phenomena, including the photothermal action of gold nanostructures. In the biomedical domain, his work has addressed computational modeling for predicting pressure drop in supravalvar aortic stenosis, particularly in patients with Williams Syndrome, and has examined the sinotubular junction-to-aortic annulus ratio as a determinant of this condition's severity. He collaborates with researchers from the University of Arkansas for Medical Sciences and within the University of Arkansas at Fayetteville, contributing to a network of scientific inquiry.

With a career marked by 111 publications and 3,463 citations, Millett's scholarship has earned him recognition as a highly cited researcher. His h-index stands at 34, reflecting a significant body of work in his fields of study.

Metrics

h-index: 34
Publications: 111
Citations: 3,463

Selected Publications

Oscillatory flow improves hydrodynamic ordering of soft suspensions in rectangular channels (2025) DOI
Numerical study of hemodynamic flow in the aortic vessel of Williams syndrome patient with congenital heart disease (2024) DOI
Order–disorder transitions within deformable particle suspensions in planar Poiseuille flow (2024) DOI
Numerical Study of Hemodynamic Flow in the Aortic Vessel of Williams Syndrome Patient with Congenital Heart Disease (2024) DOI
Numerical Studies of Hemodynamic Flow in the Aortic Vessel of Patients With Congenital Heart Disease (2023) DOI
Rheology and structure of elastic capsule suspensions within rectangular channels (2023) DOI
A Patient-based Computational Model that Predicts Pressure Drop in Supravalvar Aortic Stenosis in Patients with Williams Syndrome (2021) DOI
The Sinotubular Junction-to-Aortic Annulus Ratio as a Determinant of Supravalvar Aortic Stenosis Severity* (2021) DOI
A review on models and simulations of membrane formation via phase inversion processes (2021) DOI
Nanoscale investigation and control of photothermal action of gold nanostructure-coated surfaces (2021) DOI
A Patient-based Computational Model that Predicts Pressure Drop in Supravalvar Aortic Stenosis in Patients with Williams Syndrome (2021) DOI
Numerical study of the phase behavior of rod-like colloidal particles with attractive tips (2021) DOI