2020 - Fellow, National Academy of Inventors
His primary areas of study are Composite material, Nanofiber, Fiber, Biomedical engineering and Artificial intelligence. His is doing research in Polymer, Fracture toughness, Fracture mechanics, Flexural strength and Ultimate tensile strength, both of which are found in Composite material. His studies deal with areas such as Nylon 6, Nanoparticle, Drop and Polyacrylonitrile as well as Nanofiber.
His Fiber research incorporates themes from Volume fraction, Porosity, Filtration and Dissolution. His work in the fields of Biomedical engineering, such as Scaffold, Tissue engineering and Vascular graft, overlaps with other areas such as Research areas. The various areas that Behnam Pourdeyhimi examines in his Artificial intelligence study include Computer vision and Pattern recognition.
His primary scientific interests are in Composite material, Fiber, Polymer, Nanofiber and Chemical engineering. His study in Ultimate tensile strength, Nonwoven fabric, Polypropylene, Composite number and Porosity is carried out as part of his studies in Composite material. Ultimate tensile strength and Finite element method are frequently intertwined in his study.
The concepts of his Fiber study are interwoven with issues in Tissue engineering, Work, Extrusion, Polyethylene and Filtration. His study in Nanofiber is interdisciplinary in nature, drawing from both Nylon 6 and Electrospinning. Many of his studies on Chemical engineering apply to Polymer chemistry as well.
Behnam Pourdeyhimi mostly deals with Composite material, Chemical engineering, Polymer, Fiber and Work. His Chemical engineering research is multidisciplinary, incorporating perspectives in Ion, Scientific method and Adsorption. Behnam Pourdeyhimi has included themes like Ultimate tensile strength, Tissue engineering, Polyethylene, Crystallinity and Numerical analysis in his Polymer study.
Behnam Pourdeyhimi works mostly in the field of Ultimate tensile strength, limiting it down to topics relating to Planar and, in certain cases, Composite number. His work deals with themes such as Airflow, Interlocking, Water jet, Polypropylene and Biomedical engineering, which intersect with Fiber. His research integrates issues of Porosity, Mechanics and Viscoelasticity in his study of Work.
His scientific interests lie mostly in Composite material, Electrospinning, Nanofiber, Contact angle and Work. His work is connected to Polystyrene, Microstructure, Toughness, Fibrous layer and Extrusion, as a part of Composite material. Behnam Pourdeyhimi works mostly in the field of Toughness, limiting it down to topics relating to Stiffness and, in certain cases, Polymer, as a part of the same area of interest.
The concepts of his Electrospinning study are interwoven with issues in Fiber, Biomedical engineering, Morphology and Polycaprolactone. The Fiber study combines topics in areas such as Tissue engineering, Airflow, Biomaterial, Tendon and Bending. To a larger extent, Behnam Pourdeyhimi studies Chemical engineering with the aim of understanding Nanofiber.
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Ultrastretchable Fibers with Metallic Conductivity Using a Liquid Metal Alloy Core
Shu Zhu;Ju-Hee So;Robin Mays;Sharvil Desai.
Advanced Functional Materials (2013)
Fabrication of nanofiber meltblown membranes and their filtration properties
Mohammad Abouelreesh Hassan;Bong Yeol Yeom;Arnold Wilkie;Behnam Pourdeyhimi.
Journal of Membrane Science (2013)
Fundamentals and Applications of Micro- and Nanofibers
Alexander L. Yarin;Behnam Pourdeyhimi;Seeram Ramakrishna.
A realistic approach for modeling permeability of fibrous media : 3-D imaging coupled with CFD simulation
S. Jaganathan;H. Vahedi Tafreshi;B. Pourdeyhimi.
Chemical Engineering Science (2008)
MEASURING FIBER ORIENTATION IN NONWOVENS. PART III : FOURIER TRANSFORM
B. Pourdeyhimi;R. Dent;H. Davis.
Textile Research Journal (1997)
A simulation of unsteady-state filtration via nanofiber media at reduced operating pressures
B. Maze;H. Vahedi Tafreshi;Q. Wang;B. Pourdeyhimi.
Journal of Aerosol Science (2007)
Measuring Fiber Orientation in Nonwovens: Part I: Simulation
B. Pourdeyhimi;R. Ramanathan;R. Dent.
Textile Research Journal (1996)
A case study of simulating submicron aerosol filtration via lightweight spun-bonded filter media
Q. Wang;B. Maze;H. Vahedi Tafreshi;B. Pourdeyhimi.
Chemical Engineering Science (2006)
Electrospun composite poly(L-lactic acid)/tricalcium phosphate scaffolds induce proliferation and osteogenic differentiation of human adipose-derived stem cells.
S D McCullen;Y Zhu;S H Bernacki;R J Narayan.
Biomedical Materials (2009)
Sensor device for real-time monitoring of relative movement using capacitive fabric sensors
H. Nagle;Tae-Ho Kang;Carey Merritt;Burcak Karaguzel.
Journal of Engineered Fibers and Fabrics
(Impact Factor: 2)
Materials Science & Engineering A: Structural Materials: Properties, Microstructure and Processing
(Impact Factor: 6.044)
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