Video Lecture by Yogesh K Vohra PhD

Dr. Yogesh K. Vohra is a Fellow of the International Association of Advanced Materials (FIAAM) in recognition for his contribution to “Advancement of Materials to Global Excellence.”

Click image below to view video lecture titled Microwave Plasma Chemical Vapor Deposition of Diamond and Novel Superhard Materials.

Dr. Yogesh K Vohra presents a video lecture on Microwave Plasma Chemical Vapor Deposition of Diamond and Novel Superhard Materials

 

New Advanced Materials Characterization Institutional Core

Dr. Paul Baker
Dr. Paul Baker, Director

The Advanced Materials Characterization (AMC) Core has been selected an institutional research core (Director: Dr. Paul Baker and co-Director: Dr. Vinoy Thomas). It will be a part of the fifteen cores that are supported centrally by the office of Vice President for Research. The AMC Core will provide a broad range of services related to the research and development of materials. Our services will cover the analysis of basic properties of materials such as the structure, composition, and hardness. The types of materials to be analyzed include biomaterials, nanomaterials, metals, ceramics, thin films, composite materials, and semiconductors.

Dr. Vinoy Thomas
Dr. Vinoy Thomas, Co-Director

The AMC Core will include the University’s only scanning electron microscope (SEM), which provides high resolution images of surfaces of a broad range of materials, including soft matter (biological samples) and has elemental analysis capability (EDX). The x-ray photoelectron spectrometer (XPS) is a powerful surface analysis (probing depth of only 3-10nm) instrument that provides elemental composition and chemical bonding information with small spot size (minimum 10 micrometers) and surface mapping capability. The multipurpose X-ray diffractometer (XRD) is a state-of-the-art instrument purchased in 2018 that provides information on crystal structure and phase identification, particle size and shape analysis (SAXS), thin film analysis, epitaxial layer analysis, and can be upgraded to include even additional capabilities. The micro-Raman spectrometer is a high-resolution spectrometer that analyzes the vibrational modes of the material to provide information about the molecular structure of a material. The nanoindenter measures the hardness of a material near the surface and can measure polymers and thin films. These materials growth and characterization facilities are being combined and proposed as a single core to provide materials characterization under one managed facility and serve as a catalyst for innovative materials discovery at UAB. One of the key strengths of the core will be the broad support from industry usage as well as the multi-departmental use. This multi-disciplinary approach to characterization of advanced materials is a part of the UAB research mission.

 

Congratulations to Our 2020-21 NASA REU Participants

2020-21 NASA REU – Hybrid Model

In spite of not being able to have a Summer 2020 REU due to COVID-19, NASA REU is moving forward for 2020-21 with REU for a 10 week period beginning October 1, 2020.The following UAB students have been selected to participate in this fascinating hybrid REU model.  We want to recognize and congratulate them.


Rachel Day is a UAB Junior
Major: Physics
Mentor: Dr. Andrei Stanishevsky, Physics

Hannah Blansett is a Junior at UAB
Major: Materials Science & Engineering
Mentor: Dr. Vinoy Thomas, Material Sciences and Engineering

Brita is a UAB Senior
Major: Physics
Mentor: Dr. Cheng-Chien, Physics
Ishmael James
Ishmael is a Senior at UAB
Major: Physics
Mentor: Dr. Ryoichi Kawai, Physics

NSF EPSCoR Seed Grant Funding for UAB Investigators

Dr. Yogesh K. Vohra is pleased to announce that the following collaborative seed grants from UAB were selected for funding by the NSF EPSCoR RII program in Alabama for FY2021. These are collaborative grants between two Alabama institutions that are part of this NSF supported state-wide consortium in plasma science and technology.  https://www.uah.edu/cpu2al

Dr. Aaron Catledge (PI), Awarded Amount $40,000

Aaron Catledge
Dr. Aaron Catledge

Title: Low-temperature plasma as a means to create superhard high-entropy metal diborides via boro-carbothermal reduction

Collaborating Institution: Tuskegee University

Dr. Cheng-Chien Chen (PI), Awarded Amount $40,000

Dr. Cheng-Chien Chen

Tile: Assemble Plasmon and Phonon Polaritons in Atomic-Scale van der Waals Hybrids

Collaborating Institution: Auburn University

Dr. Vineeth Vijayan (PI) and Dr. Vinoy Thomas, Awarded Amount $40,000

Dr. Vineeth Vijayan

Title: Low Temperature Dusty Plasma based Nanoparticles Modified Polymer Scaffolds as Potential Biointerface for Bone Tissues

Collaborating Institution: Alabama State University & Auburn University

 

 

Dr. Masaru Nakanotani (PI, UAH), Awarded Amount, $40,000

Title:Physics of Collisional Shock Waves :Laser Ablation Experiments, Fluid and Fully Kinetic Simulations

Collaborating Institutions: CFDRC & UAB –Dr. Renato Camata

Congratulations to all the PI’s and their collaborators!

NSF EPSCoR Program Harnesses Non-thermal Plasma Processing for Nano-structuring 3D Printed Tissue-Scaffolds: 

Vinoy_Thomas
Dr. Vinoy Thomas, Materials Science and Engineering

A UAB team led by Dr. Vinoy Thomas, Department of Materials Science & Engineering, has surface engineered 3D Printed polymeric soft biomaterial scaffolds by an in-situ robust synthesis of nanoparticles using low temperature dusty plasma.

The proof-of-concept communication published in ACS Applied Nano Materials, reports a rapid and easy method for nanoparticles (SiNp) synthesis from a liquid precursor into dusty plasma and deposition of them onto 3D printed polymer. “Non-thermal plasma has emerged as a viable method for surface engineering soft materials and biomaterials”, says Dr. Vineeth Vijayan, (first author of the publication), “and we have successfully utilized non-thermal plasma for making super-hydrophilic and blood-friendly materials surfaces in our previous publication in Journal of Materials Chemistry”.

As part of the NSF supported EPSCoR collaborative CPU2AL program, the new method we reported has many appealing attributes:

    1. It is a single step greener and cost effective process
    2. The radiofrequency plasma reactor can be an ideal scalable technology for industries to produce and modify the surface of various biomedical scaffolds/devices with SiNp, and
    3. This method can simultaneously modify the 3D printed scaffolds with SiNp for biomedical applications (bone tissue engineering) and also sterilize them.

The future aspects of this present work will deal with (I) functionalization and attachment of SiNp with biochemical moieties by using volatile amino acids in the plasma phase and (II) strategies for preparation titanium dioxide nanoparticles and nanowires via plasma process which in turn could be used for decontaminate corona virus during the current COVID-19 pandemic.