Dr. Faranak Hatami | Computational Chemistry | Best Researcher Award

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Dr. Faranak Hatami | Computational Chemistry | Best Researcher Award

Dr. Faranak Hatami , Computational Chemistry , PhD at University of massachuessetes Lowell, United States

Faranak Hatami (Fara) is a dedicated physicist and researcher specializing in molecular dynamics simulations, machine learning, and nuclear materials science. Currently pursuing her Ph.D. in Physics at the University of Massachusetts Lowell, she focuses on transport property analysis and multi-objective optimization for molecular systems like Tri-Butyl-Phosphate (TBP). Faranak holds two master’s degrees—one in Physics from UMASS Lowell, where she explored force fields for TBP, and another in Nuclear Engineering from Shahid Beheshti University, where she investigated radiation damage in metals. With a robust background in computational physics, AI, and advanced simulation tools, she has authored multiple publications across nuclear materials and computational chemistry. Her teaching experience spans both the U.S. and Iran, reflecting her passion for education. Beyond academia, she completed a research internship at the University of Montreal. Faranak’s work bridges fundamental physics and practical applications, contributing innovative insights to the fields of material science and chemical engineering.

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Summary of Suitability for Award:

Faranak Hatami is a highly suitable candidate for a “Best Researcher Award”. She demonstrates exceptional multidisciplinary expertise spanning physics, molecular dynamics, machine learning, and nuclear materials science. Her Ph.D. work at UMASS Lowell innovatively combines atomic-scale simulations with AI to optimize force field parameters for Tri-Butyl-Phosphate, addressing both fundamental science and practical applications.  She has authored several impactful publications in reputable journals and preprints, covering diverse topics from radiation damage in metals to machine learning models predicting thermodynamic properties. Her research portfolio includes complex computational modeling, multi-objective optimization, and advanced materials analysis. Additionally, Faranak’s teaching record and successful research internship in Canada reflect her commitment to knowledge dissemination and international collaboration. Her ability to merge computational physics with machine learning showcases originality and forward-thinking, key attributes for top research honors. Faranak Hatami embodies the qualities of a best researcher: scientific rigor, innovative thinking, multidisciplinary skillset, and impactful publications. Her contributions significantly advance computational methods in physical sciences and engineering, making her a strong and deserving candidate for a “Best Researcher Award”.

🎓Education:

 Faranak Hatami is completing her Ph.D. in Physics at the University of Massachusetts Lowell (2021–2025), with her thesis focused on transport property analysis and optimization of force field parameters for Tri-Butyl-Phosphate (TBP), combining atomic-scale simulations with machine learning. Prior to this, she earned her M.Sc. in Physics from the same university in 2023, where she conducted a comparative study of force fields for liquid TBP using molecular dynamics. Earlier, she obtained her M.Sc. in Nuclear Engineering from Shahid Beheshti University in Iran (2016), where she examined radiation damage effects on zirconium and iron grain boundaries through simulations. Her academic journey began with a B.S. in Electrical Engineering from Kurdistan University in 2013. Throughout her studies, Faranak has integrated advanced computational methods, AI, and experimental data analysis, building a multidisciplinary foundation that connects physics, materials science, and engineering disciplines.

🏢Work Experience:

Faranak Hatami brings diverse experience across research, teaching, and technical projects. At UMASS Lowell, she serves as a Teaching Assistant in Physics while pursuing her Ph.D., guiding students through complex concepts. Previously, she lectured on Computational Methods and Statistical Methods and Physics courses at Shahid Beheshti University between 2014 and 2018. Her research career includes an internship at the University of Montreal (2019–2021), exploring hydrogen’s effects on iron grain boundaries using the kinetic activation relaxation technique (k-ART). Faranak has led significant academic projects spanning molecular dynamics simulations, multi-objective optimization, and machine learning applications in material science. She has deep expertise in computational tools such as LAMMPS, MCNP, VASP, and Python-based AI frameworks. Her work reflects a unique blend of fundamental physics research, practical problem-solving, and advanced data analysis, contributing to fields like chemical engineering, nuclear materials, and computational modeling.

🏅Awards: 

 Faranak Hatami has built an impressive research portfolio during her academic career, reflected in multiple publications and conference presentations. While specific named awards were not explicitly listed in her profile, her contributions have earned her recognition through invited presentations such as at the AIChE Annual Meeting, showcasing her expertise in molecular dynamics simulations and force field optimization. Completing dual M.Sc. degrees in Physics and Nuclear Engineering highlights her dedication and academic excellence. Her selection as a research intern at the University of Montreal, working on advanced computational studies in materials science, further underscores her capability and esteem in her field. Through her multidisciplinary approach integrating AI, molecular modeling, and nuclear materials science, she stands out as a rising scholar contributing valuable insights to computational physics and chemical engineering. As she advances her Ph.D., she is poised for further accolades in research innovation and scientific community engagement.

🔬Research Focus:

 Faranak Hatami focuses her research on the intersection of molecular dynamics simulations, machine learning, and materials science. Her Ph.D. work centers on analyzing transport properties and optimizing force field parameters for Tri-Butyl-Phosphate (TBP) using multi-objective optimization algorithms like NSGA-II/III. She applies molecular dynamics to predict critical thermodynamic and transport properties, integrating neural networks for parameter tuning. Additionally, she explores AI-based classification of microscopy and atomic-scale images, blending physics with cutting-edge data science. Faranak’s earlier research in nuclear engineering examined radiation damage in metals such as zirconium and nickel, utilizing techniques like climbing image nudged elastic band (CI-NEB) for defect analysis. She’s also investigated hydration free energies, grain boundary behaviors, and primary knock-on atom (PKA) spectra in irradiated materials. Her work bridges computational physics with practical engineering challenges, advancing predictive models and simulation methods to better understand complex molecular and material systems.

Publication Top Notes:

Comparative Analysis of Machine Learning Models for Predicting Viscosity in Tri-n-Butyl Phosphate Mixtures Using Experimental Data

Citations: 6

Quantification of Methane Hydration Energy Through Free Energy Perturbation Method

Comparison of Different Machine Learning Approaches to Predict Viscosity of Tri-n-Butyl Phosphate Mixtures Using Experimental Data

Citations: 3

Properties of Tri-Butyl-Phosphate from Polarizable Force Field MD Simulations

Citations: 1

A Revision of Classical Force Fields for Tri-N-Butyl Phosphate Molecular Dynamics Simulations

Interaction of primary cascades with different atomic grain boundaries in α-Zr: An atomic scale study

Citations: 34

An energetic and kinetic investigation of the role of different atomic grain boundaries in healing radiation damage in nickel

Citations: 31

Dr. Yuntian Xiao | Coordination Chemistry | Best Researcher Award

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Dr. Yuntian Xiao | Coordination Chemistry | Best Researcher Award

Dr. Yuntian Xiao , Tianjin University , China

Yuntian Xiao is a Ph.D. candidate at Tianjin University’s School of Chemical Engineering and Technology, specializing in chemical engineering with a focus on crystallization technology. Guided by Professor Qiuxiang Yin, Xiao’s research emphasizes sustainable pesticide delivery, environmental chemistry, and molecular simulation. His academic journey began with a Bachelor’s degree in Chemical Engineering from Tianjin University of Science and Technology, followed by a Master’s degree in Chemical Engineering at Tianjin University. He has contributed significantly to the fields of cocrystal engineering and agrochemical sustainability, earning numerous accolades such as the National Scholarship and the Tianjin University Major Awards. Xiao has published extensively in top journals like Chem. Eng. J. and Green Chem., showcasing innovations in crystallization and molecular assembly. Proficient in advanced lab techniques and computational tools, Xiao actively engages in research that bridges science and industry, aiming to develop eco-friendly solutions in agriculture and beyond.

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Summary of Suitability for Award:

Yuntian Xiao demonstrates exceptional qualifications that align with the criteria for the “Best Researcher Awards.” As a Ph.D. candidate specializing in chemical engineering at Tianjin University, Xiao has made significant contributions to sustainable agriculture and environmental chemistry through cocrystal engineering and molecular simulation. With 15 high-impact publications in prestigious journals such as Chem. Eng. J. and ACS Appl. Mater. Interfaces, Xiao has advanced innovations in agrochemical delivery systems and crystallization processes. His interdisciplinary research addresses global challenges like environmental sustainability and efficient pesticide usage. Based on his impactful research contributions, proven academic excellence, and innovative approaches to addressing critical environmental issues, Yuntian Xiao is a highly suitable candidate for the “Best Researcher Awards.” His dedication to sustainability and interdisciplinary problem-solving exemplifies the qualities expected of a leading researcher, making him a deserving nominee.

🎓Education:

Yuntian Xiao is pursuing a Ph.D. in Chemical Engineering at Tianjin University’s School of Chemical Engineering and Technology, where he specializes in crystallization technology under the guidance of Professor Qiuxiang Yin. His doctoral research focuses on sustainable agrochemical solutions through cocrystal engineering. Xiao earned his Master’s degree in Chemical Engineering from Tianjin University, working at the National Engineering Research Center of Industry Crystallization Technology under Professor Chuang Xie . During his Master’s program, he deepened his understanding of crystallization processes and molecular simulations. He holds a Bachelor’s degree in Chemical Engineering and Technology from Tianjin University of Science and Technology, where he excelled academically, achieving a GPA of 3.92. His comprehensive curriculum covered subjects like Chemical Thermodynamics, Reaction Engineering, and Phase Diagrams, building a solid foundation in chemical engineering principles. Xiao’s academic journey reflects a commitment to excellence and a passion for advancing sustainable chemical engineering solutions.

🏢Work Experience:

Yuntian Xiao has diverse research experience in crystallization technology and sustainable chemical engineering solutions. His doctoral research includes developing cocrystal engineering strategies for agrochemical delivery, focusing on herbicides with sustained release, reduced leaching, and enhanced efficiency. He has employed molecular simulations to understand these processes at a mechanistic level. Xiao has also contributed to interdisciplinary projects, including the melt crystallization of buty nediol, reactive crystallization of sodium bicarbonate, and cooling crystallization of creatine phosphate sodium. His main responsibilities involved optimizing experimental methods, modeling processes, and analyzing factors influencing industrial crystallization outcomes. Proficient in techniques like PXRD, TGA/DSC, SEM, Raman, and HPLC, Xiao also has advanced computational skills, including MATLAB and Materials Studio. His expertise combines experimental techniques with computational modeling, allowing him to bridge fundamental research with industrial applications. Xiao’s contributions highlight his ability to address real-world challenges in chemical engineering effectively.

🏅Awards: 

Yuntian Xiao has received numerous awards recognizing his academic excellence and research achievements. As a Ph.D. student, he earned the Ph.D. Student Major Award (2021–2022) from Tianjin University for his innovative research in chemical engineering. During his Master’s program, he consistently achieved the Master Student Major Awards (2018–2021) and a Minor Award (2019–2020) for exceptional academic performance and contributions to crystallization research. His undergraduate achievements include the National Scholarship (2017–2018), a prestigious honor awarded for outstanding academic performance and extracurricular involvement. Additionally, Xiao received the Student Major Awards (2015–2018) from Tianjin University of Science and Technology and the Merit Student Award (2015–2016) from Hebei University of Technology. These accolades reflect Xiao’s dedication to excellence and his impactful contributions to chemical engineering research, solidifying his reputation as a top-performing researcher and scholar.

🔬Research Focus:

Yuntian Xiao’s research focuses on sustainable chemical engineering solutions, particularly through cocrystal engineering. His work addresses global challenges in agriculture and environmental chemistry by designing eco-friendly agrochemical delivery systems. By developing novel cocrystals, Xiao aims to achieve sustained-release pesticides and herbicides with reduced environmental leaching and enhanced efficacy. His expertise extends to mechanochemistry and molecular simulations, employing advanced computational tools to predict and optimize crystallization mechanisms. Xiao has also explored solid-state chemistry to enhance the lifecycle efficiency of agrochemicals. His interdisciplinary projects include studies on the crystallization of buty nediol, sodium bicarbonate, and creatine phosphate sodium, demonstrating his ability to translate research into industrial applications. Xiao’s research integrates experimental techniques like PXRD, Raman spectroscopy, and HPLC with computational modeling, ensuring a comprehensive understanding of crystallization processes. His innovative work in sustainable chemical engineering highlights his commitment to addressing pressing environmental and agricultural challenges.

Publication Top Notes:

1. Title: Cocrystals of propylthiouracil and nutraceuticals toward sustained-release: Design, structure analysis, and solid-state characterization
Authors: Y Xiao, L Zhou, H Hao, Y Bao, Q Yin, C Xie
Journal: Crystal Growth & Design
Citations: 47
Year: 2021

2. Title: New salts and cocrystals of pymetrozine with improvements on solubility and humidity stability: Experimental and theoretical study
Authors: D Wu, J Li, Y Xiao, X Ji, C Li, B Zhang, B Hou, L Zhou, C Xie, J Gong, …
Journal: Crystal Growth & Design
Citations: 46
Year: 2021

3. Title: Mechanochemical synthesis of cocrystal: From mechanism to application
Authors: Y Xiao, C Wu, X Hu, K Chen, L Qi, P Cui, L Zhou, Q Yin
Journal: Crystal Growth & Design
Citations: 29
Year: 2023

4. Title: Cocrystal engineering strategy for sustained release and leaching reduction of herbicides: a case study of metamitron
Authors: Y Xiao, C Wu, L Zhou, Q Yin, J Yang
Journal: Green Chemistry
Citations: 24
Year: 2022

5. Title: Pursuing Green and Efficient Agriculture from Molecular Assembly: A Review of Solid-State Forms on Agrochemicals
Authors: Y Xiao, C Wu, P Cui, L Zhou, Q Yin
Journal: Journal of Agricultural and Food Chemistry
Citations: 21
Year: 2023

6. Title: Analysis of solid-liquid equilibrium behavior of highly water-soluble beet herbicide metamitron in thirteen pure solvents using experiments and molecular simulations
Authors: Y Xiao, C Wu, C Zhao, L Qi, Y Bao, L Zhou, Q Yin
Journal: Journal of Molecular Liquids
Citations: 18
Year: 2022

7. Title: Structure analysis and insight into hydrogen bond and van der Waals interactions of etoricoxib cocrystals and cocrystal solvate
Authors: Y Wang, L Wang, F Zhang, N Wang, Y Gao, Y Xiao, Z Wang, Y Bao
Journal: Journal of Molecular Structure
Citations: 16
Year: 2022

8. Title: Comparison Study of KBH4 Spherical Agglomerates Prepared in Different Antisolvents: Mechanisms and Properties
Authors: Z Zhang, L Wang, P Zhao, Y Xiao, H Hao, Y Bao
Journal: Industrial & Engineering Chemistry Research
Citations: 13
Year: 2021

9. Title: Intermolecular interactions and solubility behavior of multicomponent crystal forms of 2,4-D: Design, structure analysis, and solid-state characterization
Authors: L Fang, Y Xiao, C Zhang, Z Gao, S Wu, J Gong, S Rohani
Journal: CrystEngComm
Citations: 13
Year: 2021

10. Title: Enhancing adsorption capacity and herbicidal efficacy of 2,4-D through supramolecular self-assembly: insights from cocrystal engineering to solution chemistry
Authors: Y Xiao, C Wu, P Cui, X Luo, L Zhou, Q Yin
Journal: Chemical Engineering Journal
Citations: 12
Year: 2023

 

 

 

 

 

Dr. samira abozeid | Inorganic Chemistry Award | Best Researcher Award

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Dr. samira abozeid | Inorganic Chemistry Award | Best Researcher Award

Dr. samira abozeid,mansoura university,Egypt

Dr. Samira Abozeid is a dedicated Lecturer and Assistant Professor in the Chemistry Department at Mansoura University, Egypt. With a strong academic background, she earned her Ph.D. in Chemistry from the State University of New York at Buffalo, complemented by an MSc and BSc from Mansoura University. Dr. Abozeid specializes in synthesizing metal complexes for applications in MRI contrast agents and drug delivery systems using innovative nanotechnology. Her commitment to academic excellence is evident through her extensive research contributions, collaborative efforts, and participation in various national and international projects. Additionally, she has been recognized with several awards for her outstanding research and teaching, showcasing her dedication to advancing the field of chemistry and contributing to educational initiatives.

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Summary of Suitability for Award:

Dr. Samira Mohammed Abozeid exemplifies the qualities and achievements that make her a suitable candidate for the “Best Researcher Award.” With a Ph.D. in Chemistry from the State University of New York at Buffalo, she has made significant contributions to the field, particularly in synthesizing metal complexes for MRI contrast agents and drug delivery systems. Her publication record, which includes 18 articles in high-impact journals, underscores her prolific research output and the relevance of her work in advancing medical applications of chemistry.

🎓Education:

Dr. Samira Abozeid holds an impressive academic portfolio. She completed her Bachelor’s and Master’s degrees in Chemistry at Mansoura University, Egypt, where she developed a solid foundation in chemical sciences. Dr. Abozeid then pursued her Ph.D. at the State University of New York at Buffalo, specializing in the synthesis of metal complexes and their applications in medical imaging and drug delivery. Her doctoral research significantly contributed to the understanding of MRI contrast agents, showcasing her capability to conduct high-level research. Throughout her academic journey, she has maintained a focus on integrating theoretical knowledge with practical applications, which has enriched her teaching methodologies and research approach. Dr. Abozeid’s education has equipped her with the skills to excel in both academia and research, fostering a commitment to innovation in chemistry.

🏢Work Experience:

Dr. Samira Abozeid has garnered extensive experience in academia and research throughout her career. Currently serving as a Lecturer and Assistant Professor at both Mansoura University and New Mansoura University, she plays a pivotal role in educating and mentoring students in chemistry. Dr. Abozeid has completed three significant research projects focused on the synthesis and characterization of metal complexes for MRI applications and drug delivery systems. With 18 published articles in esteemed journals and a citation index reflecting her impactful research contributions, she has established herself as a leading figure in her field. Furthermore, she has engaged in consultancy projects related to chemistry and has participated in multiple collaborative research efforts, both nationally and internationally, which have enriched her research perspective and facilitated knowledge exchange. Dr. Abozeid’s commitment to research excellence is complemented by her active involvement in professional memberships and initiatives aimed at bridging academic research with industry applications.

🏅Awards:

Dr. Samira Abozeid has received several prestigious awards and recognitions throughout her academic career. Among her notable accolades is the Egyptian Government Scholarship, which allowed her to pursue her studies at the State University of New York at Buffalo from 2016 to 2018. Additionally, she was honored with the James T. Grey, Jr. Fellowship in Summer 2020, which acknowledges outstanding research contributions. Dr. Abozeid also received the Mattern-Tyler Teaching Award and the Speyer Fellowship in Fall 2020, reflecting her excellence in both teaching and research. In 2023, she was awarded a competitively funded research project at Mansoura University, highlighting her commitment to advancing scientific knowledge. Furthermore, she has been recognized for delivering the Best Specialized Lecture at multiple conferences, showcasing her ability to communicate complex scientific ideas effectively. These honors underline her significant contributions to the field of chemistry and her dedication to academic excellence.

🔬Research Focus:

Dr. Samira Abozeid’s research focuses primarily on the synthesis and application of metal complexes, particularly in the development of MRI contrast agents and drug delivery systems. Her innovative approach involves utilizing nanoparticles and liposomes to enhance the effectiveness and biocompatibility of these complexes. Dr. Abozeid’s work emphasizes the importance of transition metal complexes in medical applications, providing novel insights into their structural properties and potential therapeutic uses. Her ongoing projects include the development of more effective and safer MRI probes, which can significantly improve diagnostic imaging capabilities. Additionally, she collaborates with national and international research groups to explore energy-related applications of metal complexes. Through her research, Dr. Abozeid aims to bridge the gap between chemistry and medicine, contributing to advancements in nanotechnology and its practical implications for healthcare. Her commitment to innovation and excellence continues to shape her contributions to the scientific community.

Publication Top Notes:

  • Two New Inner-Sphere Pt(II) Thiosemicarbazone Schiff Base Complexes Immobilized into Magnetic Nanoparticles: Synthesis, Characterization, and Biological Investigations
  • A Novel Fluorescent Probe Based Imprinted Polymer-Coated Magnetite for the Detection of Imatinib Leukemia Anti-Cancer Drug Traces in Human Plasma Samples
  • Fe(III) T1 MRI Probes Containing Phenolate or Hydroxypyridine-Appended Triamine Chelates and a Coordination Site for Bound Water
    • Citations: 5 citations.
  • Co(II) Complexes of Tetraazamacrocycles Appended with Amide or Hydroxypropyl Groups as ParaCEST Agents
    • Citations: 3 citations.
  • Comparison of Phosphonate, Hydroxypropyl and Carboxylate Pendants in Fe(III) Macrocyclic Complexes as MRI Contrast Agents
    • Citations: 18 citations.

 

 

 

 

Ica Manas-Zloczower | Chemistry | Best Researcher Award

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Prof. Ica Manas-Zloczower | Chemistry| Best Researcher Award

Professor at Case Western Reserve University, United States

Ica Manas-Zloczower is a distinguished university professor at Case Western Reserve University, specializing in macromolecular science and chemical engineering. With a career spanning over four decades, she has made significant contributions to the fields of polymer processing, advanced materials, and energy solutions. Her extensive research and leadership roles have positioned her as a prominent figure in both academia and professional societies.

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Throughout her career, Ica Manas-Zloczower has published numerous research articles in high-impact journals, contributing significantly to the scientific community. Her work is widely cited, reflecting her influence and expertise in polymer science. Metrics such as citation indices and h-index highlight her prolific output and the impact of her research on advancing knowledge in her field.

  • Total Citations: 5,873
  • Total Documents: 236
  • h-index: 43

Education

Ica earned her Doctor of Science from the Technion – Israel Institute of Technology, where she focused on chemical engineering. Her academic journey began at the Polytechnic Institute in Jassy, Romania, where she received both her B.S. and M.S. degrees. This solid educational foundation has underpinned her subsequent achievements in research and teaching.

Research Focus

Her research primarily centers on polymer processing, recycling technologies, and the development of advanced materials. Ica is particularly interested in mechanochemical methods for the recycling of thermosetting polymers and the enhancement of thermomechanical properties of polymer composites. This focus not only addresses critical environmental issues but also pushes the boundaries of material science.

Professional Journey

Ica’s professional journey includes roles as an assistant professor, associate professor, and now as a distinguished university professor at Case Western Reserve University. She has served as the Associate Dean of Faculty Development and has held leadership positions in several professional organizations, including the International Polymer Processing Society. Her academic and administrative roles demonstrate her commitment to fostering growth in engineering education.

Honors & Awards

Ica has received numerous accolades for her teaching, research, and service. Notable honors include the 2017 Society of Plastics Engineers Fred E. Schwab Education Award and the 2012 George S. Whitby Award for Distinguished Teaching and Research. Her recognition as a Fellow of the Society of Plastics Engineers underscores her contributions to the field.

Publications Noted & Contributions

Ica has authored and co-authored a plethora of articles in leading journals, contributing vital research on topics like polymer recycling and mechanical properties of materials. Her editorial roles in several journals further amplify her impact, as she shapes the discourse in polymer science and engineering. Notable publications include works on vitrimerization and thermomechanical properties of polymers, reflecting her innovative research approach.

Improving Performance of TPU by Controlled Crosslinking of Soft Segments

Journal: Polymer Engineering & Science
Publication Date: August 2024
DOI: 10.1002/pen.26826
Contributors: Lucivan P. Barros Junior, Lucio R. de Souza, Rasoul Rahimzadeh, Ica Manas‐Zloczower
This article explores innovative methods to enhance the performance of thermoplastic polyurethane (TPU) by controlling the crosslinking of its soft segments. The findings contribute to optimizing TPU properties for various applications, particularly in areas requiring enhanced mechanical performance and durability.

A Mechanochemical Approach to Recycle Thermosets Containing Carbonate and Thiourethane Linkages

Journal: Polymer
Publication Date: April 2024
DOI: 10.1016/j.polymer.2024.126877
Contributors: Rasoul Rahimzadeh, Yazhe Han, Ica Manas-Zloczower
This research presents a mechanochemical method for recycling thermosetting polymers with carbonate and thiourethane linkages. The study addresses the critical issue of polymer waste, proposing a viable recycling technique that could significantly impact sustainability in polymer usage.

Thermomechanical Performance of Thermoplastic Polyurethane–Poly(tetrafluoroethylene) Fibril Nanocomposites

Journal: ACS Applied Polymer Materials
Publication Date: July 14, 2023
DOI: 10.1021/acsapm.3c00738
Contributors: Maya Pishvar, Mehrad Amirkhosravi, Ica Manas-Zloczower
This article investigates the thermomechanical properties of nanocomposites made from TPU and poly(tetrafluoroethylene) (PTFE) fibrils. The research contributes to the understanding of composite behavior, highlighting the potential for developing advanced materials with superior mechanical properties.

Porous Hydrogels: Present Challenges and Future Opportunities

Journal: Langmuir
Publication Date: February 14, 2023
DOI: 10.1021/acs.langmuir.2c02253
Contributors: Reza Foudazi, Ryan Zowada, Ica Manas-Zloczower, Donald L. Feke
This publication reviews the current challenges in developing porous hydrogels while identifying future research directions. It serves as a comprehensive resource for researchers in the field, fostering innovation in hydrogel applications.

Thermomechanical Properties of Cross-Linked EVA: A Holistic Approach

Journal: ACS Applied Polymer Materials
Publication Date: February 10, 2023
DOI: 10.1021/acsapm.2c01928
Contributors: Kimberly Miller McLoughlin, Amin Jamei Oskouei, Michelle K. Sing, Alireza Bandegi, Sarah Mitchell, Jayme Kennedy, Thomas G. Gray, Ica Manas-Zloczower
This article presents a comprehensive analysis of the thermomechanical properties of cross-linked ethylene-vinyl acetate (EVA). By utilizing a holistic approach, the study enhances understanding of the relationship between processing conditions and material performance.

Research Timeline

Over the years, Ica’s research has evolved, with early work focusing on basic polymer processing principles and later expanding into advanced recycling technologies and material characterization. This timeline illustrates her adaptability and foresight in addressing emerging challenges in materials science, making significant contributions to both academia and industry.

Conclusion

Ica Manas-Zloczower’s career is marked by a dedication to research, teaching, and professional service in the field of macromolecular science and engineering. Her contributions not only advance scientific understanding but also inspire future generations of engineers. As she continues to push the boundaries of polymer science, her legacy will undoubtedly influence the direction of research and education in the field.