John Goff | Experimental methods | Best Researcher Award

Posted on by ScienceFather

Prof. John Goff | Experimental methods | Best Researcher Award

University of Lynchburg | United States

John Eric Goff is a Professor of Physics at the University of Lynchburg, with extensive experience in the field of sports engineering, fluid dynamics, and computational physics. Over the course of his career, he has made significant contributions to the study of aerodynamics in sports, the physics of surfaces, and optics. His academic journey began at Vanderbilt University, where he earned his B.S. in Physics and Mathematics in 1992, followed by an M.S. in Physics and Ph.D. in Physics from Indiana University. His thesis on the photon-drag effect in simple metals set the stage for his further academic pursuits and professional contributions.

๐Ÿ‘จโ€๐ŸŽ“ Profile

Google scholar

Scopus

Orcid

Early Academic Pursuits ๐ŸŽ“

Dr. Goff’s academic path began with a passion for physics and mathematics, which led him to Vanderbilt University for his undergraduate studies. From there, he continued his education at Indiana University, where he completed both his Master’s and Ph.D. His dissertation work focused on the photon-drag effect in simple metals, a topic that would shape much of his future research endeavors. His early academic experiences, including roles as an Associate Instructor and a Physics Instructor, honed his teaching abilities and deepened his understanding of the complexities of condensed matter physics.

Professional Endeavors ๐ŸŒ

Dr. Goff has held notable academic positions at institutions such as Lynchburg College (now University of Lynchburg), where he served as Chair of the Department of Physics and Professor of Physics. His roles also include a Visiting Professorship at the University of Sheffield (UK), allowing him to engage with an international community of scientists and engineers. His research endeavors have spanned several interdisciplinary fields, including sports physics, fluid dynamics, and computational simulations of physical systems. His experience teaching and researching in these diverse areas has made him a prominent figure in the academic and sports engineering communities.

Contributions and Research Focus ๐Ÿ”ฌ

Dr. Goff is best known for his work in the physics of sports, where he investigates the aerodynamics of soccer balls, the physics of cycling, and the design of sports equipment like climbing helmets. His research has led to numerous articles in prestigious journals, including studies on soccer ball aerodynamics and Tour de France modeling. Dr. Goff’s research has practical applications in both engineering and sports performance, and he continues to explore new avenues in fluid dynamics, sports engineering, and numerical simulations. He is also dedicated to mentoring students, helping them bridge the gap between theory and practical application in physics.

Impact and Influence ๐ŸŒŸ

Dr. Goffโ€™s work has had a profound impact on both the academic community and the sports industry. His research on soccer ball flight trajectories, cycling performance modeling, and sports equipment design has influenced the way engineers design and test sports equipment. His contributions to sports engineering education and his advocacy for using numerical modeling in the classroom have reshaped how students approach problem-solving in physics. Through his research articles, teaching, and collaborations, Dr. Goff has established himself as a key figure in the application of physics to real-world sports challenges.

Academic Cites ๐Ÿ“š

Dr. Goff’s work is widely cited in the academic community, with contributions to journals such as the American Journal of Physics, Journal of Sports Engineering and Technology, and European Journal of Physics. His publications on soccer ball aerodynamics, Tour de France modeling, and sports engineering are often referenced by researchers in the field. His citation record attests to his influence in applied physics, particularly in the study of fluid dynamics and sports biomechanics.

Research Skills ๐Ÿ”ง

Dr. Goff possesses a broad set of research skills that include expertise in numerical simulations, fluid dynamics modeling, and computational physics. He is fluent in programming languages such as FORTRAN and Mathematica, as well as Linux systems, making him well-equipped to tackle complex physical simulations. His ability to collaborate across disciplines, combining theoretical insights with practical engineering solutions, has resulted in innovative studies that bridge the gap between physics and sports technology.

Teaching Experience ๐Ÿ“–

With over two decades of teaching experience, Dr. Goff has taught a wide variety of courses at both the undergraduate and graduate levels. His courses span topics from classical mechanics and electromagnetic theory to quantum mechanics and computational physics. He has also developed general education courses like Physics of Sports, helping non-science majors engage with physics in a way that connects to their everyday lives. Dr. Goff is known for his student-centered teaching style, using interactive techniques and real-world examples to foster a deep understanding of complex concepts.

Awards and Honors ๐Ÿ†

Dr. Goffโ€™s contributions to teaching, research, and student mentoring have been recognized with numerous awards, including the James A. Huston Award for Excellence in Scholarship and the Faculty Award for Excellence in Research Mentoring at the University of Lynchburg. He has also been honored with the Sigma Nu Herbert Bruce Award for being an outstanding faculty member, and multiple Frank R. Haig Prizes for best papers from four-year colleges at the American Association of Physics Teachers meetings. These accolades reflect Dr. Goff’s excellence in both academic scholarship and mentorship.

Legacy and Future Contributions ๐Ÿ”ฎ

Dr. Goffโ€™s legacy lies in his innovative teaching methods and his impactful research at the intersection of physics and sports engineering. His continued research will likely focus on improving sports performance modeling and engineering design. Through his research projects with students, his mentorship will shape the next generation of physicists, engineers, and sports scientists. Dr. Goffโ€™s future contributions will undoubtedly advance our understanding of fluid dynamics and its applications to sports technologies, influencing both academic and practical fields for years to come.

ย  Publications Top Notes

The Aerodynamics of New Design Soccer Balls Using a Three-Dimensional Printer

  • Authors: Sungchan Hong, John Eric Goff, Takeshi Asai
    Journal: Applied Sciences
    Year: 2024

Aerodynamic comparisons between Al Rihla and recent World Cup soccer balls

  • Authors: John Eric Goff, Sungchan Hong, Takeshi Asai
    Journal: Proceedings of the Institution of Mechanical Engineers, Part P: Journal of Sports Engineering and Technology
    Year: 2022

Multiple approaches to incorporating scattering states in non-degenerate perturbation theory

  • Authors: John Goff
    Journal: American Journal of Physics
    Year: 2020

Influence of Surface Properties on Soccer Ball Trajectories

  • Authors: John Goff
    Journal: Proceedings
    Year: 2020

Measurements of the Flight Trajectory of a Spinning Soccer Ball and the Magnus Force Acting on It

  • Authors: John Goff
    Journal: Proceedings
    Year: 2020

 

Priyanka Sahu | Experimental methods | Young Scientist Award

Posted on by ScienceFather

Dr. Priyanka Sahu | Experimental methods | Young Scientist Award

Assistant Professor at Rajiv Gandhi University of Knowledge of Technologies-RK Valley (AP-IIIT RK Valley), India

Dr. Priyanka Sahu is an accomplished academic and researcher, currently serving as an Assistant Professor in the Department of Electronics and Communication Engineering at Rajiv Gandhi University of Knowledge Technologies (AP-IIIT), Idupulapaya, Andhra Pradesh. With a solid foundation in Physics and Astronomy (Materials Science), she holds an M.Tech degree from NIT Rourkela and a Ph.D. from IIT Indore. Her research focuses on the development of high entropy alloys and soft magnetic materials, with expertise in experimental methodologies such as sol-gel auto-combustion and mechanical alloying. Dr. Sahu has published numerous high-impact papers, presented at international conferences, and received prestigious accolades like the Best Researcher Award and Best Oral Presentation. She is a passionate educator and an innovative thinker, contributing significantly to both research and academia.

Profile:

Education

Dr. Priyanka Sahu has pursued an impressive academic journey, earning her Ph.D. in Materials Science from the Indian Institute of Technology Indore (IITI) in 2023, where her dissertation focused on developing and characterizing high-entropy soft magnetic alloys. She holds an M.Tech (Research) degree in Physics and Astronomy with a specialization in Materials Science from the National Institute of Technology Rourkela (NITR) in 2017, during which she studied the electrical and magnetic properties of modified strontium hexaferrite. Prior to this, she completed her Bachelor of Engineering in Electronics and Telecommunication at the Government Engineering College Bilaspur in 2014, following a diploma in the same discipline from the Government Polytechnic College Ambikapur in 2011. Throughout her academic journey, Dr. Sahu has consistently maintained high honors and distinctions, showcasing her dedication to research and learning.

 

Professional experience

Dr. Priyanka Sahu has accumulated diverse teaching and research experience. She is currently serving as an Assistant Professor in the Department of Electronics and Communication Engineering at Rajiv Gandhi University of Knowledge Technologies (AP-IIIT), Idupulapaya, Andhra Pradesh, since March 2024. Prior to this, Dr. Sahu worked as a Teaching Assistant and researcher at IIT Indore from 2017 to 2023, during which she handled multiple labs and courses related to physical metallurgy and material science. Her research experience also includes working at NIT Rourkela in a Physics Laboratory. Dr. Sahu has expertise in handling various high-end instruments such as X-ray diffraction (XRD), Scanning Electron Microscopy (SEM), and Differential Scanning Calorimetry (DSC), which are crucial in material characterization. She has also participated in numerous national and international conferences as a presenter and invited speaker, furthering her knowledge and sharing insights into her specialized research areas.

Research focus

Dr. Priyanka Sahu’s research is centered around the development of advanced materials, particularly high-entropy alloys (HEAs), soft magnetic materials, and magnetocaloric materials. Her work explores novel synthesis methods, including mechanical alloying and sol-gel auto-combustion, to develop new materials with superior thermal, magnetic, and electrical properties. Dr. Sahu has extensively studied the microstructural and magnetic behaviors of multi-component alloys, investigating the influence of elements like Si and Mn on phase evolution and magnetic properties. She also focuses on thermodynamic modeling using Redlich-Kister formalism and Miedema’s semi-empirical models for predicting phase formations in these alloys. Her research aims to apply theoretical models to experimental data for better material characterization, especially in high-entropy amorphous alloys. Dr. Sahu’s work is highly interdisciplinary, impacting fields like nanotechnology, metallurgy, and condensed matter physics.

Award and Recognition

Dr. Priyanka Sahu has received numerous accolades throughout her academic and professional career. She was awarded the prestigious “Best Researcher Award” at the 16th edition of International Research Awards in Atomic, Molecular, and Optical Physics in 2024. Her outstanding oral presentation in the “Progress in Metallurgy & Materials (ISPMM-2023)” at IIT Indore earned her a Best Oral Presentation award. Additionally, she secured the 1st runner-up spot in poster presentation during the Research and Industrial Conclave (RIC-2023) at IIT Indore. Dr. Sahu has also received multiple honorariums for her contributions to various programs such as the QIP program at IIT Indore and TEQIP-III in 2018. She was recognized for her early academic excellence with a merit scholarship at Government Polytechnic College Ambikapur, and she ranked 1st in class during her diploma years. These honors reflect her commitment to research and academia.

Publication Top Notes:

  • Synthesis and characterization of hydrogenated novel AlCrFeMnNiW high entropy alloy
    โœ๏ธ SK Dewangan, VK Sharma, P Sahu, V Kumar
    ๐Ÿ“˜ International Journal of Hydrogen Energy, 45(34), 16984-16991, 2020, cited 62 times
  • Investigating the effect of multiple grainโ€“grain interfaces on electric and magnetic properties of [50 wt% BaFe12O19โ€“50 wt% Na0.5Bi0.5TiO3] composite system
    โœ๏ธ R Pattanayak, R Muduli, RK Panda, T Dash, P Sahu, S Raut, S Panigrahi
    ๐Ÿ“˜ Physica B: Condensed Matter, 485, 67-77, 2016, cited 42 times
  • Microstructure and magnetic behavior of FeCoNi (Mnโ€“Si) x (x= 0.5, 0.75, 1.0) high-entropy alloys
    โœ๏ธ P Sahu, S Solanki, S Dewangan, V Kumar
    ๐Ÿ“˜ Journal of Materials Research, 34(5), 829-840, 2019, cited 30 times
  • Dielectric, ferroelectric and impedance spectroscopic studies in TiO2-doped AgNbO3 ceramic
    โœ๏ธ R Muduli, R Pattanayak, S Raut, P Sahu, V Senthil, S Rath, P Kumar, …
    ๐Ÿ“˜ Journal of Alloys and Compounds, 664, 715-725, 2016, cited 21 times
  • Effect of grain size on electric transport and magnetic behavior of strontium hexaferrite (SrFe12O19)
    โœ๏ธ P Sahu, SN Tripathy, R Pattanayak, R Muduli, N Mohapatra, S Panigrahi
    ๐Ÿ“˜ Applied Physics A, 123, 1-10, 2017, cited 15 times
  • Microstructural, magnetic, and geometrical thermodynamic investigation of FeCoNi (MnSi) x (0.0, 0.1, 0.25, 0.5, 0.75, 1.0) high entropy alloys
    โœ๏ธ P Sahu, S Samal, V Kumar
    ๐Ÿ“˜ Materialia, 18, 101133, 2021, cited 7 times
  • Impact of Si and Mg on Microstructural and Magnetic Behavior of Fe-Co-Ni (Mg-Si)x (x = 0.00,0.1,0.2) Multicomponent Alloys
    โœ๏ธ P Sahu, AS Bagri, MD Anoop, M Kumar, V Kumar
    ๐Ÿ“˜ Silicon, 12, 893-902, 2020, cited 7 times
  • Microstructural, magnetic, and geometrical thermodynamic investigation of FeCoNi (MnSi) x (0.0, 0.1, 0.25, 0.5, 0.75, 1.0) high entropy alloys
    โœ๏ธ P Sahu, S Samal, V Kumar
    ๐Ÿ“˜ Materialia, 18, 101133, Patent NO
  • Microstructure, Non-isothermal Crystallization Kinetics and Magnetic Behaviour Study of [FeCoNi100-x(SiMn)x] High Entropy Amorphous Alloys Synthesized by โ€ฆ
    โœ๏ธ P Sahu, S Samal, V Kumar
    ๐Ÿ“˜ Metals and Materials International, 29(9), 2684-2709, 2023, cited 3 times
  • Phase Evolution and Soft Magnetic Behavior of Mechanically Alloyed Feโ€“Coโ€“Ni Medium Entropy Alloy at Different Disk Angular Velocity
    โœ๏ธ P Sahu, S Samal, V Kumar
    ๐Ÿ“˜ Transactions of the Indian Institute of Metals, 76(11), 3065-3078, 2023, cited 2 times
  • Investigation of the structural, electrical, and magnetic behavior of Co3+-Ti4+ doped strontium hexaferrite: validation of measured and theoretical models
    โœ๏ธ P Sahu, PK Sahu, S Panigrahi
    ๐Ÿ“˜ Journal of Materials Science: Materials in Electronics, 35(10), 709, 2024, cited 1 time
  • Influence of Si and Mn on the Phase Formation, Crystallization Kinetics, and Enhanced Magnetic Properties of Mechanically Alloyed NiCoFe(SiMn)x High Entropy โ€ฆ
    โœ๏ธ P Sahu, S Samal, V Kumar
    ๐Ÿ“˜ Silicon, 15(12), 5367-5392, 2023, cited 1 time
  • An assessment of the mechanically alloyed equiatomic FeCoNiMnSi high entropy amorphous alloy for non-isothermal crystallization kinetics and magnetocaloric refrigeration โ€ฆ
    โœ๏ธ P Sahu, S Samal, V Kumar
    ๐Ÿ“˜ Materials Characterization, 216, 114269, 2024

Conclusion

Overall, Dr. Priyanka Sahu is a well-rounded researcher with a solid background in materials science, excellent technical skills, a significant publication record, and previous awards. Her contributions to the field of high entropy alloys and magnetocaloric materials are impressive and impactful. While focusing on securing research funding and pursuing interdisciplinary research could enhance her profile further, she is undoubtedly a deserving candidate for the “Best Researcher Award.”