Faustyn Recha | Civil Engineering | Academic Achievement in Civil Engineering Award

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Dr. Faustyn Recha | Civil Engineering | Academic Achievement in Civil Engineering Award

Assistant professor at Academy of Silesia, Poland.

Dr. Faustyn Recha, PhD, C.Eng, is a passionate civil engineering researcher and practitioner from Poland 🇵🇱. With expertise in reinforced concrete durability and structural mechanics 🏗️, he merges academic rigor with practical design. He earned his PhD in Civil Engineering and Transport in 2021, focusing on modeling reinforcement corrosion 🧪. Currently, he serves as an Assistant Professor at the Academy of Silesia, where he teaches and conducts innovative research 👨‍🏫. Dr. Recha is the author of over 200 technical designs and multiple scientific publications 📚. He collaborates internationally with institutions in Germany, Slovakia, China, and the USA 🌍. In addition to research, he is involved in structural inspections, prefabrication innovations, and has developed a patented balcony slab connection system 🔧. His career is a blend of science, teaching, and hands-on engineering — continuously pushing boundaries in civil infrastructure 💡.

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Suitability for Academic Achievement in Civil Engineering Award – Dr. Faustyn Recha

Dr. Faustyn Recha exemplifies what this award represents — exceptional academic performance, original research, and meaningful impact on civil engineering education and practice. He demonstrates consistent scholarly excellence, leadership in academic settings, and contributions that merge scientific advancement with industry relevance. From high-level research to real-world design, his career highlights a dedication to elevating civil engineering standards.

Education 

Dr. Faustyn Recha began his academic journey by graduating with distinction from high school in Psary in 2010 🎓. He earned his B.Eng. (2014) and M.Sc. (2015) in Civil Engineering from the Częstochowa University of Technology 🏫, specializing in Building and Engineering Structures 🏗️. Passionate about deeper inquiry, he pursued a PhD at the Silesian University of Technology, completing it in 2021 🧠. His doctoral thesis focused on modeling the degradation of reinforced concrete due to reinforcement corrosion, combining thermomechanical theory and experimental verification 🔬📐. This solid educational foundation underpins his academic and engineering expertise.

Professional Development 

Dr. Recha’s professional journey began in 2015 in a reinforced concrete design studio 🏢. Alongside his doctoral studies from 2016, he gained hands-on experience in design offices and achieved full construction qualifications in 2018 🔧📐. Since 2021, he has served as an Assistant Professor at the Academy of Silesia, teaching subjects such as concrete structures, mechanics, and corrosion science 👨‍🏫. He has also coordinated the Civil Engineering discipline at the academy since 2022 🏛️. Internationally active, Dr. Recha completed scientific internships in Germany 🇩🇪 and Slovakia 🇸🇰, and maintains collaborations with researchers in China and the USA 🌐. His dual role as an academic and practicing engineer bridges research with real-world construction applications. As a designer, he has authored over 200 construction designs, assessments, and structural analyses 🧱🧮. His contributions reflect a dynamic blend of research, education, and professional engineering excellence 💼📊.

Research Focus Area 

Dr. Faustyn Recha’s research primarily focuses on the durability and degradation of reinforced concrete structures under corrosion effects 🏗️⚙️. His work centers around modeling corrosion-induced damage in reinforced concrete elements, with an emphasis on thermomechanical and electrochemical processes 🔬🧪. He has developed advanced numerical models to predict crack propagation and structural degradation using parameters like corrosion current density and volumetric strain tensors 💡📊. Dr. Recha’s studies also include non-invasive diagnostic methods, aiming to estimate corrosion current based on deflection – a significant step in preventive infrastructure maintenance 🛠️. His research is deeply relevant to sustainable construction, extending the life of concrete structures and reducing repair costs 🔍♻️. With collaborations across Europe and Asia 🌍, he bridges scientific theory with structural safety and real-world application, ensuring his research contributes meaningfully to the field of civil engineering infrastructure and materials science 🧱🌐.

Research Skills 

Dr. Recha brings an impressive array of research skills to the civil engineering domain 📘🧪. He excels in numerical modeling, particularly Finite Element Method (FEM) simulations for analyzing stress, deflection, and crack propagation in reinforced concrete elements 💻🔍. He is skilled in experimental verification, having conducted advanced lab testing to correlate corrosion levels with structural behavior ⚗️📏. His work in thermo-mechanical coupling and electrochemical modeling reflects high proficiency in cross-disciplinary research 🔄🧠. Dr. Recha is also proficient in probabilistic simulation methods such as Monte Carlo analysis for assessing model sensitivity under uncertainty 🎲📈. In addition to technical modeling, he demonstrates strong analytical writing, technical reporting, and journal publication skills 📝📚. His ability to integrate theoretical models with real-world applications — including construction diagnostics and structural design — makes him a rare blend of researcher and practitioner ⚙️🏗️. He also actively contributes to academic peer review and interdisciplinary collaborations 🤝🌍.

Awards & Honors

Dr. Faustyn Recha’s dedication to civil engineering has earned him multiple honors and recognitions 🏆. He received a prestigious Rector’s Scholarship from the Silesian University of Technology for academic excellence 🎓🌟. In 2020, he was awarded second place in the poster session for young scientists at the 66th Conference of the Polish Academy of Sciences 🖼️🥈. His achievements also include top placements in the “Modern Engineer” competition organized by the Silesian Chamber of Construction Engineers, securing 4th and 7th places in 2018 and 2019 respectively 🏗️🎯. His growing reputation as a researcher and educator has led to international internship invitations and reviewer roles in scientific journals 📄🌍. In addition, his patent-pending innovation for prefabricated slab connections underlines his contribution to practical engineering and technological advancement ⚙️📑. These awards reflect his consistent pursuit of excellence in both academic and industrial domains.

Publication Top Notes

1. A Cracking Model for Reinforced Concrete Cover Taking Account of the Accumulation of Corrosion Products in the ITZ Layer, and Including Computational and Experimental Verification

  • Authors: T. Krykowski, T. Jaśniok, F. Recha, M. Karolak

  • Journal: Materials, 13(23), Article 5375

  • Year: 2020

  • Citations: 16

  • Summary:
    This paper presents a comprehensive model for simulating the cracking of reinforced concrete (RC) covers, with special attention to the interfacial transition zone (ITZ) between the steel and concrete. It accounts for the accumulation of corrosion products, which induces expansive stresses leading to cracking. Both computational simulations and experimental results are provided, confirming the model’s effectiveness in predicting crack initiation and propagation due to rebar corrosion.

2. The Simulation of Corrosion Degradation of Concrete Specimen in Stationary Heat and Moisture Conditions

  • Authors: F. Recha, T. Jaśniok, T. Krykowski

  • Journal: Architecture, Civil Engineering, Environment, 10(4)

  • Year: 2018

  • Citations: 6

  • Summary:
    This study uses numerical simulations to analyze the degradation of concrete due to corrosion under constant thermal and moisture conditions. The results show how environmental stability influences the rate of corrosion and crack formation. The simulation helps in understanding the long-term performance of RC structures exposed to consistent environmental stressors.

3. Estimation Method of Corrosion Current Density of RC Elements

  • Author: F. Recha

  • Journal: Open Engineering, 13(1), Article 20220430

  • Year: 2023

  • Citations: 4

  • Summary:
    The paper introduces a new method to estimate corrosion current density in RC elements. The method is based on measurable physical parameters and provides a practical tool for engineers to assess corrosion levels without invasive testing. It contributes to better monitoring and prediction of RC degradation.

4.Numerical simulation of the load-bearing capacity decrease of reinforced concrete structure due to reinforcement corrosion

  • Authors: F. Recha, T.J. Krykowski, T. Jaśniok

  • Conference: 15th Int. Conf. on New Trends in Statics and Dynamics of Buildings

  • Year: 2017

  • Citations: 4

  • Summary:
    This conference paper details a numerical study of how reinforcement corrosion reduces the load-bearing capacity of RC structures over time. The simulation includes the progressive loss of cross-section and bond strength, providing insight into long-term structural performance and failure risks due to corrosion.

5.Principles for conducting periodic technical inspections of buildings in terms of safety and use

  • Authors: F. Recha, P. Nagel

  • Journal: BUILDER, 295(2), pp. 12–14

  • Year: 2022

  • Citations: 3

  • Summary:
    A practical article outlining procedures and legal requirements for routine inspections of buildings. It emphasizes safety, usability, and the early detection of degradation phenomena such as corrosion. The paper serves as a guideline for engineers and inspectors to ensure compliance and structural integrity.

6. Application of Interval Analysis to Assess Concrete Cover Degradation in Accelerated Corrosion Tests

  • Authors: F. Recha, K. Yurkova, T. Krykowski

  • Journal: Materials

  • Year: 2023

  • Citations: 2

  • Summary:
    This research explores the use of interval analysis to model and evaluate the degradation of concrete covers during accelerated corrosion testing. The interval approach allows for uncertainty in material properties and measurement data, offering a more robust assessment tool for interpreting test results in corrosion studies.

Conclusion

Dr. Faustyn Recha is an ideal recipient of the Academic Achievement in Civil Engineering Award. His blend of rigorous research, innovative thinking, and educational leadership defines him as a transformative figure in modern civil engineering academia. With a PhD that breaks new ground, significant teaching responsibilities, and global collaboration, Dr. Recha not only achieves academic excellence — he inspires it in others. Recognizing his work would honor a career committed to advancing civil engineering knowledge, resilience, and practice.

Jeba Beula R | Engineering | Best Researcher Award

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Prof. Jeba Beula R | Engineering | Best Researcher Award

Associate Professor at Rathinam College of Arts and Science, India

AUTHOR PROFILE

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SUMMARY

Dr. R. Jeba Beula is an accomplished Associate Professor of Physics at Rathinam College of Arts and Science, Coimbatore, India. With over 16 years of academic and research experience, she specializes in advanced materials for energy applications, including dye-sensitized and perovskite solar cells. A dynamic academic leader, she is actively engaged in curriculum design, student mentorship, and quality assurance initiatives like NAAC and NBA. Dr. Beula is recognized for her significant contributions to nanomaterials research and innovation in photovoltaics.

EDUCATION

Dr. Jeba Beula holds a Ph.D. in Physics from Karunya Institute of Technology and Sciences with a specialization in Dye-Sensitized Solar Cells (DSSC). Her academic path also includes postgraduate degrees focused on multiferroics and material science. With a strong foundation in optics, electronics, and environmental physics, she developed significant skills in experimental physics and device fabrication. Her educational journey is deeply aligned with advanced solar energy applications, leading to impactful contributions in perovskite and thermoelectric research. She combines theoretical learning with hands-on material development and analysis, fostering strong interdisciplinary knowledge applicable to modern scientific challenges.

PROFESSIONAL EXPERIENCE

Dr. Beula began her academic career in 2008 as an Assistant Professor at Karunya Institute of Technology and Sciences, where she served for nearly 16 years. In 2024, she joined Rathinam College of Arts and Science as an Associate Professor. Over the years, she has taught a wide array of subjects in Physics for engineering, science, optometry, and forensic science students. She also played key roles in curriculum development, examination coordination, and accreditation processes. She is experienced in thin-film deposition techniques and integrating technology into pedagogy.

RESEARCH INTEREST

Dr. Jeba Beula’s research focuses on renewable energy materials, particularly third-generation solar cells, including DSSC and perovskite cells. Her work investigates structural and optical modifications of TiO₂-based photoanodes, advanced thin-film fabrication techniques, and thermoelectric energy conversion materials. She also explores hybrid materials, photodegradation, and nanostructured interfaces for enhanced photovoltaic performance. Her goal is to develop high-efficiency, cost-effective devices with environmentally friendly materials. Additionally, she has worked on computational chemistry, surface coatings, and nanocomposites. Her research intersects physics, materials science, and energy engineering, promoting sustainability and technological advancement in green energy solutions.

AWARD AND HONOR

Dr. Jeba Beula has received several prestigious honors, including the Best Researcher Award (2024) in Atomic, Molecular, and Optical Physics. She was selected for the WISE-KIRAN Women in Science Fellowship (2025) and AICTE-ATAL FDP Grant, recognizing her research leadership and academic excellence. She has also been awarded seed funding from Rathinam College and Karunya Institute to support solar energy research. These accolades affirm her impactful contributions to renewable energy science and commitment to advancing women in STEM. Her recognition by national and international agencies underscores her influence in materials research and scientific mentorship.

RESEARCH SKILL

  • Thin Film Fabrication: Skilled in techniques such as spin coating, sol-gel, and hydrothermal synthesis for preparing nanostructured materials.

  • Materials Characterization: Proficient in using tools like XRD, FESEM, UV-Vis spectroscopy, FTIR, and EIS for analyzing structural, optical, and electrical properties of materials.

  • Photovoltaic Device Design: Experienced in assembling and optimizing dye-sensitized and perovskite solar cells for enhanced energy conversion efficiency.

  • Thermoelectric Materials: Competent in the synthesis and analysis of materials for heat-to-electricity conversion.

  • Data Analysis & Simulation: Skilled in software such as Origin, LabVIEW, and MATLAB for data plotting, curve fitting, and simulation of device behavior.

  • Research Writing & Publication: Strong command of scientific writing, peer-review response, and publication in indexed journals (Scopus, WoS).

  • Project Development: Capable of designing research proposals, managing funded projects, and mentoring postgraduates and Ph.D. scholars.

  • Collaborative Research: Adept at interdisciplinary collaboration with academic, industrial, and international research teams.

PUBLICATIONS

1.  Enhanced Charge Transfer and Stability in Heterojunction Perovskite Solar Cells with Optimized Se/CuSe Multi-layer Hole Transport Layer using Physical Vapour Deposition Technique

Authors: HC Bennett, R. Tamilarasi, R. Magesh, R. Nandhakumar, N. Ganesan, RJ Beula, et al.
Journal: Journal of Physics and Chemistry of Solids
Volume/Article ID: 112835
Year: 2025
DOI: [To be added]
Summary: This study demonstrates improved charge transfer and device stability in perovskite solar cells by integrating a Se/CuSe multilayer hole transport layer fabricated using the Physical Vapor Deposition (PVD) technique.

2. Synergistic Effects of Co–Mn Co-doping on the Structural and Optical Properties of TiO₂ Nanospheres: Dual Functions for DSSC Photoanodes and Degradation Photocatalyst

Authors: A. Ashok, T. Raguram, RJ Beula, G. Gopinath, S. Ayyasamy, A. Abiram, et al.
Journal: Journal of Alloys and Compounds
Volume: 1005
Article ID: 176024
Year: 2024
Citations: 7
DOI: [To be added]
Summary: Co–Mn co-doped TiO₂ nanospheres were engineered to act as high-efficiency dual-function materials for dye-sensitized solar cells and photocatalytic pollutant degradation.

3. Structural and Opto-electronic Engineering with ZnS ETL via PVD Technique for Efficient and Durable Heterojunction Perovskite Solar Cells

Authors: HC Bennett, R. Tamilarasi, A. Ashok, F. Joselin, R. Nandhakumar, E. Antony, RJ Beula, et al.
Journal: Optical Materials
Volume: 154
Article ID: 115695
Year: 2024
Citations: 2
DOI: [To be added]
Summary: The work explores ZnS as an electron transport layer deposited via PVD, enhancing the overall performance and long-term stability of perovskite solar cells.

4. Impact of Venomous Agent X (VX) Adsorption on the Structural and Electronic Properties of BN Nanosheet, Nanotube and Nanocage: A DFT-D3 Study

Authors: SPM Paul, D. Parimala Devi, G. Praveena, P. Selvarengan, RJ Beula, et al.
Journal: Journal of Cluster Science
Volume: 35, Issue 5
Pages: 1279–1289
Year: 2024
Citations: 4
DOI: [To be added]
Summary: A theoretical study using dispersion-corrected DFT-D3 to evaluate the potential of BN nanostructures (sheet, tube, cage) as chemical sensors for detecting the toxic VX nerve agent.

5. Polymer/Organic Solar Cells: Progress and Current Status

Authors: L. Vidhya, S. Vinodha, SJ. Pradeeba, RJ Beula
Book Title: Third Generation Photovoltaic Technology: Recent Progress and Future Perspectives
Chapter: 163
Year: 2024
Citations: 1
Publisher: [To be added]
Summary: This book chapter reviews the technological evolution, fabrication techniques, materials, and performance trends of polymer and organic solar cells in the context of third-generation photovoltaics.

CONCLUSION

Dr. R. Jeba Beula is highly suitable for the Best Researcher Award in Engineering or Physical Sciences domains. Her research contributions are innovative, application-oriented, and address critical global challenges in renewable energy and nanomaterials. She demonstrates strong leadership, technical skills, and a commitment to mentoring the next generation of scientists.