Associate Prof. at Shahid Rajaee Teacher Training University, Iran.
Dr. Azam Anaraki Firooz is an Associate Professor of Inorganic Chemistry at Shahid Rajaee Teacher Training University, Tehran, Iran. She specializes in nanochemistry, catalysis, and advanced functional materials. Her prolific academic career includes impactful publications in high-ranking journals such as Applied Catalysis B: Environmental, with an h-index of 18. Dr. Firooz has led research on heterogeneous catalysis, photocatalysis, gas sensors, and fuel cell technologies. A skilled experimentalist, she utilizes advanced synthesis (sol-gel, hydrothermal) and characterization techniques (XRD, TEM, BET, DR-UV/Vis). She has fostered international collaborations and mentored over 30 students. Her work contributes significantly to sustainable energy and environmental remediation solutions. With over a decade of experience, she is recognized for innovation, scientific leadership, and cross-disciplinary teamwork.
Professional Profiles
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Educationπ
Dr. Firooz completed her Ph.D. in Inorganic Chemistry through a joint program between the University of Tehran and Tarbiat Modares University. Her doctoral research focused on the catalytic and sensing functions of SnOβ nanostructures, where she ranked in the top 1% of her class. She also pursued a sabbatical at Nagasaki University in Japan, synthesizing mesoporous MoOβ nanostructures via spray pyrolysis for gas sensing. She earned her M.Sc. from Tarbiat Modares University, working on the synthesis and characterization of N-carbonyl phospho compounds. Her education combined theoretical rigor with hands-on experimental expertise in material synthesis and characterization, forming the basis of her future research in smart catalysts, functional nanomaterials, and energy/environmental applications.
Professional Experience
Dr. Azam Anaraki Firooz has over a decade of academic and research experience. She serves as Associate Professor at Shahid Rajaee University, where she has also held the position of department head for six years. She has taught undergraduate and graduate courses in inorganic chemistry and supervised over 30 theses. As a visiting professor at the University of Twente (Netherlands), she designed and synthesized smart catalysts and collaborated on advanced research projects. She has led numerous experimental studies involving catalyst development, material characterization, and sensor design. Her leadership in research, teaching, and international collaboration highlights her ability to integrate academic excellence with impactful scientific contributions in the fields of energy and environmental science.
Research Focus π
Dr. Firoozβs research focuses on the synthesis and characterization of advanced inorganic and nanostructured materials for applications in catalysis, environmental remediation, and sustainable energy. She designs smart catalysts and functional materials using methods like sol-gel and hydrothermal synthesis. Her work targets heterogeneous and photocatalytic reactions for water purification and gas pollutant breakdown. She also develops gas sensors, fuel cell components, and polymer-graphite hybrid materials. Her lab is equipped with advanced tools such as XRD, TEM, BET, and DR-UV/Vis for material analysis. A key area of her interest is the interface of nanochemistry with energy conversion and sensing technologies, striving to solve environmental challenges through innovative, scalable, and environmentally friendly materials.
Awards and Honorsπ
Dr. Firooz has consistently demonstrated excellence throughout her academic journey. She graduated in the top 1% of her Ph.D. class and was selected for a prestigious research sabbatical at Nagasaki University in Japan. She has published extensively in high-impact journals such as Applied Catalysis B, receiving strong citation metrics (h-index 18) that reflect the influence of her work. Her role as head of the chemistry department and visiting professor at international institutions like the University of Twente also attest to her leadership and recognition. While specific award titles are not mentioned, her accolades include competitive research fellowships, institutional leadership positions, and invitations to collaborate globallyβall of which reinforce her standing as a distinguished and award-worthy researcher.
Conclusion 
Dr. Azam Anaraki Firooz is a highly deserving candidate for the Women Researcher Award. Her research in inorganic and nanochemistry, backed by a solid publication record and international experience, reflects both depth and innovation. She has contributed significantly to environmental sustainability through catalysis and sensor development. While she could benefit from greater commercialization and global stage presence, her academic leadership, mentoring impact, and scientific excellence make her a standout in her field. This award would not only recognize her current achievements but also empower her future endeavors in advancing science and mentoring the next generation of women in STEM.
Publications to Noted
πΏ Green in situ synthesis of sandwich-like W-bridged siligraphene (g-SiC@WC@g-SiC) heterostructure from Saccharum Ravennae gum for ultrahigh-rate photodegradation of acetaminophen
ποΈ Year: 2024 | π Cited by: β | π Photodegradation | π Green Chemistry | π§ͺ Nanomaterials
β‘ Achievement of an efficient oxygen reduction electrocatalyst based on carbon boosted with MnOx/MnCoβOβ with excellent electrocatalytic activity in neutral media
ποΈ Year: 2024 | π Cited by: 2 | π Electrocatalysis | π ORR | π§ͺ Carbon-Based Materials
𧬠Synthesis of Ag and Mn/ZnO nanoparticles using a hydrothermal method β A brief study and their role in the electrocatalytic oxidation of glucose in alkaline media
ποΈ Year: 2023 | π Cited by: 12 | 𧫠Nanoparticles | π Glucose Sensing | βοΈ Hydrothermal Synthesis
π§ Green Synthesis of Nonprecious Metal-Doped Copper Hydroxide Nanoparticles for Construction of a Dopamine Sensor
ποΈ Year: 2021 | π Cited by: 14 | πΏ Green Synthesis | π§ Dopamine Detection | π¬ Biomedical Sensor
π· High electrochemical detection of dopamine based on Cu-doped single-phase hexagonally ZnO plates
ποΈ Year: 2021 | π Cited by: β | β‘ Electrochemical Sensor | π΅ ZnO Nanoplates | π§ͺ Metal Doping
βοΈ The Effect of Different Dopants (Cr, Mn, Fe, Co, Cu, and Ni) on Photocatalytic Properties of ZnO Nanostructures
ποΈ Year: 2020 | π Cited by: β | π§ͺ Photocatalysis | π§ Doping Effect | π± Environmental Nanoscience