Wenndy Pantoja | Nanotechnology | Innovative Research Award

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Innovative Research Award

Wenndy Pantoja 
Institute of Nanoscience and Materials of Aragon. University of Zaragoza-CSIC , Spain

Wenndy Pantoja
Affiliation Institute of Nanoscience and Materials of Aragon. University of Zaragoza-CSIC
Country Spain
Google Scholar ID ARwN9u4AAAAJ
Citations 53
h-index 3
i10-index 3
Scopus ID 57190880346
Subject Area Nanotechnology
Event New Scientists Awards

Wenndy Pantoja is associated with the Institute of Nanoscience and Materials of Aragon at the University of Zaragoza-CSIC in Spain, contributing to scientific research within the field of Nanotechnology. Her scholarly activities reflect engagement in advanced materials science, nanoscale engineering, and interdisciplinary scientific innovation. Indexed academic metrics and publication visibility demonstrate measurable contributions to contemporary nanoscience research and emerging technological development.[1]

Abstract

This article presents an academic overview of Wenndy Pantoja and her scholarly profile within the field of Nanotechnology. The profile highlights contributions to nanoscience research, interdisciplinary materials innovation, and scientific dissemination through indexed publications and citation visibility. The article further examines research impact indicators, publication activities, and the suitability of the researcher for recognition under the Innovative Research Award category within the New Scientists Awards initiative.[2]

Keywords

Nanotechnology; Nanoscience; Materials Science; Advanced Nanomaterials; Nanoscale Engineering; Scientific Innovation; Interdisciplinary Research; Nanomaterial Applications; Emerging Technologies; Research Impact

Introduction

Nanotechnology is a multidisciplinary scientific field focused on the manipulation and application of materials at the nanoscale level. Research in nanoscience has contributed significantly to innovations in medicine, electronics, environmental technologies, and advanced materials engineering. The integration of nanoscale methodologies continues to influence emerging scientific and industrial developments worldwide.[3]

Within this scientific context, Wenndy Pantoja has participated in research activities associated with advanced materials and nanotechnology innovation. Her academic profile reflects scholarly engagement through indexed scientific publications and measurable citation activity related to nanoscale materials research and interdisciplinary technological development.[1]

Research Profile

Wenndy Pantoja is affiliated with the Institute of Nanoscience and Materials of Aragon at the University of Zaragoza-CSIC in Spain. Her scholarly profile is indexed within international scientific databases and reflects participation in nanotechnology-related research activities. Citation indicators and publication metrics demonstrate measurable engagement within interdisciplinary nanoscience and materials engineering communities.[1]

Research Contributions

The research contributions associated with Wenndy Pantoja involve interdisciplinary nanotechnology investigations and advanced materials research. Scientific activities in this field commonly include nanoscale characterization, nanomaterial synthesis, and technological applications relevant to healthcare, electronics, environmental sustainability, and emerging industrial innovation.[4]

Indexed scientific publications and citation activity further demonstrate engagement with international nanoscience discourse and collaborative research dissemination. The integration of materials science with nanoscale engineering reflects the growing relevance of nanotechnology in addressing complex scientific and technological challenges.[2]

Publications

The publication record of Wenndy Pantoja reflects scholarly participation in nanotechnology and advanced materials research. Scientific outputs indexed in recognized academic databases contribute to ongoing discussions related to nanoscale science, material innovation, and interdisciplinary technological applications.[5]

  1. Research publications associated with nanomaterial synthesis and characterization.
  2. Scientific studies involving nanoscale engineering methodologies and materials innovation.
  3. Interdisciplinary research outputs contributing to emerging nanotechnology applications.
  4. Indexed scholarly articles disseminated through international scientific platforms.

Research Impact

Research impact within nanotechnology is frequently evaluated through publication dissemination, citation performance, interdisciplinary collaboration, and scientific relevance to emerging technological innovation. Wenndy Pantoja’s scholarly profile demonstrates measurable research visibility through indexed publications and citation indicators available within international academic databases.[1]

The increasing significance of nanotechnology within global scientific research highlights the importance of interdisciplinary collaboration and innovative materials engineering. Citation metrics and indexed scientific dissemination collectively indicate academic participation within evolving nanoscience and technological research communities.[3]

Award Suitability

The academic and scientific profile of Wenndy Pantoja aligns with the objectives of research recognition programs focused on interdisciplinary innovation and scientific advancement. Her engagement in nanotechnology-related research, publication dissemination, and scholarly collaboration supports consideration for recognition within international scientific award initiatives.[4]

The Innovative Research Award under the New Scientists Awards framework recognizes researchers contributing to scientific progress through measurable academic activities and emerging technological research. Wenndy Pantoja’s indexed publication profile and citation visibility support suitability within this recognition category.[5]

Conclusion

Wenndy Pantoja has established a measurable academic profile within the field of Nanotechnology through publication dissemination, interdisciplinary scientific engagement, and indexed research visibility.The documented academic indicators collectively support recognition within international scientific award platforms focused on emerging research excellence and interdisciplinary scientific advancement.[1]

References

  1. Elsevier. (n.d.). Scopus author details: Wenndy Pantoja, Author ID 57190880346. Scopus.
    https://www.scopus.com/authid/detail.uri?authorId=57190880346
  2. Google Scholar. (n.d.). Academic citation profile for Wenndy Pantoja.
    https://scholar.google.com/citations?view_op=list_works&hl=en&hl=en&user=ARwN9u4AAAAJ
  3. Nature Nanotechnology. (2020). Advances in nanotechnology and nanoscale materials engineering.
    https://doi.org/10.1038/s41565-020-0649-3
  4. European Commission. (n.d.). Nanotechnology research and innovation initiatives in Europe.
    https://research-and-innovation.ec.europa.eu/
  5. New Scientists Awards. (n.d.). International platform recognizing scientific research excellence and innovation.
    https://newscientists.net/

Jahangeer Khan | Nanotechnology and Materials Science | Research Excellence Award

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Dr. Jahangeer Khan | Nanotechnology and Materials Science | Research Excellence Award

Post Doctoral Researcher (MSCA-Cofund) | Institute of Physics of the Czech Academy of Sciences, Czech Centre for Phenogenomics | Czech Republic

Dr. Jahangeer Khan is an active researcher in advanced materials and next-generation photovoltaic technologies, with a strong focus on metal oxide nanoparticles, quantum dots, perovskite materials, and solution-processable solar cell architectures. His research contributions span nanomaterial synthesis, thin-film engineering, charge transport optimization, and device performance enhancement, resulting in publications in reputable, high-impact journals. He has contributed to peer review and editorial activities and has been involved in collaborative and funded research projects addressing sustainable energy technologies. According to Google Scholar, his research output includes 19 scholarly documents with 2,260 citations, an h-index of 17, and an i10-index of 17, reflecting consistent impact and recognition within the scientific community.

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View Scopus Profile  View ORCID Profile  View Google Scholar  View ResearchGate

Featured Publications

Nelson Etafo | Nanotechnology and Materials Science | Best Scholar Award

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Dr. Nelson Etafo | Nanotechnology and Materials Science | Best Scholar Award

Researcher | Universidad Carolina | Mexico

Dr. Nelson Etafo is an active materials science and environmental technology researcher whose work spans photoluminescence, nanotechnology, catalysis, wastewater remediation, and sustainable materials engineering. With 238 Scopus citations, 24 indexed publications, and an h-index of 7, he has contributed significantly to the advancement of functional materials, luminescent phosphors, and electrocoagulation-based technologies. His research focuses strongly on lanthanide-doped phosphors, solid-state lighting, upconversion materials, and their applications in bioimaging, sensing, anti-counterfeiting, and light-emitting devices. He has developed and analyzed BaLaAlO₄, SrLaAlO₄, and Sr₂CeO₄-based phosphors, contributing new insights into blue, red, and NIR emissions, refractive-index-influenced catalysis, and photoluminescent mechanisms. His work includes advancements in combustion synthesis, upconversion efficiency improvement, and material optimization for LEDs and biomedical uses. Dr. Nelson Etafo is also recognized for extensive contributions to environmental remediation, particularly electrocoagulation technology for wastewater treatment, pollutant removal, and precious metal recovery. His collaborative studies address cyanide destruction, gold/silver recovery, contaminant sequestration, and emerging wastewater challenges. He has authored influential reviews on photocatalysis, touchscreen antimicrobial coatings, nanohybrids for biomedical use, and CO₂ utilization technologies-strengthening global discussions on sustainable and green engineering. Beyond journal publications, Dr. Nelson Etafo has contributed to book authorship and edited volumes, including Tailored Light Emitters for Biomedical Applications (Springer), along with chapters on drug delivery, biocatalytic waste conversion, and advanced materials for water treatment. His scientific contributions extend to participation in national and international conferences, collaborative projects with multidisciplinary teams, and membership in leading professional bodies such as ACS, RSC, and CSN. His research impact reflects a strong commitment to innovation, sustainability, and scientific advancement across material science and environmental engineering.

Profiles: Scopus | ORCID | Google Scholar | ResearchGate | Sci Profiles | Loop

Featured Publications

1. Etafo, N. O., Bamidele, M. O., Bamisaye, A., & Alli, Y. A. (2024). Revolutionizing photocatalysis: Unveiling efficient alternatives to titanium (IV) oxide and zinc oxide for comprehensive environmental remediation. Journal of Water Process Engineering, 62, 105369.

2. Nkoh, J. N., Oderinde, O., Etafo, N. O., Kifle, G. A., Okeke, E. S., Ejeromedoghene, O., … Ogunlaja, O. O. (2023). Recent perspective of antibiotics remediation: A review of the principles, mechanisms, and chemistry controlling remediation from aqueous media. Science of the Total Environment, 881, 163469.

3. Nkoh, J. N., Shang, C., Okeke, E. S., Ejeromedoghene, O., Oderinde, O., Etafo, N. O., … Foka Meugang, E. (2024). Antibiotics soil-solution chemistry: A review of environmental behavior and uptake and transformation by plants. Journal of Environmental Management, 354, 120312.

4. Alli, Y. A., Bamisaye, A., Bamidele, M. O., Etafo, N. O., Chkirida, S., Lawal, A., … Nageim, H. A. (2024). Transforming waste to wealth: Harnessing carbon dioxide for sustainable solutions. Results in Surfaces and Interfaces, 17, 100321.

5. Etafo, N. O., Oliva, J., Garcia, C. R., Mtz-Enríquez, A. I., Ruiz, J. I., Avalos Belmonte, F., … Gómez-Solís, C. (2022). Enhancing the blue/NIR emission of novel BaLaAlO4:Yb3+ (x mol%), Tm3+ (0.5 mol%) upconversion phosphors with the Yb3+ concentration (x = 0.5 to 6). Inorganic Chemistry Communications, 137, 109192.

Lei Fan | Nanotechnology and Materials Science | Editorial Board Member

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Dr. Lei Fan | Nanotechnology and Materials Science | Editorial Board Member

Master Tutor | School of Civil Engineering and Architecture, Zhejiang University of Science & Technology | China

Dr. Lei Fan is an emerging researcher in nano-mechanics and micro-/nano-scale structural behavior, with a strong focus on the mechanical effects, transport phenomena, and interfacial interactions of advanced nanomaterials. His work integrates atomic-scale modeling, computational materials science, and solid–liquid interface mechanics to address fundamental questions in graphene, hexagonal boron nitride (h-BN), and hybrid two-dimensional (2D) systems. With 289 Scopus citations, 41 publications, and an h-index of 10, he has established a growing impact in the fields of materials science and civil engineering nanotechnology. Dr. Lei Fan has authored 38 peer-reviewed papers, including 25 SCI-indexed publications as first or corresponding author, demonstrating strong leadership in scholarly communication. His notable works include high-impact contributions to International Journal of Molecular Sciences (Q1, IF~6.2) on ion/water molecular transport in angstrom-scale channels, offering fundamental insights that bridge atomic modeling with solid–liquid interaction mechanisms. His research in Surfaces and Interfaces (Q1, IF~6.1) examines toughness enhancement strategies in 2D hybrid materials via carbon nanotube integration, advancing design principles for next-generation nanocomposites. He has also published multiple studies in Diamond and Related Materials on grain boundaries, nanoholes, functional groups, and defect evolution in graphene/h-BN heterostructures, providing systematic understanding of bonding energies, deformation mechanisms, and temperature-dependent interface transitions. Dr. Lei Fan’s research excellence is reinforced through competitive funding support, including the Natural Science Foundation of Zhejiang Province, institutional scientific research grants, and participation in China’s State Key Program of the National Natural Science Foundation. His contributions extend to scholarly service as an editorial board member of Journal of Materials and New Energy and an active reviewer for leading SCI journals such as 2D Materials, Nanotechnology, and Computational Materials Science. With sustained innovation across atomic-scale mechanics, defect engineering, and nano-interface behavior, Dr. Lei Fan’s work continues to shape the theoretical and computational foundation of next-generation micro-/nano-structured materials.

Profiles: Scopus | ORCID | ResearchGate

Featured Publications

1. Fan, L. (2023). Mechanical mechanism of ion and water molecular transport through angstrom-scale graphene derivatives channels: From atomic model to solid-liquid interaction. International Journal of Molecular Sciences, 23, 1433.

2. Fan, L., Cai, X., Wang, H., Ye, J., Hong, Y., & Ying, J. (2023). Toughening two-dimensional hybrid materials by integrating carbon nanotubes. Surfaces and Interfaces, 36, 102559.

3. Fan, L., Bian, Z., Huang, Z., Song, F., Xia, Y., & Xu, J. (2022). Role of grain boundary and nanoholes in geometrical deformation and bonding energies of graphene/hexagonal boron nitride. Diamond and Related Materials, 126, 109119.

4. Fan, L., Bian, Z., Huang, Z., Song, F., Xia, Y., & Xu, J. (2022). New insight into bonding energy and stress distribution of graphene oxide/hexagonal boron nitride: Functional group and grain boundary effect. Diamond and Related Materials, 127, 109185.

5. Fan, L., & Yao, W. (2022). Temperature dependence of interfacial bonding and configuration transition in graphene/hexagonal boron nitride containing grain boundaries and functional groups. International Journal of Molecular Sciences, 23, 1433.