Mr. Mohammad Ali Nasiri | Thermoelectric sensor | Best Researcher Award

Mr. Mohammad Ali Nasiri ,university of valencia -Instituto de Ciencia Molecular (ICMOL), Spain

Mohammad Ali Nasiri, based in Valencia, Spain, is an innovative researcher specializing in thermoelectric materials, energy storage, and sustainable solutions. With over five years of experience at the Instituto de Ciencia Molecular (ICMOL), he has made significant advancements in energy storage technologies and sustainable thermoelectric materials. Nasiri has expertise in micro/nanofabrication and extensive characterization techniques, including electron beam evaporation, thermal evaporation, and Raman spectroscopy. His notable publications include works on ultrathin transparent nickel electrodes and lignin-derived ionic conducting membranes. Nasiri holds a Master of Science in Nanotechnology from the Materials and Energy Research Center, Iran, and a Master of Science in Mechanical Engineering from Tarbiat Modares University, Iran. He is currently pursuing research in Nanoscience and Nanotechnology at the University of Valencia, focusing on thermoelectric materials. Nasiri’s work has been guided by esteemed research advisors Andres Cantarero and Clara Gomez.

Professional Profile:

ORCID

Education:

Researcher in Nanoscience and Nanotechnology, University of Valencia (March 2019 – Present)
Master of Science in Nanotechnology – Nanomaterials, Materials and Energy Research Center, Tehran, Iran (September 2014 – 2017)
Master of Science in Mechanical Engineering, Tarbiat Modares University, Tehran, Iran (November 2006 – 2009)

Languages:

English (B1), Persian (Native) 🗣️📚

Research Interests:

Hydrogel bioelectronics
Thermal conductivity on flakes
Ionic thermometric materials 🌊🌡️

Professional Experience:

Researcher Assistant at Instituto de Ciencia Molecular (ICMOL) (March 2019 – Present)
- Developed sensors for 3ω method thermal conductivity characterization.
- Created lignin-based MWCNT/MXene multilayered electrodes for energy storage.
- Pioneered sustainable innovations in thermoelectric materials, including lignin-derived ionic conducting membranes and hydrogels.
- Advanced techniques in transparent thermoelectric materials, including ultrathin transparent nickel electrodes and selective light absorbers. 🌞🧪

Skills:

Cleanroom Class 10000: Expert in micro and nanofabrication techniques such as electron beam evaporation, thermal evaporation, sputtering, ellipsometry, dry etching, and wire bonding. 🏭🔧
Characterization Techniques: Proficient in thermoelectric and thermal conductivity measurements, Hall effect, Raman, FTIR, UV-Vis, XPS, Kerr electro-optic effect, and SThM. 📊🔍
Mathematical Modeling and Problem Solving: Specializes in ionic thermoelectric materials and metamaterials using finite element method (FEM) and perturbation method. 📐🧩

Publication top Notes:

Highly-efficient sustainable ionic thermoelectric materials using lignin-derived hydrogels

Synthesis of PEDOT/CNTs Thermoelectric Thin Films with a High Power Factor

Lignin‐Derived Ionic Conducting Membranes for Low‐Grade Thermal Energy Harvesting

Ultrathin Transparent Nickel Electrodes for Thermoelectric Applications

Textile‐based Thermoelectric Generator Produced Via Electrochemical Polymerization

Elevated temperature annealed α-Fe<inf>2</inf>O<inf>3</inf>/reduced graphene oxide nanocomposite photoanode for photoelectrochemical water oxidation

Introductio Best Environmental Sensing Technology

The Best Environmental Sensing Technology Award recognizes outstanding innovations in technology that contribute to environmental monitoring and sustainability. This award highlights advancements in sensor technology that enhance our ability to understand and protect the environment.

Award Eligibility:

This award is open to individuals, teams, and organizations worldwide that have developed innovative environmental sensing technologies. There are no age limits for applicants. Qualification requires a demonstrable impact on environmental monitoring and sustainability. Publications related to the technology are encouraged but not required.

Requirements:

Submissions must include a detailed description of the technology, its development process, and its environmental impact. Evaluation criteria include innovation, environmental impact, scalability, and potential for future applications. Submissions should be in English and follow the submission guidelines outlined below.

Submission Guidelines:

Submissions must be sent via email to the award committee and include a biography of the applicant(s), an abstract of the technology, and supporting files such as videos, images, or data sets. The deadline for submissions is [insert deadline here].

Recognition:

The winner(s) of the Best Environmental Sensing Technology Award will receive a monetary prize and recognition at a prestigious environmental conference. They will also be featured in press releases and on the award website.

Community Impact:

The winning technology will have a significant impact on environmental monitoring and sustainability, helping to protect ecosystems and improve the quality of life for communities around the world.

Biography:

Applicants should provide a brief biography highlighting their relevant experience and expertise in environmental sensing technology.

Abstract and Supporting Files:

The abstract should provide a concise overview of the technology, its development, and its environmental impact. Supporting files should include any additional information or media that helps to showcase the technology’s innovation and impact.