A5089891591- Advancements in Battery Materials
- Supercapacitor Materials and Fabrication
- Semiconductor materials and devices
- Nanowire Synthesis and Applications
- Advanced battery technologies research
- Advanced Battery Technologies Research
- Advanced Battery Materials and Technologies
- Advanced Sensor and Energy Harvesting Materials
- Graphene research and applications
- MXene and MAX Phase Materials
- Microfluidic and Capillary Electrophoresis Applications
- Silicon Nanostructures and Photoluminescence
- Surface Modification and Superhydrophobicity
- ZnO doping and properties
- Carbon Nanotubes in Composites
- Conducting polymers and applications
- Nanofabrication and Lithography Techniques
- Electrochemical sensors and biosensors
- Diamond and Carbon-based Materials Research
- Microfluidic and Bio-sensing Technologies
- Mechanical and Optical Resonators
- Advanced Materials and Mechanics
- Microbial Fuel Cells and Bioremediation
- Plasma Diagnostics and Applications
- Metal and Thin Film Mechanics
University of Tehran
2016-2025
Energy Storage Systems (United States)
2025
Sharif University of Technology
2018
A highly efficient protective membrane based on PVDF-HFP/LiF for protecting an LATP solid-state electrolyte from lithium metal anodes.
Core-shell silicon/multiwall carbon nanotubes are one of the most promising anode candidates for further improvement lithium-ion batteries. Sufficient accommodation massive volume expansion silicon during lithiation process and preventing pulverization delamination with easy fabrication processes still critical issues practical applications. In this study, core-shell silicon/MWCNTs materials were synthesized using a facile controllable PECVD technique to realize aligned MWCNTs followed by...
The growing energy demands of the industrial world have driven advancements in green technologies. Microbial fuel cells (MFCs), which harness power from microorganisms, show promise for extraction wastewater and sludge. However, challenges remain improving output sustaining performance under high-charge conditions. Incorporating nanomaterials into 3D structures offers potential solutions, including miniaturized designs. This study introduces nickel silicide nanowires as anode materials MFCs....
GO and MoS<sub>2</sub> solution in combination with NiO nanoparticles present a high performance supercapacitor excellent cycling stability.
First report on silicon-nanowires@void@carbon grown a conductive substrate through scalable fabrication process, with excellent specific capacity, cycle life, and rate performance.
Here, we report 3D hierarchical SnO2 nanowire (NW) core-amorphous silicon shell on free-standing carbon nanotube paper (SnO2@a-Si/CNT paper) as an effective anode for flexible lithium-ion battery (LIB) application. This binder-free electrode exhibits a high initial discharge capacity of 3020 mAh g-1 with large reversible charge 1250 at current density 250 mA g-1. Compared to other NW or its core-shell nanostructured anodes, the fabricated SnO2@a-Si/CNT structure demonstrates outstanding...
Here, SnO2 nanoribbons (NRs) synthetized on the catalyst-free stainless steel (SS) substrate as a possible anode for Li-ion batteries (LIBs) have been reported. NRs were synthesized SS via vapor-solid (VS) growth approach. Morphological and structural characterizations of confirmed using scanning electron microscopy (SEM), transmission (TEM) microscopes x-ray diffraction (XRD) respectively. The prepared binder-free electrode demonstrated high initial discharge/charge capacities 1818/929 mAh...
Abstract SnO 2 is considered as one of the high specific capacity anode materials for Lithium-ion batteries. However, low electrical conductivity limits its applications. This manuscript reports a simple and efficient approach synthesis Sb-doped nanowires (NWs) core carbon shell structure which effectively enhances electrochemical performance nanostructures. Sb doping was performed during vapor-liquid-solid NWs in horizontal furnace. Subsequently, nanolayer coated on using DC Plasma Enhanced...
Silicon nanograss and nanostructures are realized using a modified deep reactive ion etching technique on both plane vertical surfaces of silicon substrate. The process is based sequential passivation cycle, it can be adjusted to achieve grassless high aspect ratio features as well grass-full surfaces. incorporation onto vertically placed parallel fingers an interdigital capacitive accelerometer increases the total capacitance from 0.45 30 pF. Vertical structures with below 100 nm have been realized.