We specialize in synthesizing advanced electrode materials — transition metal oxides, sulfides, and graphene-based composites — for high-performance energy storage applications.
Synthesis of high-purity transition metal oxides (TMOs) including manganese oxide (MnO₂), cobalt oxide (Co₃O₄), nickel oxide (NiO), and iron oxide (Fe₂O₃) for supercapacitor and battery electrode applications.
MnO₂ · Co₃O₄ · NiO · Fe₂O₃Development of transition metal sulfides (TMSs) including molybdenum disulfide (MoS₂), cobalt sulfide (CoS), nickel sulfide (NiS), and copper sulfide (CuS) with optimized morphology for enhanced electrochemical performance.
MoS₂ · CoS · NiS · CuSEngineered graphene-based metal oxide nanocomposites that combine high conductivity of graphene with pseudocapacitive properties of metal oxides for superior energy storage performance.
RGO-MnO₂ · Graphene-NiO · GO-Co₃O₄Hybrid nanostructures integrating graphene with transition metal sulfides to achieve enhanced electron transport, increased surface area, and improved cycling stability for next-gen batteries.
Graphene-MoS₂ · RGO-CoS · CNT-NiSCustom electrode fabrication using synthesized nanomaterials optimized for high specific capacitance, excellent rate capability, and long cycle life in symmetric and asymmetric supercapacitor configurations.
EDLC · Pseudocapacitors · HybridDevelopment of cathode and anode materials for lithium-ion, sodium-ion, and next-generation battery systems with focus on capacity retention, rate performance, and electrochemical stability.
Li-ion · Na-ion · Solid-StateHigh-temperature aqueous synthesis route (150-250°C) in autoclaves for producing crystalline nanomaterials with controlled morphology. Ideal for TMOs and TMSs with uniform particle distribution and high phase purity.
Crystalline · Controlled MorphologyNon-aqueous synthesis using organic solvents at elevated temperatures and pressures. Enables precise control over particle size, shape, and surface chemistry for enhanced electrochemical properties.
Size Control · Surface ModificationChemical solution-based approach for producing homogeneous, high-purity metal oxides at lower temperatures. Excellent for creating uniform thin films and porous structures with high surface area.
Homogeneous · High PurityGas-phase synthesis for growing high-quality graphene, MoS₂, and other 2D materials. Produces large-area films with excellent crystallinity and tunable thickness for advanced composite fabrication.
2D Materials · High CrystallinityElectrochemical deposition technique for direct growth of metal oxides and sulfides on conductive substrates. Provides excellent adhesion and uniform coating for electrode applications.
Direct Growth · Uniform CoatingScalable synthesis route involving simultaneous precipitation followed by thermal treatment. Ideal for large-batch production of nanoparticles with consistent quality and controlled stoichiometry.
Scalable · Batch ProductionWe begin by understanding your application requirements — energy density, power density, cycle life, operating conditions — and selecting optimal material compositions and synthesis routes.
Using advanced techniques like hydrothermal, solvothermal, sol-gel, and chemical vapor deposition (CVD), we synthesize nanomaterials with precise control over morphology, crystallinity, and particle size.
Comprehensive material characterization using XRD, SEM, TEM, BET, Raman spectroscopy, and XPS to validate structure, composition, surface area, and chemical states.
Rigorous electrochemical evaluation including cyclic voltammetry (CV), galvanostatic charge-discharge (GCD), electrochemical impedance spectroscopy (EIS), and long-term cycling stability tests.
Iterative refinement of synthesis parameters for performance enhancement, followed by process optimization for pilot-scale production and technology transfer support.
15+ years of specialized research in nanomaterial synthesis, electrochemistry, and energy storage technologies with proven track record in TMOs, TMSs, and graphene composites.
State-of-the-art facilities for hydrothermal, solvothermal, CVD, and sol-gel synthesis with precise control over morphology, particle size, and crystallinity.
Full analytical suite: XRD (crystallography), SEM/TEM (morphology), BET (surface area), Raman/XPS (chemical states), CV/GCD/EIS (electrochemistry).
Tailored material formulations designed for specific applications — from lab-scale R&D to pilot production with consistent quality and reproducibility.
Developed hierarchical MnO₂ nanosheets on reduced graphene oxide for a high-performance asymmetric supercapacitor. Achieved 485 F/g specific capacitance with 92% retention after 10,000 cycles.
Synthesized flower-like MoS₂ nanosheets decorated on carbon nanotubes for lithium-ion battery anodes. Demonstrated 1,240 mAh/g reversible capacity with excellent rate capability up to 5C.
Fabricated mesoporous NiO nanoparticles anchored on graphene nanosheets for high-power supercapacitor applications. Delivered 1,680 F/g at 1 A/g with outstanding long-term stability.
Engineered CoS₂ nanocrystals embedded in reduced graphene oxide matrix for sodium-ion battery applications. Achieved 620 mAh/g capacity with superior sodium storage kinetics.
Developed flexible solid-state supercapacitor using Co₃O₄ nanowires grown on graphene foam. Achieved 328 F/g with excellent mechanical flexibility and electrochemical stability under bending.
Synthesized hierarchical NiS microspheres on graphene sheets for asymmetric supercapacitor with activated carbon counter electrode. Delivered 51.3 Wh/kg energy density at 850 W/kg power density.
"The graphene-MnO₂ composite developed by Nano Research exceeded our performance targets. Exceptional specific capacitance with outstanding cycling stability — exactly what we needed for our supercapacitor application."
"Their expertise in transition metal sulfide synthesis is unparalleled. The MoS₂-based anode materials showed remarkable rate capability and we've successfully integrated them into our prototype cells."
"Nano Research delivered custom NiO-graphene composites with precise morphology control. Their characterization data was thorough and the material performed exceptionally in our asymmetric supercapacitor tests."
Our research contributes to advancing energy storage science through peer-reviewed publications in high-impact journals and innovative patent applications.
Demonstrates synthesis of 3D hierarchical MnO₂/rGO composites with 485 F/g capacitance and 92% retention after 10,000 cycles. Published in high-impact materials science journal.
Reports novel synthesis of MoS₂ nanosheets on CNT scaffold achieving 1,240 mAh/g capacity with excellent rate performance up to 5C. Featured research article.
Presents hydrothermal synthesis approach for mesoporous NiO-graphene composites with 1,680 F/g capacitance and 95% retention after 15,000 cycles.
Patent covering novel solvothermal synthesis process for producing graphene-MoS₂ and graphene-CoS composites with controlled morphology for battery applications.
Details synthesis and electrochemical characterization of CoS₂-rGO composites achieving 620 mAh/g capacity with superior Na-ion storage kinetics.
Patent describing fabrication method for flexible solid-state supercapacitors using Co₃O₄ nanowires grown on 3D graphene foam substrates.
Whether you need custom nanomaterials, electrode development, or collaborative R&D — let's create breakthrough solutions together.
Start a CollaborationHave a research project or need custom electrode materials? Our team of materials scientists is ready to discuss your requirements.