Preparation of different morphology Cu/GO nanocomposites and their catalytic performance for thermal decomposition of ammonium perchlorate

Abstract: Cu nanoparticles are more active catalytically than CuO nanoparticles, which have been widely studied as catalysts for organic synthesis, electrochemistry, and optics.

“…The XPS spectra that were previously reported for NiCu, NiCu/GO, and NiCu/rGO nanocomposites reveal the surface elements and groups, their binding energy, and the electronic structure of the catalysts. [43][44][45] For the NiCu nanocomposite, a peak at around 284 eV was attributed to the Ni 2+ ions and the peak around 172 eV was due to the Cu 2+ ions. 43 The peak at around 159 eV was related to the oxygen atoms, whereas the peak at around 137 eV was assigned to the carbon atoms.…”

“…[43][44][45] For the NiCu nanocomposite, a peak at around 284 eV was attributed to the Ni 2+ ions and the peak around 172 eV was due to the Cu 2+ ions. 43 The peak at around 159 eV was related to the oxygen atoms, whereas the peak at around 137 eV was assigned to the carbon atoms. 43 For the NiCu/GO nanocomposite, a shi in some peaks was observed compared with that of pure NiCu.…”

“…43 The peak at around 159 eV was related to the oxygen atoms, whereas the peak at around 137 eV was assigned to the carbon atoms. 43 For the NiCu/GO nanocomposite, a shift in some peaks was observed compared with that of pure NiCu. The peak at around 284 eV was shifted to higher binding energy, indicating that more oxygen atoms were present on the surface.…”

Fabrication and characterization of NiCu/GO and NiCu/rGO nanocomposites for fuel cell application

“…The XPS spectra that were previously reported for NiCu, NiCu/GO, and NiCu/rGO nanocomposites reveal the surface elements and groups, their binding energy, and the electronic structure of the catalysts. [43][44][45] For the NiCu nanocomposite, a peak at around 284 eV was attributed to the Ni 2+ ions and the peak around 172 eV was due to the Cu 2+ ions. 43 The peak at around 159 eV was related to the oxygen atoms, whereas the peak at around 137 eV was assigned to the carbon atoms.…”

“…[43][44][45] For the NiCu nanocomposite, a peak at around 284 eV was attributed to the Ni 2+ ions and the peak around 172 eV was due to the Cu 2+ ions. 43 The peak at around 159 eV was related to the oxygen atoms, whereas the peak at around 137 eV was assigned to the carbon atoms. 43 For the NiCu/GO nanocomposite, a shi in some peaks was observed compared with that of pure NiCu.…”

“…43 The peak at around 159 eV was related to the oxygen atoms, whereas the peak at around 137 eV was assigned to the carbon atoms. 43 For the NiCu/GO nanocomposite, a shift in some peaks was observed compared with that of pure NiCu. The peak at around 284 eV was shifted to higher binding energy, indicating that more oxygen atoms were present on the surface.…”

Fabrication and characterization of NiCu/GO and NiCu/rGO nanocomposites for fuel cell application

“…In the synthesis of NPs, temperature is an influential parameter. Metal NPs undergo calcination in a temperature range of 100 to 900 • C, depending on the specific synthesis methods employed [158][159][160][161]. Chemical and physical methodologies involve the utilization of temperatures surpassing 300 • C, whereas biological methodologies typically operate at more moderate temperatures, such as 100 • C or even ambient conditions.…”

Recent Developments in Lignocellulosic Biofuel Production with Nanotechnological Intervention: An Emphasis on Ethanol

Construction of 3DOM Fe2O3/CuO heterojunction nanomaterials for enhanced AP decomposition