Disclosed is a net-shaped polyimide sponge. The polyimide sponge has a stack structure of nets. Also disclosed is a method for producing a polyimide sponge. The method enables the production of a polyimide sponge in a continuous process, which offers advantages for large-scale production compared to conventional methods using batch systems.

Disclosed is a net-shaped polyimide sponge. The polyimide sponge has a stack structure of nets. Also disclosed is a method for producing a polyimide sponge. The method enables the production of a polyimide sponge in a continuous process, which offers advantages for large-scale production compared to conventional methods using batch systems.

Embodiments herein provide a method of preparing Silicon (Si) from sand (SiO.sub.2).The method includes preparing sand particles with a size less than 50 microns. Further, the method includes obtaining Magnesium (Mg) particles with a size in range of 105-150 microns. Further, the method includes mixing sand and Mg particles in a predefined ratio to obtain a Sand-Magnesium (SM) mixture. Further, the method includes subjecting the SM mixture to heating at a temperature for a predefined time to obtain Si sample. Further, the method includes identifying un-reacted portion of Mg and sand particles. Furthermore, the method includes purifying byproducts of magnesium as well as un-reacted-magnesium and silica to obtain pure Si.

Embodiments herein provide a method of preparing Silicon (Si) from sand (SiO.sub.2).The method includes preparing sand particles with a size less than 50 microns. Further, the method includes obtaining Magnesium (Mg) particles with a size in range of 105-150 microns. Further, the method includes mixing sand and Mg particles in a predefined ratio to obtain a Sand-Magnesium (SM) mixture. Further, the method includes subjecting the SM mixture to heating at a temperature for a predefined time to obtain Si sample. Further, the method includes identifying un-reacted portion of Mg and sand particles. Furthermore, the method includes purifying byproducts of magnesium as well as un-reacted-magnesium and silica to obtain pure Si.

A method of making mesoporous silicon from silica, the mesoporous silicon obtained by the method, and uses of the mesoporous silicon are described. The mesoporous silicon may be derived from plants, particularly land-based plants.

A method of making mesoporous silicon from silica, the mesoporous silicon obtained by the method, and uses of the mesoporous silicon are described. The mesoporous silicon may be derived from plants, particularly land-based plants.

A method for manufacturing porous silicon can include reducing unpurified silica in the presence of a reducing agent to prepare a porous silicon material. The method of manufacture can optionally include purifying a silica, exposing the silica to reaction modifiers, purifying the mixture of the silica and reaction modifiers, comminuting the silica, purifying the silicon, coating the silicon, post-processing the silicon, and/or any suitable steps.

A method for manufacturing a silicon material can include comminuting a silicon material. A silicon material can include silicon nanoparticles formed by comminuting silicon particles, where the silicon nanoparticles can cooperatively form pores.

Disclosed is a tunneling diode, which includes a graphene-silicon quantum dot hybrid structure, having improved performance and electrical characteristics by controlling the sizes of silicon quantum dots and the doping concentration of graphene. The ideal tunneling diode of the present disclosure may be utilized in diode-based optoelectronic devices.

Disclosed is a tunneling diode, which includes a graphene-silicon quantum dot hybrid structure, having improved performance and electrical characteristics by controlling the sizes of silicon quantum dots and the doping concentration of graphene. The ideal tunneling diode of the present disclosure may be utilized in diode-based optoelectronic devices.