Effect of Channel Length and Dielectric Constant on Carbon Nanotube FET to Evaluate the Device Performance

“…A smaller voltage drop indicates a smaller depletion zone and a higher current flow through the channel because the voltage drop across the gate dielectric affects the size of the depletion region in the channel. Since the current is less susceptible to temperature fluctuations when the depletion region is smaller, this effect lessens the effect of temperature on the drain current against drain voltage relationship [22], [23]. 7 to illustrate how current varies with temperature as dielectric constant increases.…”

Temperature and Dielectric Constant Dependent Input and Output Characteristics of CNTFET

“…A smaller voltage drop indicates a smaller depletion zone and a higher current flow through the channel because the voltage drop across the gate dielectric affects the size of the depletion region in the channel. Since the current is less susceptible to temperature fluctuations when the depletion region is smaller, this effect lessens the effect of temperature on the drain current against drain voltage relationship [22], [23]. 7 to illustrate how current varies with temperature as dielectric constant increases.…”

Temperature and Dielectric Constant Dependent Input and Output Characteristics of CNTFET

“…Their smaller size allows for more uniform intercalation than microparticles, improving fracture toughness and fatigue life for electrode materials. [16][17][18][19][20] Notably, nanoparticles also exhibit superior fastcharging capabilities. Their small size drastically reduces diffusion length, enabling faster charging and discharging ability.…”

“…31,32 Nanostructure-based batteries also suffer from low volumetric capacity, significantly limiting their utility in stationary and grid storage applications. 19,33,34 Moreover, the synthesis cost of nanostructures is higher, and the manufacturing process generates substantial chemical waste. 35–38…”

“…31,32 Nanostructure-based batteries also suffer from low volumetric capacity, significantly limiting their utility in stationary and grid storage applications. 19,33,34 Moreover, the synthesis cost of nanostructures is higher, and the manufacturing process generates substantial chemical waste. [35][36][37][38] Multiscale particles (MP) embody nanoscale attributes within microscale particles, effectively combining characteristics of both micro and nanostructures, 13 potentially yielding the best of both worlds.…”

Unlocking the potential of open-tunnel oxides: DFT-guided design and machine learning-enhanced discovery for next-generation industry-scale battery technologies

A Comparative Analysis of High-k Gate Dielectrics on 30nm Fully Depleted Silicon on Insulator (FD SOI) MOSFET and NMOS Devices