Simple alcohols are found widely in nature. Ethanol is the most prominent because it is the product of fermentation, a major energy-producing pathway. 527-07-1, formula is C6H11NaO7, Other simple alcohols, chiefly fusel alcohols, are formed in only trace amounts. More complex alcohols however are pervasive, as manifested in sugars, some amino acids, and fatty acids. , COA of Formula: C6H11NaO7
Mishra, Gaurav Kumar;Kant, Rama research published 《 Modular theory for DC-biased electrochemical impedance response of supercapacitor》, the research content is summarized as follows. Supercapacitor electrodes consist of complex nanoporous structures in carbonaceous and non-carbonaceous materials causing alteration of elec. double layer (EDL) structure and response. We develop a modular theory for DC-bias dependent electrochem. impedance spectroscopy (EIS) for EDL in the heterogeneous bimodal porous electrode, viz. arbitrary mesopores with embedded heterogeneous micropores. Theory accounts for the compact- and diffuse-EDL dynamics along with charge transfer kinetics of pseudocapacitance. The influence of applied DC-bias on various phenomenol. components is accounted through a heuristic approach. This is achieved by using the potential and concentration dependent diffuse layer thickness for unsym. electrolytes, charge transfer resistance, and elec. field dependent dielec. constant The generic nature of theory is further highlighted by extending it for the composite porous electrode materials. The theor. response shows that increasing the magnitude of DC-bias enhances the characteristic ion relaxation rates therefore, increases the rate capability of supercapacitors. The electrode morphol. parameters, viz. mesopore size, micropore size, micropore length, and the pore surface heterogeneity, can effectively tune the capacitance and charging-discharging rates therefore, influence the performance of supercapacitors. Finally, our theory explains the exptl. EIS data for hierarchical sodium gluconate and graphdiyne porous electrodes.
COA of Formula: C6H11NaO7, Sodium Gluconate is the sodium salt of gluconic acid with chelating property. Sodium gluconate chelates and forms stable complexes with various ions, preventing them from engaging in chemical reactions.
Sodium gluconate is an organic sodium salt having D-gluconate as the counterion. It has a role as a chelator. It contains a D-gluconate.
D-Gluconic acid sodium salt is a glycol ether that is used as an injection solution. It has been shown to have antibacterial efficacy against wild-type strains of bacteria such as Escherichia coli, Pseudomonas aeruginosa, and Staphylococcus aureus. The in vitro antimicrobial action of D-gluconic acid sodium salt was found to be due to its ability to inhibit bacterial growth by interfering with the synthesis of DNA. D-gluconic acid sodium salt also has been shown to have antihypertensive effects in rats through the inhibition of angiotensin II type 1 receptor (AT1) signaling pathway and erythrocyte proliferation. This drug also has been shown to bind benzalkonium chloride and x-ray diffraction data show that it is crystalline in nature. The analytical method for determining the concentration of D-gluconic acid sodium salt is by electrochemical impedance, 527-07-1.
Referemce:
Alcohol – Wikipedia,
Alcohols – Chemistry LibreTexts