Rechargeable Battery 14.4V 2600mah 18650 Battery Li Ion Battery Pack

Item	14.4V2000mAh	14.4V 4400mAh	14.4V 2600mAh	LiFePO4 12.8V 6400mAh
Assembly	4S1P	4S2P	4S1P	4S2P
Norminal Capacity	2.0Ah	4.4Ah	2.6Ah	6.4Ah
Nominal Voltage	14.4V	14.4V	14.4V	12.8V
Max charge voltage	16.8V	16.8V	16.8V	14.4V
Cut-off discharge voltage	12V	12.0V	12.0V	10.0V
Max continuous discharge current	1-2A	1-4A	1-2A	1-10A
Charge current	1-2A	1-2A	1-2A	1-3A
Charge&Discharge plug	Tamiya or selected	JST or customiz	customiz	Cigerate or customize
Dimension(mm)	70x36x36	132x38x38	70x36x36	132x54x30
Weight(Unit:Gram)	App.200g	App.390g	App.200g	App.700g
Cell Brand	Top A Grade Chinese Brand cells
Protection	Over charge&discharge, over current, short circuit
Cycle life	Capacity ≥60% ,cycle life ≥600times			≥1000times
Application	Garden sprayer, medical instrument, smart vacuum cleaner, outdoor instrument, door control, Solar LED,12v lead acid battery replacement etc.
Warranty	12months

Currently, power plants equipped with carbon capture systems generally use up to 30 percent of the electricity they generate just to power the capture, release, and storage of carbon dioxide. Anything that can reduce the cost of that capture process, or that can result in an end product that has value, could significantly change the economics of such systems, the researchers say.

However, “carbon dioxide is not very reactive,” Gallant explains, so “trying to find new reaction pathways is important.” Generally, the only way to get carbon dioxide to exhibit significant activity under electrochemical conditions is with large energy inputs in the form of high voltages, which can be an expensive and inefficient process. Ideally, the gas would undergo reactions that produce something worthwhile, such as a useful chemical or a fuel. However, efforts at electrochemical conversion, usually conducted in water, remain hindered by high energy inputs and poor selectivity of the chemicals produced.