There wasn't enough room to write everthing I wanted to say, but I tried it on my own and this is what I was able to come up with:
[C] = .3646 mg/ml HCl
HCl = 36.46 grams per mole
*convert to g/L*
.3646mg/1ml X 1g/1000mg X 1000ml/1L = .0003646g/L
*convert g/L to Moles/L*
[C] = .0003646g/1L X 36.46g/ 1M
= .0001 M/L
Am I correct?
The molarity of hydrochloric acid 36,5 % (concentrated acid) is 10 M.
It is 11.3
Strong acid with strong base always ends with neutral water and the resulting ions Na+ and Cl-, both neutral as well!
Hydrochloric acid can be measured in units of concentration, such as molarity (moles per liter) or normality (equivalent grams per liter). It can also be measured using pH, which indicates the acidity or alkalinity of a solution, or by titration with a suitable base to determine its concentration.
its boiling point depends on the cocentration or molarity of hci and it is a binary (two-componet) mixture
6M
The molarity of hydrochloric acid 36,5 % (concentrated acid) is 10 M.
It is 11.3
The normality of commercial grade hydrochloric acid (HCl) can vary depending on the concentration specified by the manufacturer. Hydrochloric acid is commonly available in different concentrations, such as 37% or concentrated hydrochloric acid. To determine the normality, it is essential to know the molarity (moles of solute per liter of solution) and the number of equivalents of the acid. Normality (N) is related to molarity (M) by the equation: � = � × � N=n×M where: � N is the normality, � n is the number of equivalents, � M is the molarity. For hydrochloric acid (HCl), which is a monoprotic acid (donates one proton), the number of equivalents ( � n) is equal to 1. Therefore, if you know the molarity of the commercial grade hydrochloric acid, you can determine its normality using the equation mentioned above. It's important to check the product label or contact the manufacturer for the specific concentration of the hydrochloric acid you are using.
Strong acid with strong base always ends with neutral water and the resulting ions Na+ and Cl-, both neutral as well!
The equation for finding the pH of a solution is -log([H+]). That is, the negative log of the molarity of the hydrogen ions released by the compound in solution. Almost no chemicals can release hydrogen ions with a molarity greater than 1 or less than 10^-14. however, there are some rare cases where the pH of a solution is not between 0 and 14. For example, 10 molarity hydrochloric acid (there are ten moles of hydrochloric acid for every liter of water.), has a pH of -1 (-log(10) =-1). But these are so rare in occurence, that they generally disregard it.
Hydrochloric acid can be measured in units of concentration, such as molarity (moles per liter) or normality (equivalent grams per liter). It can also be measured using pH, which indicates the acidity or alkalinity of a solution, or by titration with a suitable base to determine its concentration.
its boiling point depends on the cocentration or molarity of hci and it is a binary (two-componet) mixture
In solution this is an acid. Hydrochloric acid.
Preparation of standard solution and standardization of hydrochloric acid Objective : To prepare a standard solution of sodium carbonate and use it to standardize a given solution of dilute hydrochloric acid. Introduction : Anhydrous sodium carbonate is a suitable chemical for preparing a standard solution (as a primary standard). The molarity of the given hydrochloric acid can be found by titrating it against the standard sodium carbonate solution prepared. The equation for the complete neutralization of sodium carbonate with dilute hydrochloric acid is Na2CO3(aq) + 2HCl(aq) → 2NaCl(aq) + CO2(g) + H2O(l) The end-point is marked by using methyl orange as indicator. Chemicals :solid sodium carbonate, 0.1 M hydrochloric acid
phenolphthalein only turns pink in a solution that is a base. Hydrochloric acid is obviously an acid.
That's a difficult question to answer, because "pure" hydrochloric acid is a gas at room temperature, and the conductivity of a solution of hydrochloric acid depends on the concentration.