Milk of magnesia is a basic solution. Therefore, methyl orange shows a yellowish orange colour. Further, this indicator shows a red colour in acidic solutions.
The color is blue because magnesia milk is a hydroxide.
A mixture of phenolphthalein, methyl orange, and litmus would typically result in a color that depends on the pH of the solution. Phenolphthalein is colorless in acidic solutions and turns pink in basic solutions, while methyl orange is red in acidic conditions and yellow in neutral to basic conditions. Litmus is red in acidic solutions and blue in basic ones. Therefore, the overall color would vary, likely appearing red in acidic environments and transitioning through shades of orange to yellow in neutral to basic conditions, depending on the dominant indicator's pH response.
A suitable indicator for an endpoint at pH 10.5 would be methyl orange. At this pH, methyl orange changes color from red to yellow, making it a good choice for acid-base titrations that end around pH 10.5.
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Alkalinity is different from basicity, which is directly related to the pH. The higher the pH, the more basic the water.Like acidity, there are different ways to measure and report alkalinity;The first is to titrate the water with acid titrant to the phenolphthalein end point. This is called the phenolphthalein alkalinity. Since phenolphthalein changes color at pH~8.3, this corresponds to a pH where all the CO32- present would be protonated.Second, acid titration to a methyl orange end point, pH~4.3, further converts the bicarbonate to aqueous carbon dioxide. At this end point, some of the weaker conjugate bases are protonated. The methyl orange end point titration indicates total alkalinity.
When nitric acid reacts with methyl orange, the color of the solution changes. Methyl orange is an indicator that changes color from orange/yellow in acidic solutions to red in basic solutions. In the presence of nitric acid, which is a strong acid, the solution would turn red.
The equation of the titration using methyl orange as an indicator depends on the specific reaction being titrated. Methyl orange is typically used in acid-base titrations, where the indicator changes color in the presence of a certain pH range. For example, in a titration of a strong acid (e.g., HCl) with a strong base (e.g., NaOH), the equation would involve the stoichiometry of the acid-base reaction, with the color change of methyl orange indicating the endpoint of the titration.
The color is blue because magnesia milk is a hydroxide.
A mixture of phenolphthalein, methyl orange, and litmus would typically result in a color that depends on the pH of the solution. Phenolphthalein is colorless in acidic solutions and turns pink in basic solutions, while methyl orange is red in acidic conditions and yellow in neutral to basic conditions. Litmus is red in acidic solutions and blue in basic ones. Therefore, the overall color would vary, likely appearing red in acidic environments and transitioning through shades of orange to yellow in neutral to basic conditions, depending on the dominant indicator's pH response.
A suitable indicator for an endpoint at pH 10.5 would be methyl orange. At this pH, methyl orange changes color from red to yellow, making it a good choice for acid-base titrations that end around pH 10.5.
Well, isn't that a happy little question! Methyl orange is a dye that usually turns red in acidic solutions and yellow in alkaline solutions. Since grapefruit juice is acidic, it would likely turn methyl orange red, creating a vibrant and colorful reaction that shows the acidity of the juice. Just like painting a beautiful sunset, nature always provides us with lovely surprises!
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A green orange.AnswerA yellow orange. AnswerIt would be a gold orangeANSWER: - OrangeAnswerAny color but orange
On the additive color wheel, the opposite of Orange would be Blue.
You would either get a lighter orange or you would get a yellow orange colour.
For example methyl orange become red in acidic solutions.
Methyl orange is a halochromic substance. When it binds to existing hydrogen and hydroxide ions in solution, these bonds cause changes in the flow of electrons, which in turn affects the amount of light absorbed. This is perceptible to the naked eye as a color change in the solution.