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Q: Why it is acceptable to use volume rather than concentration for drawing graph?

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1700 m3 is a measure of volume; it is rather big.

Volume is the space that an object occupies (or that it would occupy if it were to exist in the physical world rather than just as a concept).

The initial concentration affects the conductivity of a solution in a sense that the greater the initial concentration,the greater the conductivity.increase in concentration means presence of more free moving ions in the solution.but this can only occur in the initial concentration because,after the initial concentration,an increase in concentration will mean that there are now more ions present in the solution but the same volume,hence the ions wouldn't be able to move freely an in the initial concentration,hence the conductivity would then decrease since they can't move freely now.

No. To express concentration as a percentage both components (usually solvent and solute, but could be two fluids) need to be measured in the same units - both in volume or both in mass.

231 cubic inches == (presumed that you meant cubic inches, which like gallons is a measure of volume, rather than square inches, which is a measure of area) 1 US gallon = 231 Cubic inches (presuming you meant cubic inches, which like gallons is a measure of volume, rather than square inches, which is a measure of area)

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To find the final concentration of a solution after dilution, you can use the formula: (C_1V_1 = C_2V_2), where (C_1) is the initial concentration, (V_1) is the initial volume, (C_2) is the final concentration, and (V_2) is the final volume. Plug in the values for the initial concentration, volume, and final volume to calculate the final concentration of HCl.

As the concentration gradient increases, the urine volume typically decreases. This is because a higher concentration gradient drives more water reabsorption in the kidneys, resulting in a lower urine volume being produced.

Concentration of a solution refers to the amount of solute present in a given quantity of solvent or total solution. It can be expressed in various ways, such as mass/volume (g/mL), moles/volume (mol/L), or as a percentage. Concentration is important for determining the properties and behavior of a solution.

The amount of one material in a certain volume of another material?

Blood volume and concentration are crucial for maintaining proper bodily functions. Blood volume ensures adequate circulation of nutrients, hormones, and oxygen to body tissues, while blood concentration regulates the balance of electrolytes, proteins, and cells in the blood. Changes in blood volume and concentration can impact blood pressure, hydration levels, and overall health.

The concentration of a solution refers to the amount of solute present in a given volume of the solution. It can be expressed as mass/volume (g/mL) where mass is the amount of solute and volume is the amount of solution. This measurement helps determine the strength or potency of a solution.

To determine the volume of NaOH used in the titration, you need to know the concentration of the NaOH solution and the volume required to reach the endpoint. Use the formula: volume NaOH (L) = volume HCl (L) * concentration HCl / concentration NaOH.

Ye.. the concentration of a substance is measured as the amount of substance per unit volume. Accordingly, the amount of a substance in per unit volume is the concentration of the substance.

Concentration is typically given with the volume of solution. This allows for a consistent measurement of how much solute is present in the entire solution, regardless of the volume of solvent used to make the solution.

The concentration is related to the volume of the atmosphere and the amount of the element your looking at.Molarity(concentration)= G/(Molecular weight)x Liters(volume)

Concentration is the amount of a substance in a specified mass (or volume) of a material.

Volume (cm3) = (Number of Moles X 1000) Divided by Concentration Volume (dm3) = Number of Moles Divided by Concentration