It is 0.055... (repeating) g per ml.
419 mL
To find the volume of the rock, you can use the formula: Volume = Mass / Density. Plug in the values: Volume = 16 grams / 4 g/ml = 4 ml. So, the rock occupies a volume of 4 ml.
129
To find the new volume, we can use the Charles's Law equation: V1 / T1 = V2 / T2. Plugging in the values, we get 3.8 / (-45 + 273) = V2 / (45 + 273). Solving for V2 gives us approximately 4.22 liters.
It is 0.055... (repeating) g per ml.
Density = Mass/Volume = 25.0/100 g/mL = 0.25 g/mL
Density = Mass/Volume = 50mg/6.4ml = 7.8125 mg/ml or 7.8125 grams per litre.
419 mL
Density = Mass/Volume = 10 g/100 mL = 0.1 grams per millilitre.
The density of CO gas can be calculated using the formula: density = mass/volume. Given the mass of CO gas (0.196 g) and the volume it occupies (100 ml), we can convert the volume to liters (1 L = 1000 ml) and then calculate the density as 0.196 g / 0.1 L = 1.96 g/L. So, the density of CO gas is 1.96 g/L.
423mL
To find the volume of the rock, you can use the formula: Volume = Mass / Density. Plug in the values: Volume = 16 grams / 4 g/ml = 4 ml. So, the rock occupies a volume of 4 ml.
Density = Mass/Volume = 25/30 g/ml = 0.833... g/ml
129
1000 ml = 1 litre so 874000 ml = 874 l
5 mL of water vapor would occupy significantly less volume as a liquid. All gasses occupy more space than their liquid counterparts as the extra energy of gaseous states drive the molecules further apart.