Technically, anything can have a large mass, as long as there is a lot of that substance. Even the very tiniest molecule can form a substance with a large mass. For example, hydrogen is the smallest atom, but the mass of hydrogen in the Sun is monumental. The atom with the largest mass - that is currently known - is roentgenium, element number 111.
Water. It always has the same mass, but when you freeze it, the volume it requires expands, the same thing happens when you excite it or heat it up, again it expands in volume, but still has the same amount of mass.
If you want something with a large volume and a small mass, try a hot air balloon.
That depends on what you call "large".
To me, a good example is: The Earth.
Although compared to, say, the sun, the earth is pretty puny, and not large at all.
Black holes, neutron stars, white dwarves.
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These are solids with high density.
The air in your room.
To convert between mass and volume you need the density of the substance. Density = mass/volume. It is not clear what you mean by count. If you are thinking of large scale objects then if they are all alike, you can convert mass to count if you know the mass of one of them. I wonder if you are thinking of chemical quantity expressed in moles? The conversion in this case is moles = mass/molar mass.
The volume and the mass of sample both depend on the size of the sample.A small sample has small volume and small mass, a big sample has big volumeand big mass. But the ratio of mass to volume is constant for a pure sample ofa substance, no matter what size the sample is. That ratio is called the densityof the substance.
The density an object depends not only on the mass but also its volume i.e. D=M/V. Therefore, if two objects had the same mass and volume then they would have the same density. By contrast, if two objects had the same mass but different volumes then they would not have the same volume. In fact, the object with the least volume would be more dense or would have would have a greater density.
You just need to rework the density formula: D = M / V, where D is density, M is mass, and V is volume. So all you need to do is put in the Density and Mass and solve for V: D = M / V D * V = M V = M / D And so our volume becomes Mass divided by Density.
Definition of density: Density = mass / volume; solving for density: volume = mass / density. Density of silver is about 10.5 grams/cm3.
"large density" ===> (relatively large mass) fits into (relatively small volume)
No, Density is directly proportional to mass; Density increases as the mass increases, density decreases when mass decreases. Density is inversely proportional to volume; Density decreases when volume increases, density increases when volume decreases.
The gravity depends on the mass.
Density equalls mass divided by its volume.
You have decreased the volume
A mineral's density increases as its mass per unit volume increases. If a mineral has a small mass and large unit volume, its density is smaller. Whereas, if a mineral has a large mass and a small unit volume, its density is greater.
Grams. * * * * * That is total rubbish. Grams is a measure of mass, not volume. Volume may be measured in cubic centimetres ( 1 cc = 1 millilitre) for small objects, litres for medium sized objects to cubic metres for "normal" large objects and cubic kilometres for mountains or bigger.
mass divided by volume... mass/volume=density
Objects of greater mass have more gravitational pull.
Compare their weights on scale's have to select scales depending on the size of the objects to find a objects density divide the objects mass by its volume.
the mass of the object is too small
Its MASS