A statement which concerns the regular spacing of the zeroes of the Riemann zeta-function. See,
http://mathworld.wolfram.com/GramsLaw.html
for more details.
grams law of diffusion deals with gases spreading out to occupy the shape of their container.
Yes. You should convert grams to moles in order to use the ideal gas law. The units of the other variable, R (gas constant) has moles in it.
Following the law of conservation of mass, also 10.0 grams.
Following the Law of Conservation of Mass (see link below), there will be 20 grams of products in a reaction of 20 grams of reactions.
Also 2.5 grams - law of conservation of matter.
Well, I'm not sure exactly what the reaction is involving the wood and air, (and so whether those numbers are right) but the masses of the reactants and products add up in a way that doesn't violate the law of conservation of mass: 30+30=25+25+10=60
If all of the quantities stated actually reacted, the law of the conservation of mass shows that the mass of carbon dioxide produced would be 40 - 18 or 22 grams.
68.0 grams due to the law of conservation of mass which states that mass can not be lost but only converted.
27 g Na + H2O = 40 g NaOH + 3 g H2. Law of Conservation of Mass. The reactants must have the same number of grams of the products. 40 + 3 = 43. 43 - 27 = 16 g H2O.
Call the unknown mass x. The Law of Constant Proportions states that x/13 must equal 31/71, or x must be (13)(31)/71 or about 5.7 grams, to the justified number of significant digits.
16 grams? I would purpose that this has a little something to do with the law on conservation of mass. I could always be wrong though...
100 grams pure water can hold about 38 grams of sodium chloride. at the temperature rises nearly boiling 100 C, it increases to about 40 grams per 100 grams of water