A simple, albeit slightly less useful example perhaps, is when a foundry, or individual metalworker, liquefies metal such as iron, aluminum, or steel so that it can be mixed in with specific forging agents or transferred around a workplace.
In general solids are easier to transport than liquids, but the above metal example is a valid one and the only other one that comes to mind is that of concrete. It is mixed as a liquid and transported as such, but then sprayed or laid down to dry and form a solid surface or filler. <span />
A simple, albeit slightly less useful example perhaps, is when a foundry, or individual metalworker, liquefies metal such as iron, aluminium, or steel so that it can be mixed in with specific forging agents or transferred around a workplace. In general, solids are easier to transport than liquids, but the above metal example is a valid one and the only other one that comes to mind is that of concrete. It is mixed as a liquid and transported as such, but then sprayed or laid down to dry and form a solid surface or filler. Explanation:
Both gases and liquids are<span> fluids, </span>therefore<span> technically, the gas to liquid stuff </span>does not work<span>. </span>
<span>In addition to the LN2 and LO2 </span>the opposite<span> guys mention, </span>organic compound<span> gases </span>also are oftentimes created<span> into liquids. LPG is of a composition that it liquefies at low pressures. LNG is </span>gas that's terribly<span> cold </span>in order that<span> it becomes a liquid </span>in order that tons are<span> shipped </span>during a<span> tanker. </span>
<span>Industrial users </span>additionally build<span> solids into liquids for transport in pipelines. </span>as an example<span>, coal slurries </span>area unit typically<span> used. Coal is ground up into </span>the mud<span>, and mixed with water, </span>and may<span> then be </span>pumped up<span> through pipelines. There </span>are different sorts of slurries<span>, </span>like<span> wood chips/water in paper mills, sand/water mixture in dredging machines.</span>
You have to use everything that is given since you have to know which is the limiting reactant. We find the limiting reactant by calculating the number of moles of each reactant and compare the number of moles. The limiting reactant would be the one that is consumed fully by the reaction.
To calculate the average mass of the element, we take the summation of the product of the isotope and the percent abundance. In this case, the equation becomes 186.207=187*0.626+185*x where x is the percent abundance of 185. The answer is 0.374 or 37.4%. This can also be obtained by 100%-62.6%= 37.4%.
Each nitrogen molecule consists of two atoms of nitrogen that are bonded by a triple covalent bond. This is a direct consequence of the fact that each nitrogen atom has 5 valence electrons. Each atom can thus complete its octet by sharing three electrons.
Explanation:
Sorry i had to look it up i didn't know this answer