Betrayal!!
(Dr. Gyan Singh's Point of View.)
After electrolysis the capsule was in powdered form then I researched for the whole month, wasted my whole leave on it but that was not in vain. After the whole research I found out that it is 'Binilquadoctium' that is Element 2048. I took the remaining capsule and checked it's mass. Then I checked it's molar mass (In chemistry, the molar mass of a chemical compound is defined as the mass of a sample of that compound divided by the amount of substance in that sample, measured in moles. The molar mass is a bulk, not molecular, property of a substance. The molar mass is an average of many instances of the compound, which often vary in mass due to the presence of isotopes. Most commonly, the molar mass is computed from the standard atomic weights and is thus a terrestrial average and a function of the relative abundance of the isotopes of the constituent atoms on Earth. The molar mass is appropriate for converting between the mass of a substance and the amount of a substance for bulk quantities. The molecular weight is commonly used as a synonym of molar mass, particularly for molecular compounds; however, the most authoritative sources define it differently. The formula weight is a synonym of molar mass that is frequently used for non-molecular compounds, such as ionic salts.
The molar mass is an intensive property of the substance, that does not depend on the size of the sample. In the International System of Units (SI), the coherent unit of molar mass is kg/mol. However, for historical reasons, molar masses are almost always expressed in g/mol.
The mole was defined in such a way that the molar mass of a compound, in g/mol, is numerically equal (for all practical purposes) to the average mass of one molecule, in daltons. Thus, for example, the average mass of a molecule of water is about 18.0153 daltons, and the molar mass of water is about 18.0153 g/mol.
For chemical elements without isolated molecules, such as carbon and metals, the molar mass is computed dividing by the number of moles of atoms instead. Thus, for example, the molar mass of iron is about 55.845 g/mol.
Since 1971, SI defined the "amount of substance" as a separate dimension of measurement. Until 2019, the mole was defined as the amount of substance that has as many constituent particles as there are atoms in 12 grams of carbon-12. During that period, the molar mass of carbon-12 was thus exactly 12 g/mol, by definition. Since 2019, a mole of any substance has been redefined in the SI as the amount of that substance containing an exactly defined number of particles, 6.02214076×10 raised to power 23. The molar mass of a compound in g/mol thus is equal to the mass of this number of molecules of the compound in g.
The molar mass of atoms of an element is given by the relative atomic mass of the element multiplied by the molar mass constant. Multiplying by the molar mass constant ensures that the calculation is dimensionally correct: standard relative atomic masses are dimensionless quantities (i.e., pure numbers) whereas molar masses have units (in this case, grams per mole). Molar masses are almost never measured directly. They may be calculated from standard atomic masses, and are often listed in chemical catalogues and on safety data sheets (SDS). Molar masses typically vary between:
1–238 g/mol for atoms of naturally occurring elements;
10–1000 g/mol for simple chemical compounds;
1000–5000000 g/mol for polymers, proteins, DNA fragments, etc.
While molar masses are almost always, in practice, calculated from atomic weights, they can also be measured in certain cases. Such measurements are much less precise than modern mass spectrometric measurements of atomic weights and molecular masses, and are of mostly historical interest. All of the procedures rely on colligative properties, and any dissociation of the compound must be taken into account). After I found the mass of the capsule and molar mass of Binilquadoctium, I calculated the number of moles of Binilquadoctium I have. The capsule contained nearly 5.6 moles that is nearly 3.37232 × 10 raised to the power 23 atoms. Now I knew about how much Binilquadoctium I have so I continued to research about it's properties and uses. Whenever I got chance I researched on it. It took 10 years to complete my research. After my research was over I come to know how powerful Binilquadoctium is. I thought if it goes in wrong hand it have potential to destroy the world so I hid it in my locker. I also hid all my research papers in my highly secured locker. Since I was aware of the potential of Binilquadoctium I did never told anyone about it."
(The story ended)
"So, that's the end of story. Now I request you both, not to tell anyone about this." Dr. Gyan Singh spoke.
"Why would we tell anyone?" Dr. Nitish Khajuria replied.
"Dr. Gyan Singh sir, can we see the research papers, I want to know more about your research regarding element 2048 that is Binilquadoctium?" Dr. Pushkal Chaudhary asked.
"Ok, I will give you those but do not, I repeat do not show them to anyone. Also remember not to tell anyone about it." Dr. Gyan Singh answered.
"Ok Dr. Gyan Singh, I agree to all your terms and conditions." Dr. Pushkal Chaudhary replied.
"Ok, Dr. Pushkal Chaudhary wait here." Dr. Gyan Singh spoke and went to his locker. The locker had twenty six different locks. Dr. Gyan Singh unlocked the locker it took him around 10 minutes to open the locker. Then he brought the research papers and gave it to Dr. Pushkal Chaudhary. Dr. Pushkal Chaudhary read the whole file in two and a half hour. After reading the research papers he placed the file on the table.
"Dr. Gyan, you have wrote that Binilquadoctium can produce a large amount of energy. So, is that true?" Dr. Pushkal Chaudhary asked.
"Yes, Dr. Pushkal." Dr. Gyan Singh answered.
"Then why aren't you giving this to government, it can help us to produce a lot of energy which could help in the survival of human race?" Dr. Pushkal Chaudhary asked.
"Because the amount of Binilquadoctium I have is not enough." Dr. Gyan Singh answered.
"But there may be a lot more on Amanaviye Dweep, so why don't you tell about it to government?" Dr. Pushkal Chaudhary asked.
"Because if humans come to know about it, they will attack Amanaviye Dweep, kill all the citizens of that island. Humans don't care about there parents why will they care about some inhumans." Answered Dr. Gyan Singh.
"Why are you caring so much about them? Don't you think survival of humans is more important?" Dr. Pushkal Chaudhary asked.
"No, I think if there will be no humans, the world would be better." Dr. Gyan Singh replied.
"Ok, so if you are not going to tell anyone about Binilquadoctium and Amanaviye Dweep I will tell them." Dr. Pushkal Chaudhary spoke.
"You don't have any proof. Why would they believe you?" Dr. Gyan Singh asked.
"I have one proof Dr. Gyan Singh." Spoke Pushkal Chaudhary and then he suddenly picked up a liquefying gyn from the table and liquefied Dr. Gyan Singh. Then he took Dr. Gyan Singh's Binilquadoctium capsule and put it in his pocket.
"What did you just do? You killed Dr. Gyan Singh!" Dr. Nitish Khajuria shouted.
"No, actually I liquefied him. That is nearly equivalent to killing because even if we solidify him everything including blood and gases like carbon dioxide and oxygen will also solidify and he would be dead." Dr. Pushkal Chaudhary replied.
"Are you mad! Why did you killed him?" Dr. Nitish Khajuria asked.
"Take a chill pill, we have the research paper and a few moles of Binilquadoctium as proof. If we show this to government and manage to get permission to start an industry on that Amanaviye Dweep to extract Binilquadoctium we will become rich and meanwhile we may become heroes for saving humanity and for this contribution we would be pardoned for lilling Dr. Gyan Singh." Dr. Pushkal Chaudhary answered.
"No, you betrayed him. You can do this to me in future. I will not let you go." Dr. Nitish Khajuria shouted.
"Ok then die!" Dr. Pushkal Chaudhary replied and liquefied Dr. Nitish Khajuria.
TO BE CONTINUED