1) The number of protons in an element defines its atomic number, and for carbon, it is 6. 2) Number of neutrons in a carbon-12 atom is 6. 3) The mass defect of a carbon-12 atom is 0.09564 amu.
To determine the number of protons and neutrons in a carbon-12 atom and the mass defect, we need to use the given atomic masses of a proton and a neutron.
Number of protons in a carbon-12 atom:
Carbon-12 is the most common isotope of carbon, and it contains 6 protons. The number of protons in an element defines its atomic number, and for carbon, it is 6.
Number of neutrons in a carbon-12 atom:
The mass number of an isotope will be the sum of protons as well as neutrons in its nucleus. For carbon-12, the mass number is 12 amu. Since we already know it has 6 protons, the number of neutrons can be calculated as follows:
Number of neutrons = Mass number-Number of protons
Number of neutrons = 12 amu-6 protons
Number of neutrons = 6 neutrons
Mass defect of a carbon-12 atom:
The mass defect is the difference between the actual mass of a nucleus and the sum of the masses of its individual protons and neutrons.
Mass defect = (Mass of protons + Mass of neutrons) - Actual mass of carbon-12
Mass of protons = 6 protons × 1.00728 amu/proton = 6.04368 amu
Mass of neutrons = 6 neutrons × 1.00866 amu/neutron = 6.05196 amu
Actual mass of carbon-12 = 12.00000 amu
Mass defect = (6.04368 amu + 6.05196 amu) - 12.00000 amu
Mass defect = 12.09564 amu - 12.00000 amu
Mass defect = 0.09564 amu
So, the mass defect of a carbon-12 atom is 0.09564 amu.
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Explanation:
Hydrogen's placement on the periodic table is a subject of debate among chemists. It's in Group 1 because it has one electron in its outermost shell, like the alkali metals. However, it's not a typical alkali metal and has some nonmetallic properties, like being a diatomic gas. Its unique position results from historical reasons and its ability to both lose and gain electrons, making it difficult to classify as a typical metal or nonmetal. Hydrogen's placement reflects its anomalous nature and the periodic table's limitations in fully capturing its properties.
When two fluorine atoms react to produce a fluorine molecule, Energy is released as a bond is formed. The answer is number 4. IT takes energy to form a bond from two atoms that is why energy is releases after the bond is formed.
1. The balanced chemical reaction is:
N2 +3 I2 = 2NI3
We are given the amount of product formed. This will be the starting point of our calculations.
3.58 g NI3 ( 1 mol NI3 / 394.71 g NI3 ) ( 3 mol I2 / 2 mol NI3 ) = 0.014 mol I2.
Thus, 0.014 mol of I2 is needed to form the given amount of NI3.