Which of the following can be found in an atom's nucleus?A. cells
B. shells
C. electrons
D. protons
Answers
AND NEUTRONS
The atoms in a compound are held together by a chemical bond. The chemical bonds can be either covalent bonds or ionic bonds. Both the bonds are considered very strong bonds. These bonds are mainly formed by sharing of electrons or in the case when one of the elements making the compound donates electron to the other element. The nucleus of each atom attracts to form a strong bond. This property of attraction between the nucleus of the atoms actually helps in forming the chemical bonds.
Related Questions
Whats another name for a group of elements ?
Which family (group) of elements rarely forms chemical bonds with other elements?a. nonmetals b. noble gases c. halogens d. metals
When floral design first emerged as an art form, which technique was emphasized?
The process by which dissolved gases are exchanged between the blood and interstitial fluids is
Answers
Answer
A!! A jogger sweating after a run
Explanation:
Edge
B) The weight of the rock.
C) The hardness of the rock.
D) The composition of the rock.
Answers
Answer:
Its D.
Explanation:
I just took a usatestprep on it and it had the same question.
Answers
Explanation:
More quickly a reactant will disappear, the more quickly it will result in the formation of products. This means that consumption or disappearance of reactants determines the rate of a reaction because only then products will be formed.
Thus, we can conclude that measuring how quickly a reactant disappears is one way to measure the rate of the reaction.
Measuring how quickly a reactant disappears is one way to measure the rate of the reaction. It is because the rate of reaction for product formation and reactants forming is the same. It came to a point where their reaction attains equilibrium.
from atm to 1.80 atm, the
temperature changes from 86.0°C to
30.0°C.
Answers
Answer:
The pressure changes from 2.13 atm to 1.80 atm.
Explanation:
Given data:
Initial pressure = ?
Final pressure = 1.80 atm
Initial temperature = 86.0°C (86.0 + 273 = 359 K)
Final temperature = 30.0°C (30+273 =303 K)
Solution:
According to Gay-Lussac Law,
The pressure of given amount of a gas is directly proportional to its temperature at constant volume and number of moles.
Mathematical relationship:
P₁/T₁ = P₂/T₂
Now we will put the values in formula:
P₁ = P₂T₁ /T₂
P₁ = 1.80 atm × 359 K / 303 K
P₁ = 646.2 atm. K /303 K
P₁ = 2.13 atm
The pressure changes from 2.13 atm to 1.80 atm.
Answer:
2.13
Explanation:
Answers
Explanation:
Molarity is defined as the number of moles per liter of solution.
Mathematically, Molarity =
Since it is given that the molarity of a solution of 14.0 g and volume is 150 mL or 0.15 L.
Whereas number of moles =
So, molar mass of is 97.94 g/mol.
Thus, number of moles =
= 0.142 mol
Therefore, calculate the molarity as follows.
Molarity =
=
= 0.946 mol/L
Hence, we can conclude that molarity of the solution is 0.946 mol/L.
Final answer:
The molarity of the solution is approximately 0.952 M.
Explanation:
To calculate the molarity of the solution, we need to convert the given mass of NH4Br to moles. The molar mass of NH4Br is 97.94 g/mol. So, 14.0 g of NH4Br is equal to 0.143 mol. Next, we convert the given volume of the solution to liters, which is 0.150 L. Finally, we divide the number of moles by the volume in liters to find the molarity.
Molarity (M) = moles/volume (L)
Therefore, the molarity of the solution is approximately 0.952 M.
Learn more about molarity here:
#SPJ6
Answers
H2O + CO2 --> H2CO3
Ratio between water and CO2 is 1:1. So we can say that for every Mole of CO2, we need 1 Mole of water to produce 1 Mole of H2CO3. Thus as n=m/M we can find n = 528/44.01 = 11.997 ~ 12Mol.
Therefore, we need 12 moles of water.
Answer:
12 moles
Explanation:
The reaction will form carbonic acid:
CO₂ + H₂O ⇒ H₂CO₃
For 528 g of CO₂, the number of moles (n) will be:
n = mass/molar mass
n = 528/44.01
n = 12 moles of CO₂
The stoichiometry is 1 mol of CO₂ reacts with 1 mol of H₂O, so 12 moles of CO₂ need 12 moles of H₂O.