The gas that behaves less ideally out of CH 4 or SO 2 is to be determined. Concept introduction: The various kinds of interactions that bind a molecule are known as intermolecular forces. These can be forces of dispersion, dipole–dipole, ion–dipole, and hydrogen bonding. The basic assumption for an ideal gas is that it is free from intermolecular forces. Dispersion forces present in every molecule due to the presence of electron. Dipole–dipole is the attractive force between opposite end of polar molecule. Hydrogen bonding is the attractive force between hydrogen attached to an electronegative atom of one molecule and an electronegative atom of different molecule. Ion–dipole force is the attractive force that due to electrostatic attraction between an ion and a neutral molecule.
The gas that behaves less ideally out of CH 4 or SO 2 is to be determined. Concept introduction: The various kinds of interactions that bind a molecule are known as intermolecular forces. These can be forces of dispersion, dipole–dipole, ion–dipole, and hydrogen bonding. The basic assumption for an ideal gas is that it is free from intermolecular forces. Dispersion forces present in every molecule due to the presence of electron. Dipole–dipole is the attractive force between opposite end of polar molecule. Hydrogen bonding is the attractive force between hydrogen attached to an electronegative atom of one molecule and an electronegative atom of different molecule. Ion–dipole force is the attractive force that due to electrostatic attraction between an ion and a neutral molecule.
Solution Summary: The author explains that the gas that behaves less ideally out of CH_4's tetrahedral shape is to be determined.
The gas that behaves less ideally out of CH4 or SO2 is to be determined.
Concept introduction:
The various kinds of interactions that bind a molecule are known as intermolecular forces. These can be forces of dispersion, dipole–dipole, ion–dipole, and hydrogen bonding. The basic assumption for an ideal gas is that it is free from intermolecular forces.
Dispersion forces present in every molecule due to the presence of electron.
Dipole–dipole is the attractive force between opposite end of polar molecule.
Hydrogen bonding is the attractive force between hydrogen attached to an electronegative atom of one molecule and an electronegative atom of different molecule.
Ion–dipole force is the attractive force that due to electrostatic attraction between an ion and a neutral molecule.
Please help me answer these three questions. Required info should be in data table.
Draw the major organic substitution product or products for (2R,3S)-2-bromo-3-methylpentane reacting with the given
nucleophile. Clearly drawn the stereochemistry, including a wedged bond, a dashed bond and two in-plane bonds at each
stereogenic center. Omit any byproducts.
Bri
CH3CH2O-
(conc.)
Draw the major organic product or products.
Tartaric acid (C4H6O6) is a diprotic weak acid. A sample of 875 mg tartaric acid are dissolved in 100 mL water and titrated with 0.994 M NaOH.
How many mL of NaOH are needed to reach the first equivalence point?
How many mL of NaOH are needed to reach the second equivalence point?
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