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Chapter 21: Problem 82

Poly(lauryl methacrylate) is used as an additive in motor oils to counter the loss of viscosity at high temperature. The structure is The long hydrocarbon chain of poly(lauryl methacrylate) makes the polymer soluble in oil (a mixture of hydrocarbons with mostly 12 or more carbon atoms). At low temperatures the polymer is coiled into balls. At higher temperatures the balls uncoil and the polymer exists as long chains. Explain how this helps control the viscosity of oil.

Short Answer

Expert verified
Poly(lauryl methacrylate) is a temperature-sensitive additive in motor oils that helps control viscosity. It remains soluble in oil due to its long hydrocarbon chains. At low temperatures, the polymer is coiled into balls and doesn't significantly impact oil viscosity. However, at higher temperatures, the polymer uncoils into long chains, increasing the internal resistance of the oil and raising its viscosity. This change counteracts the loss of viscosity at high temperatures, ensuring adequate lubrication and protection for the engine components in various temperature conditions.

Step by step solution

01

Understanding poly(lauryl methacrylate) structure

Poly(lauryl methacrylate) is a polymer with long hydrocarbon chains that make it soluble in oil. As a temperature-sensitive additive, it exhibits different behavior at different temperatures due to its molecular structure.
02

Polymer behavior at low temperatures

At low temperatures, poly(lauryl methacrylate) exists as coiled balls. In this state, the polymer chains are compact and don't have a significant impact on the viscosity of the oil. The oil remains relatively thin and easy to flow as the coiled polymer doesn't create much resistance.
03

Polymer behavior at higher temperatures

When the temperature increases, the poly(lauryl methacrylate) balls uncoil and the polymer exists as long chains. The uncoiled polymer chains increase the internal resistance within the oil, leading to a higher overall viscosity.
04

How poly(lauryl methacrylate) influences oil viscosity at different temperatures

The behavior of poly(lauryl methacrylate) as an additive in motor oils helps control viscosity at different temperatures. At low temperatures, the oil remains less viscous as the polymer is coiled and doesn't interact significantly with the oil. However, at higher temperatures, the uncoiled polymer chains increase the resistance within the oil and raise its viscosity. This change in viscosity helps to counter the loss of viscosity often experienced at high temperatures, ensuring the motor oil maintains adequate lubrication and protection for the engine components in various temperature conditions.

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