Differential Equations MTH 242 Lecture # 07 Dr. Manshoor Ahmed.

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Presentation transcript:

Differential Equations MTH 242 Lecture # 07 Dr. Manshoor Ahmed

Summary (Recall) Applications first order linear differential equations. Basic assumption for growth and decay processes. Governing equation and solution. Problems for growth. Radioactive decay and half-life. Problems related to decay process.

Carbon dating  About 1950, the chemist Willard Libby devised a method of using radio active carbon as a means of determining the approximate age of fossils, such as remains of woods, bones, etc.  The half-life of a radio active carbon is about 5600 years.  The ratio of Carbon 14 to ordinary Carbon in the atmosphere is constant, and this ratio also applies to animals and plants tissue as long as they are alive.  However, when the animals or plants die, the Carbon-14 starts to decay through radioactivity, while the ordinary carbon does not disappear.  Thus knowing the ratio of C-14 to ordinary carbon we can determine an approximation to the year of death.

Problem 2: A fossilized bone is found to contain 1/1000 of the original amount of C–14. Determine the age of the fossil. Solution: Complete your self.

Newton’s Law of cooling

By applying the initial condition Therefore, the final solution becomes

Problem 1: A pot of boiling water is removed from the fire and allowed to cool at room temperature. If after two minutes the temperature of the water in the pot is find. 1. The time it will take the water to be at 2. The temperature of the water after five minutes. Solution:

Problem 2: (Cooling of a cake)

No need to worry, because, the figures clearly show that the cake will be approximately at room temperature in about one-half hour.

Problem # 3: A thermometer is taken from inside of room where the air temperature is. After one minute the temperature reads and after 5 minutes the reading. Find the temperature at t = 0. Solution:

Orthogonal Trajectories

Examples

General Method: To find the orthogonal trajectory of a given family of curves, first we find the differential equation That describes the family and second orthogonal family is given by

Summary Carbon dating (used find the age of fossils). Newton’s law of cooling. Orthogonal trajectories