- #1
Madam Currie
- 1
- 0
how can we fnd out the half life of sum element?
How to Find the Half-Life of an Element
Click For Summary
SUMMARY
The half-life of a radioactive element can be determined using a Geiger Counter to measure the activity of the sample. The half-life is defined as the time required for the activity to decrease to half its initial value. The correct equation for calculating half-life is T1/2 = ln(2)/k, where k is the decay constant, which is conventionally reported as a positive value. The discussion clarifies common misconceptions regarding the negative sign in the half-life equation and emphasizes the importance of understanding the exponential decay model.
PREREQUISITES- Understanding of radioactive decay and half-life concepts
- Familiarity with Geiger Counters for measuring radiation
- Basic knowledge of logarithmic functions and their properties
- Comprehension of exponential growth and decay models
- Study the principles of radioactive decay in detail
- Learn about the use of Geiger Counters in radiation measurement
- Explore the derivation of the half-life equation T1/2 = ln(2)/k
- Investigate first-order reaction kinetics and their applications
Students, researchers, and professionals in the fields of nuclear physics, chemistry, and environmental science who are interested in understanding radioactive decay and half-life calculations.
- #2
H_man
- 143
- 0
Well firstly you need something to measure the activity of the sample such as a Geiger Counter.
Record this figure.
Then wait till the number of counts has dropped to half the value you measured and hey presto you have the half life. As the half life is the amount of time it takes for the activity to drop by half.
Remember the half life is just the time for half the number of radioactive particles to decay.
Record this figure.
Then wait till the number of counts has dropped to half the value you measured and hey presto you have the half life. As the half life is the amount of time it takes for the activity to drop by half.
Remember the half life is just the time for half the number of radioactive particles to decay.
- #3
mathmike
- 204
- 0
the half life equation is given by ( - 1 / k * ln 2)
- #4
H_man
- 143
- 0
mathmike said:
Mathmike... I think you made an error. The equation for Half Life is actually given by...
<br /> T_\frac{1}{2} = \frac {ln2}{\lambda}<br />
- #5
mathmike
- 204
- 0
no i am right you forgot the negative which represents the fact that it is
decreasing
decreasing
- #6
H_man
- 143
- 0
How can this time be negative?
Also in my humble opinion the ln2 goes on the top as in the equation in my post above.
I am sure a third party can either determine who is correct or where the source of confusion is.
Also in my humble opinion the ln2 goes on the top as in the equation in my post above.
I am sure a third party can either determine who is correct or where the source of confusion is.
- #7
mathmike
- 204
- 0
suppose y has an exponintial growth model so
y = y_0 * e^(kt)
at any time t_1 let
y_1 = y_0 * e^(kt) be the value of y.
and let T denote the amount of time required for y to double in size. thus at time t_1 + T the value of y will be 2y_1 so
2y_1 = y_0 * e^(kt) = y_0 * e^(kt_1) * e ^(kT)
or
2y_1 = y_1 * e^(kT)
thus
2 = e^(kT)
and
ln 2 = kT
therfore doubling time is
T = 1/k * ln 2
halving time is easily derived from this as
T = - 1/k * ln 2
y = y_0 * e^(kt)
at any time t_1 let
y_1 = y_0 * e^(kt) be the value of y.
and let T denote the amount of time required for y to double in size. thus at time t_1 + T the value of y will be 2y_1 so
2y_1 = y_0 * e^(kt) = y_0 * e^(kt_1) * e ^(kT)
or
2y_1 = y_1 * e^(kT)
thus
2 = e^(kT)
and
ln 2 = kT
therfore doubling time is
T = 1/k * ln 2
halving time is easily derived from this as
T = - 1/k * ln 2
- #8
Renge Ishyo
- 281
- 1
I have studied your work a bit Mathmike and believe that the source of "error" in your calculations is due to your treatment of the value of "k" as a negative quantity. The "correct" relation for the T (half life) is (ln 2)/(k) = T (the equation H-man provided). Work:
yfinal = 1/2(y-initial)
1. 1/2(y-initial) = y-initial(e^-kt) (note the minus sign attached to k, your equation lacks this key component)
2. Divide out y initial. Moved e^-kt to the denominator on the right side.
3. 1/2 = 1/e^kt
4. Flipped equations.
5. 2 = e^kt
6. ln (2) = kt
7. t half life = ln (2)/k
K by convention is reported as a *positive* quantity (even if the rate is decreasing for the reaction, the value of k is still reported as being positive). To see why, consider that half life reactions are first order reactions and the integrated rate law for that is:
Ln [Xfinal] = - kt + Ln[Xinitial]
Note that if k was negative and you substituted a negative k into this equation, you would have that value times a negative (if k was negative that equals a *positive* slope ultimately which would not do). So k is reported as a positive number (since they decided by convention to indicate the negative slope in the equation rather than have k be a negative number. They probably did this so that people who just see the algebra without substituting any numbers will recognize that the slope for the function is decreasing).
Your thinking is NOT incorrect though I (finally) recognize. If you substitute a negative k into your equation:
T = - 1/(-k) * ln 2
Then combine.
T = - (ln 2)/(-k)
Cancel the negatives.
T = (ln 2)/(k)
Same thing.
yfinal = 1/2(y-initial)
1. 1/2(y-initial) = y-initial(e^-kt) (note the minus sign attached to k, your equation lacks this key component)
2. Divide out y initial. Moved e^-kt to the denominator on the right side.
3. 1/2 = 1/e^kt
4. Flipped equations.
5. 2 = e^kt
6. ln (2) = kt
7. t half life = ln (2)/k
K by convention is reported as a *positive* quantity (even if the rate is decreasing for the reaction, the value of k is still reported as being positive). To see why, consider that half life reactions are first order reactions and the integrated rate law for that is:
Ln [Xfinal] = - kt + Ln[Xinitial]
Note that if k was negative and you substituted a negative k into this equation, you would have that value times a negative (if k was negative that equals a *positive* slope ultimately which would not do). So k is reported as a positive number (since they decided by convention to indicate the negative slope in the equation rather than have k be a negative number. They probably did this so that people who just see the algebra without substituting any numbers will recognize that the slope for the function is decreasing).
Your thinking is NOT incorrect though I (finally) recognize. If you substitute a negative k into your equation:
T = - 1/(-k) * ln 2
Then combine.
T = - (ln 2)/(-k)
Cancel the negatives.
T = (ln 2)/(k)
Same thing.
Last edited:
Similar threads
- · Replies 2 ·
- · Replies 4 ·
- · Replies 3 ·
- · Replies 20 ·
- · Replies 10 ·
- · Replies 2 ·
- · Replies 3 ·
- · Replies 1 ·