Is the following true, for each positive integer ## k ##?

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Homework Statement
Is the following true, for each positive integer ## k ##?
## 5\mid \sigma_{1} (5k+4) ##
Briefly justify your answer.
Relevant Equations
None.
Let ## 5k+4=p_{1}^{k_{1}}p_{2}^{k_{2}}\dotsb p_{s}^{k_{s}} ##.
Then ## 5\equiv 0\pmod {5} ## and ## 5k+4\equiv 4\pmod {5} ##.
Thus ## p_{i}^{k_{i}}\not \equiv 0\pmod {5} ## for ## i=1, 2,..., s ##.
Suppose all ## p_{i}^{k_{i}}\equiv 1\pmod {5} ##.
Then ## p_{1}^{k_{1}}p_{2}^{k_{2}}\dotsb p_{s}^{k_{s}}\equiv 1\pmod {5} ##.
Since ## p_{1}^{k_{1}}p_{2}^{k_{2}}\dotsb p_{s}^{k_{s}}\equiv 4\pmod {5} ##,
it follows that ## \exists ## one ## p_{i} ## satisfying ## p_{i}^{k_{i}}\equiv 4\pmod {5} ##.
This means ## p_{i}\equiv 4\pmod {5} ##.
Observe that ## p_{i}^{2}\equiv 16\equiv 1\pmod {5} ## and ## p_{i}^{3}\equiv 4\pmod {5} ##.
If ## p_{i}^{r}\equiv 4\pmod {5} ##, then ## r ## must be odd.
This implies ## p_{i}^{k_{i}}\equiv 4\pmod {5} ## where ## k_{i} ## is odd.
Now we have
\begin{align*}
&\sigma_{1} (p_{i}^{k_{i}})=p_{i}^{k_{i}}+p_{i}^{k_{i}-1}+\dotsb +p_{i}+1\\
&\equiv (4+1+\dotsb +4+1)\pmod {5}\\
&\equiv 0\pmod {5},\\
\end{align*}
because ## p_{i}^{r}\equiv 4\pmod {5} ## if ## r ## is odd and ## p_{i}^{r}\equiv 1\pmod {5} ## if ## r ## is even.
Thus
\begin{align*}
&5\mid \sigma_{1} (p_{i}^{k_{i}})\implies 5\mid [\sigma_{1} (p_{1}^{k_{1}})\dotsb \sigma_{1} (p_{i}^{k_{i}})\dotsb \sigma_{1} (p_{s}^{k_{s}})]\\
&\implies \sigma_{1} (p_{1}^{k_{1}}p_{2}^{k_{2}}\dotsb p_{s}^{k_{s}}).\\
\end{align*}
Therefore, ## 5\mid \sigma_{1} (5k+4) ## for each positive integer ## k ##. And the following is true.
 
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Math100 said:
Homework Statement:: Is the following true, for each positive integer ## k ##?
## 5\mid \sigma_{1} (5k+4) ##
Briefly justify your answer.
Relevant Equations:: None.

Let ## 5k+4=p_{1}^{k_{1}}p_{2}^{k_{2}}\dotsb p_{s}^{k_{s}} ##.
Then ## 5\equiv 0\pmod {5} ## and ## 5k+4\equiv 4\pmod {5} ##.
Thus ## p_{i}^{k_{i}}\not \equiv 0\pmod {5} ## for ## i=1, 2,..., s ##.
Suppose all ## p_{i}^{k_{i}}\equiv 1\pmod {5} ##.
Then ## p_{1}^{k_{1}}p_{2}^{k_{2}}\dotsb p_{s}^{k_{s}}\equiv 1\pmod {5} ##.
Since ## p_{1}^{k_{1}}p_{2}^{k_{2}}\dotsb p_{s}^{k_{s}}\equiv 4\pmod {5} ##,
it follows that ## \exists ## one ## p_{i} ## satisfying ## p_{i}^{k_{i}}\equiv 4\pmod {5} ##.
What about ##p_1,p_2\equiv 2\pmod{5}##?
 
fresh_42 said:
What about ##p_1,p_2\equiv 2\pmod{5}##?
I am not sure. How did you get ## p_{1}, p_{2}\equiv 2\pmod {5} ##?
 
fresh_42 said:
You said, that there must be a prime factor congruent ##4## modulo ##5##. However, you did not cover the case ##2\cdot 2=4.## Assume ##5k+4=p_1^{k_1}\cdot\ldots\cdot p_r^{k_r}.## What if ##p_1^{k_1}\equiv 2\pmod{5}## and ##p_2^{k_2}\equiv 2\pmod{5}##? E.g. consider ##n=14.##
If ## p_{1}^{k_{1}}\equiv 2\pmod {5}, p_{2}^{k_{2}}\equiv 2\pmod {5} ##, then ## p_{1}^{k_{1}}p_{2}^{k_{2}}\equiv 4\pmod {5}.## You said to consider ## n=14 ##, but where does ## n=14 ## come from?
 
Math100 said:
If ## p_{1}^{k_{1}}\equiv 2\pmod {5}, p_{2}^{k_{2}}\equiv 2\pmod {5} ##, then ## p_{1}^{k_{1}}p_{2}^{k_{2}}\equiv 4\pmod {5}.## You said to consider ## n=14 ##, but where does ## n=14 ## come from?
It is an example of why your proof does not work. ##14=2\cdot 5 +4## but no prime divisor or its power is congruent ##4## modulo ##5.##
 
fresh_42 said:
It is an example of why your proof does not work. ##14=2\cdot 5 +4## but no prime divisor or its power is congruent ##4## modulo ##5.##
Then how should I disprove this? By using one of the counterexample(s) you've provided above?
 
fresh_42 said:
I haven't provided any counterexamples. I just said why your proof cannot work. Have you calculated ##\sigma_1(14)?##
No. What's ##\sigma_1(14)?##
 
fresh_42 said:
Do you know what ##\sigma_1## means?
No, what does it mean?
 
fresh_42 said:
It is the function that adds all divisors. So ##\sigma_1(14)=1+2+7+14=24## and ##5\,\nmid\, 24.##
I thought it's only the ## \sigma(n) ##, not the ## \sigma_{1}(n) ##.
 
So ## \sigma_{1}(n) ## is the sum of all n's divisors.
 
Math100 said:
I thought it's only the ## \sigma(n) ##, not the ## \sigma_{1}(n) ##.
This would be a matter of convention. Your problem used the function ##\sigma_1## so you must know what it means. In general, we have ##\sigma_k(n)=\sum_{d|n} d^k.##
Math100 said:
So ## \sigma_{1}(n) ## is the sum of all n's divisors.
Yes. For ##k=1## we get ##\sigma_1(n)=\sum_{d|n} d^1=\sum_{d|n}.##
 
Now I know that ## 5\mid \sigma_{1} (5k+4) ## isn't true for each positive integer ## k ##, because we just tested ## k=2 ##.
 
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fresh_42 said:
This would be a matter of convention. Your problem used the function ##\sigma_1## so you must know what it means. In general, we have ##\sigma_k(n)=\sum_{d|n} d^k.##

Yes. For ##k=1## we get ##\sigma_1(n)=\sum_{d|n} d^1=\sum_{d|n}.##
Then how should I disprove this statement? By letting ## k=2 ## as a counterexample?
 
Disproof:

Here is a counterexample:
Let ## k=6 ##.
Then ## \sigma_{1} (34)=1+2+17+34=54 ##.
Note that ## 5\nmid 54 ##.
Therefore, ## 5\nmid \sigma_{1} (5k+4) ## for each positive integer ## k ##. And the following statement is false.
 
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