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Clearly if $a,b >0$ and $p \in \mathbb{N}$ $ a^{p} + b^{p} \le (a+b)^{p} $ Is there a constante $C = C(p)$ such that if $a,b >0$ and $p \in \mathbb{N}$ then \begin{equation} a^{p} - b^{p} \le C(p)(a-b)^{p} ? \end{equation}

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    @Marcos What lhf said is exactly that with $C(p)=1$.2012-06-01

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It is not possible to find a constant $C(p)$ such that

$ a^{p} - b^{p} \le C(p)(a-b)^{p} $

for all $a,b > 0$ when $p > 1$. For example, let $a = n+1$ and $b = n$. Then

$ a^p-b^p = (n+1)^p - n^p = \sum_{k=0}^{p-1} \binom{p}{k} n^k \to \infty $

but $a-b = 1$.

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Hint: Suppose that $p>1$. Let $b$ be huge and let $a=b+1$.

Added: One might argue that choosing $a-b=1$ is unfair. However, since the proposed inequality is homogeneous, it really makes no difference. For let $b=kx$ and $b=k(x+1)$, where perhaps $k$ is very large. Then $a^p-b^p=k^p\left((x+1)^p-x^p\right)$, and $(a-b)^p=k^p$, so our inequality becomes $(x+1)^p -x^p \le C(p).$ If $x$ is large enough, this cannot hold.