Let $f$ and $F$ denote the probability density and distribution of a random variable $X$. Assume that $f$ is twice continuously differentiable. Letting $g(k) \equiv \mathbb{E}(X|_{X>k})$, I'm interested in finding distributions (or a class of distributions) for which $g^{\prime \prime}(k)>0$.
I've started by assuming that $X$ follows a distribution from the Pearson family (sufficiently general for my particular application). Letting $\lambda(k)\equiv \frac{f(k)}{\overline{F}(k)}$ denote the inverse Mills ratio,
$$\mathbb{E}(X|_{X>k})=\frac{ \left(-b_0-b_1 k-b_2 k^2\right)}{2 b_2-a_1}\lambda(k)+\mathbb{E}(X)$$ (see Inverse Mills ratio for non normal distributions.)
Thus: $$g^{\prime \prime}(k)=\frac{ -2b_2}{2 b_2-a_1}\lambda(k) + \frac{ -2b_1 -4b_2 k}{2 b_2-a_1}\lambda^{\prime}(k) +\frac{ \left(-b_0-b_1 k-b_2 k^2\right)}{2 b_2-a_1}\lambda^{\prime\prime}(k) $$
I haven't been able to draw any conclusion. Restricting attention to the Pearson class, can you find a general characterization of the distributions with the property $g^{\prime \prime}(k)>0$?
An approach. For an exponential distribution with parameter 1, $g(k)=k+1$ (for $k\ge 0$), so $g''(k)=0$. To get $g''(k)\gt 0$, you need a density function decaying slower than exponential.