Georgia Institute of Technology School of Mathematics | Georgia Institute of Technology | Atlanta, GA

In independent bond percolation  with parameter p, if one removes the vertices of the infinite cluster (and incident edges), for which values of p does the remaining graph contain an infinite cluster? Grimmett-Holroyd-Kozma used the triangle condition to show that for d > 18, the set of such p contains values strictly larger than the percolation threshold pc. With the work of Fitzner-van der Hofstad, this has been reduced to d > 10. We reprove this result by showing that for d > 10 and some p>pc, there are infinite paths consisting of "shielded"' vertices --- vertices all whose adjacent edges are closed --- which must be in the complement of the infinite cluster. Using numerical values of pc, this bound can be reduced to d > 7. Our methods are elementary and do not require the triangle condition.

Invasion percolation is a stochastic growth model that follows a greedy algorithm. After assigning i.i.d. uniform random variables (weights) to all edges of d-dimensional space, the growth starts at the origin. At each step, we adjoin to the current cluster the edge of minimal weight from its boundary. In '85, Chayes-Chayes-Newman studied the "acceptance profile"' of the invasion: for a given p in [0,1], it is the ratio of the expected number of invaded edges until time n with weight in [p,p+dp] to the expected number of observed edges (those in the cluster or its boundary) with weight in the same interval. They showed that in all dimensions, the acceptance profile an(p) converges to one for p<pc and to zero for p>pc. In this paper, we consider an(p) at the critical point p=pc in two dimensions and show that it is bounded away from zero and one as n goes to infinity.

We define the notion of a knot type having Legendrian large cables and
show that having this property implies that the knot type is not uniformly thick.
Moreover, there are solid tori in this knot type that do not thicken to a solid torus
with integer sloped boundary torus, and that exhibit new phenomena; specifically,
they have virtually overtwisted contact structures. We then show that there exists
an infinite family of ribbon knots that have Legendrian large cables. These knots fail
to be uniformly thick in several ways not previously seen. We also give a general
construction of ribbon knots, and show when they give similar such examples.

The length LC_n of the longest common subsequences of two strings X = (X_1, ... , X_n) and Y = (Y_1, ... , Y_n) is a way to measure the similarity between X and Y. We study the asymptotic behavior of LC_n when the two strings are generated by a hidden Markov model (Z, (X, Y)) and we build upon asymptotic results for LC_n obtained for sequences of i.i.d. random variables. Under some standard assumptions regarding the model we first prove convergence results with rates for E[LC_n]. Then, versions of concentration inequalities for the transversal fluctuations of LC_n are obtained. Finally, we outline a proof for a central limit theorem by building upon previous work and adapting a Stein's method estimate.

We model and analyze the dynamics of religious group membership and size. A groups
is distinguished by its strictness, which determines how much time group members are
expected to spend contributing to the group. Individuals differ in their rate of return for
time spent outside of their religious group. We construct a utility function that individ-
uals attempt to maximize, then find a Nash Equilibrium for religious group participation
with a heterogeneous population. We then model dynamics of group size by including
birth, death, and switching of individuals between groups. Group switching depends on
the strictness preferences of individuals and their probability of encountering members of
other groups. We show that in the case of only two groups one with finite strictness and
the other with zero there is a clear parameter combination that determines whether the
non-zero strictness group can survive over time, which is more difficult at higher strictness
levels. At the same time, we show that a higher than average birthrate can allow even the
highest strictness groups to survive. We also study the dynamics of several groups, gaining
insight into strategic choices of strictness values and displaying the rich behavior of the
model. We then move to the simultaneous-move two-group game where groups can set up
their strictnesses strategically to optimize the goals of the group. Affiliations are assumed
to have three types and each type of group has its own group utility function. Analysis
on the utility functions and Nash equilibria presents different behaviors of various types
of groups. Finally, we numerically simulated the process of new groups entering the reli-
gious marketplace which can be viewed as a sequence of Stackelberg games. Simulation
results show how the different types of religious groups distinguish themselves with regard
to strictness.