## ASU Electronic Theses and Dissertations

This collection includes most of the ASU Theses and Dissertations from 2011 to present. ASU Theses and Dissertations are available in downloadable PDF format; however, a small percentage of items are under embargo. Information about the dissertations/theses includes degree information, committee members, an abstract, supporting data or media.

In addition to the electronic theses found in the ASU Digital Repository, ASU Theses and Dissertations can be found in the ASU Library Catalog.

Dissertations and Theses granted by Arizona State University are archived and made available through a joint effort of the ASU Graduate College and the ASU Libraries. For more information or questions about this collection contact or visit the Digital Repository ETD Library Guide or contact the ASU Graduate College at gradformat@asu.edu.

- Bremner, Andrew
- 8 Arizona State University
- 5 Childress, Nancy
- 5 Fishel, Susanna
- 5 Jones, John
- 2 Kaliszewski, Steven
- 2 Paupert, Julien
- more
- 2 Quigg, John
- 2 Spielberg, John
- 1 Barcelo, Helene
- 1 Carrillo, Benjamin
- 1 Childress, Nancy E
- 1 Czygrinow, Andrzej
- 1 Elledge, Shawn Michael
- 1 Franks, Chase Leroyce
- 1 Jones, John W
- 1 Kawski, Matthias
- 1 Kierstead, Henry
- 1 Kim, Younghwan
- 1 Nguyen, Tho Xuan
- 1 Patani, Nura
- 1 Roth, Sanford Gary
- 1 Spielberg, Jack
- 1 Zinzer, Scott

- 8 English

- 8 Public

- Mathematics
- 1 $\lambda$-invariant
- 1 C*-algebras
- 1 C*-correspondences
- 1 Consecutive
- 1 Crossed products
- 1 Diophantine equations
- more
- 1 Dynamical systems
- 1 Gamma-transform
- 1 Graph algebras
- 1 Hilbert bimodules
- 1 Integers
- 1 Iwasawa Invariant
- 1 Iwasawa Theory
- 1 Iwasawa theory
- 1 Iwasawa theory 11R23
- 1 Lambda modules
- 1 Limits
- 1 Pseudo-polynomial
- 1 Squares
- 1 Sums
- 1 Theoretical mathematics
- 1 affine permutation
- 1 algebraic number theory
- 1 cd-index
- 1 cyclic sieving phenomenon
- 1 elliptic curve
- 1 elliptic curve Chabauty
- 1 elliptic curves
- 1 flag enumeration
- 1 matchings
- 1 number theory
- 1 p-adic Valued Measure
- 1 p-adic analysis
- 1 profinite groups 20E18
- 1 the uncrossing partial order

- Microfluidic Models of Tumor-Stroma Interactions to Study the Interplay of Cancer Cells with their Surrounding Microenvironment
- Ain't She Sweet: A Critical Choreographic Study of Identity & Intersectionality
- Suppositions for Desert Modernism: An Architectural Framework Informed by Climate, Natural Light, and Topography
- Concurrent reduction of trichloroethylene and perchlorate in continuous flow-through soil columns
- Design and Fabrication of Fabric ReinforcedTextile Actuators forSoft Robotic Graspers

In this thesis, I investigate the C*-algebras and related constructions that arise from combinatorial structures such as directed graphs and their generalizations. I give a complete characterization of the C*-correspondences associated to directed graphs as well as results about obstructions to a similar characterization of these objects for generalizations of directed graphs. Viewing the higher-dimensional analogues of directed graphs through the lens of product systems, I give a rigorous proof that topological k-graphs are essentially product systems over N^k of topological graphs. I introduce a "compactly aligned" condition for such product systems of graphs and show that this coincides with ...

- Contributors
- Patani, Nura, Kaliszewski, Steven, Quigg, John, et al.
- Created Date
- 2011

In Iwasawa theory, one studies how an arithmetic or geometric object grows as its field of definition varies over certain sequences of number fields. For example, let $F/\mathbb{Q}$ be a finite extension of fields, and let $E:y^2 = x^3 + Ax + B$ with $A,B \in F$ be an elliptic curve. If $F = F_0 \subseteq F_1 \subseteq F_2 \subseteq \cdots F_\infty = \bigcup_{i=0}^\infty F_i$, one may be interested in properties like the ranks and torsion subgroups of the increasing family of curves $E(F_0) \subseteq E(F_1) \subseteq \cdots \subseteq E(F_\infty)$. The main technique for studying this sequence of curves when ...

- Contributors
- Franks, Chase Leroyce, Childress, Nancy, Barcelo, Helene, et al.
- Created Date
- 2011

This dissertation will cover two topics. For the first, let $K$ be a number field. A $K$-derived polynomial $f(x) \in K[x]$ is a polynomial that factors into linear factors over $K$, as do all of its derivatives. Such a polynomial is said to be {\it proper} if its roots are distinct. An unresolved question in the literature is whether or not there exists a proper $\Q$-derived polynomial of degree 4. Some examples are known of proper $K$-derived quartics for a quadratic number field $K$, although other than $\Q(\sqrt{3})$, these fields have quite large discriminant. (The second known field is $\Q(\sqrt{3441})$.) ...

- Contributors
- Carrillo, Benjamin, Jones, John, Bremner, Andrew, et al.
- Created Date
- 2019

In 1959, Iwasawa proved that the size of the $p$-part of the class groups of a $\mathbb{Z}_p$-extension grows as a power of $p$ with exponent ${\mu}p^m+{\lambda}\,m+\nu$ for $m$ sufficiently large. Broadly, I construct conditions to verify if a given $m$ is indeed sufficiently large. More precisely, let $CG_m^i$ (class group) be the $\epsilon_i$-eigenspace component of the $p$-Sylow subgroup of the class group of the field at the $m$-th level in a $\mathbb{Z}_p$-extension; and let $IACG^i_m$ (Iwasawa analytic class group) be ${\mathbb{Z}_p[[T]]/((1+T)^{p^m}-1,f(T,\omega^{1-i}))}$, where $f$ is the associated Iwasawa power series. It is expected that $CG_m^i$ and $IACG^i_m$ be isomorphic, providing us ...

- Contributors
- Elledge, Shawn Michael, Childress, Nancy, Bremner, Andrew, et al.
- Created Date
- 2013

The uncrossing partially ordered set $P_n$ is defined on the set of matchings on $2n$ points on a circle represented with wires. The order relation is $\tau'\leq \tau$ in $P_n$ if and only if $\tau'$ is obtained by resolving a crossing of $\tau$. %This partial order has been studied by Alman-Lian-Tran, Huang-Wen-Xie, Kenyon, and Lam. %The posets $P_n$ emerged from studies of circular planar electrical networks. Circular planar electrical networks are finite weighted undirected graphs embedded into a disk, with boundary vertices and interior vertices. By Curtis-Ingerman-Morrow and de Verdi\`ere-Gitler-Vertigan, the electrical networks can be encoded with response matrices. By ...

- Contributors
- Kim, Younghwan, Fishel, Susanna, Bremner, Andrew, et al.
- Created Date
- 2018

In 1984, Sinnott used $p$-adic measures on $\mathbb{Z}_p$ to give a new proof of the Ferrero-Washington Theorem for abelian number fields by realizing $p$-adic $L$-functions as (essentially) the $Gamma$-transform of certain $p$-adic rational function measures. Shortly afterward, Gillard and Schneps independently adapted Sinnott's techniques to the case of $p$-adic $L$-functions associated to elliptic curves with complex multiplication (CM) by realizing these $p$-adic $L$-functions as $Gamma$-transforms of certain $p$-adic rational function measures. The results in the CM case give the vanishing of the Iwasawa $mu$-invariant for certain $mathbb{Z}_p$-extensions of imaginary quadratic fields constructed from torsion points of CM elliptic curves. In ...

- Contributors
- Zinzer, Scott, Childress, Nancy, Bremner, Andrew, et al.
- Created Date
- 2015

Diophantine arithmetic is one of the oldest branches of mathematics, the search for integer or rational solutions of algebraic equations. Pythagorean triangles are an early instance. Diophantus of Alexandria wrote the first related treatise in the fourth century; it was an area extensively studied by the great mathematicians of the seventeenth century, including Euler and Fermat. The modern approach is to treat the equations as defining geometric objects, curves, surfaces, etc. The theory of elliptic curves (or curves of genus 1, which are much used in modern cryptography) was developed extensively in the twentieth century, and has had great application ...

- Contributors
- Nguyen, Tho Xuan, Bremner, Andrew, Childress, Nancy, et al.
- Created Date
- 2019

ABSTRACT This thesis attempts to answer two questions based upon the historical observation that 1^2 +2^2 +· · ·+24^2 = 70^2. The first question considers changing the starting number of the left hand side of the equation from 1 to any perfect square in the range 1 to 10000. On this question, I attempt to determine which perfect square to end the left hand side of the equation with so that the right hand side of the equation is a perfect square. Mathematically, Question #1 can be written as follows: Given a positive integer r with 1 less than or ...

- Contributors
- Roth, Sanford Gary, Bremner, Andrew, Childress, Nancy E, et al.
- Created Date
- 2010