# Schedule for: 24w2020 - Alberta Number Theory Days XV

Beginning on Friday, March 22 and ending Sunday March 24, 2024

All times in Banff, Alberta time, MDT (UTC-6).

Friday, March 22 | |
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16:00 - 19:30 |
Check-in begins (Front Desk – Professional Development Centre - open 24 hours) ↓ Note: the Lecture rooms are available after 16:00. (Front Desk – Professional Development Centre) |

17:30 - 19:30 |
Dinner ↓ Dinner is available at Vistas Dining Room between 5:30pm-7:30pm. (Vistas Dining Room) |

19:30 - 22:00 |
Informal gather at BIRS Lounge ↓ Beverages and a small assortment of snacks are available in the lounge on a cash honour system. (Other (See Description)) |

Saturday, March 23 | |
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07:00 - 09:00 |
Breakfast ↓ A buffet breakfast is served daily between 7:00am and 9:00am in the Vistas Dining Room, the top floor of the Sally Borden Building. Note that BIRS does not pay for meals for 2-day workshops. (Vistas Dining Room) |

08:45 - 09:00 |
Welcome Talk by BIRS Staff ↓ A brief introduction to BIRS with important logistical information, technology instruction, and opportunity for participants to ask questions. (TCPL 201) |

09:00 - 09:55 |
Ha Tran: Well-rounded ideals of cyclic cubic and quartic fields ↓ A well-rounded (WR) ideal lattice or a WR ideal is an ideal of a number field for which the associated lattice is well-rounded. WR ideal lattices can be used to investigate various problems such as kissing numbers, sphere packing problems, and Minkowski’s conjecture. They also have a variety of applications to coding theory.
In this talk, we show criteria for when cyclic cubic and cyclic quartic fields have well-rounded ideal lattices. We prove that every cyclic cubic field has at least one well-rounded ideal. We also prove that there exist families of cyclic quartic fields which have well-rounded ideals and explicitly construct their minimal bases.
In addition, for a given prime number $p$, if a cyclic quartic field has a unique prime ideal above $p$, then we provide the necessary and sufficient conditions for that ideal to be well-rounded. (TCPL 201) |

10:05 - 10:30 |
Fatemeh Jalalvand: Geometry of Log-unit lattices ↓ The log-unit lattice of a number field is the image of the units of the ring of integers under Minkowski embedding in $\mathbb{R}^n$. Computing the log-unit lattice (or a fundamental unit) of a number
field is a hard problem and is linked to the problem of computing class numbers which is one of the main tasks of computational algebraic number theory. Knowing the geometry of these lattices may help us to find better ways to compute them.
In this talk, we will discuss the geometry of these lattices. Among different properties, orthogonality and well-roundedness of these lattices are two properties that are more interesting to us. As an example, we will discuss the geometry of log unit lattices of totally real bi-quadratic fields. (TCPL 201) |

10:30 - 10:50 | Coffee Break (TCPL Foyer) |

10:50 - 11:10 |
Sreerupa Bhattacharjee: Parity Bias in Partitions and Restricted Partitions ↓ In 2020, in the article "Parity bias in Partitions", Kim, Kim, and Lovejoy presented a curious result regarding the parity of partitions which stated that the number of partitions of n with more odd parts (than even parts), denoted by $p_o(n)$ is greater than the number of partitions with more even parts (than odd parts), denoted by $p_e(n)$ whenever $n \geq 2$. Their paper majorly used q-series analysis to show this result. Moreover, they conjectured that if the partitions had an added condition that the parts were distinct, an equivalent inequality holds for $n>19$. This talk is based on a joint work with Kaustav Banerjee, Manosij Ghosh Dastidar, Pankaj Jyoti Mahanta and Manjil P. Saikia and I will be proving the first result combinatorially, using injective mappings from the smaller set to the larger set . The conjecture will be proved analogously and I will also show that if we add another condition, that the smallest part of the partition equals 2, the parity bias is reversed for all $n>7$. (TCPL 201) |

11:15 - 11:40 |
Kübra Benli: Sums of proper divisors with missing digits ↓ Let $s(n)$ denote the sum of proper divisors of a positive integer $n$. In 1992, Erdős, Granville, Pomerance, and Spiro conjectured that if $\mathcal{A}$ is a set of integers with asymptotic density zero then the preimage set $s^{-1}(\mathcal{A})$ also has asymptotic density zero. In this talk, we will discuss the verification of this conjecture when $\mathcal{A}$ is the set of integers with missing digits (also known as ellipsephic integers) by giving a quantitative estimate on the size of the set $s^{-1}(\mathcal{A})$. The talk is based on the joint work with Giulia Cesana, Cécile Dartyge, Charlotte Dombrowsky and Lola Thompson. (TCPL 201) |

11:40 - 13:00 |
Lunch ↓ A buffet lunch is served daily between 11:30am and 1:30pm in the Vistas Dining Room, the top floor of the Sally Borden Building. Note that BIRS does not pay for meals for 2-day workshops. (Vistas Dining Room) |

13:00 - 13:20 |
Group Photo ↓ Meet in foyer of TCPL to participate in the BIRS group photo. The photograph will be taken outdoors, so dress appropriately for the weather. Please don't be late, or you might not be in the official group photo! (TCPL Foyer) |

13:20 - 14:15 |
Alvaro Lozano-Robledo: Advances in the theory of Galois representations attached to elliptic curves ↓ In this talk we will give an overview of recent advances in the theory of Galois representations attached to elliptic curves. In particular, we will discuss recent results of the speaker and collaborators (Enrique González-Jiménez, Asimina Hamakiotes, Benjamin York) in the special case of Galois representations attached to elliptic curves with complex multiplication, where we can give a complete classification of the $\ell$-adic representations that occur, together with the arithmetic applications of such classification. (TCPL 201) |

14:20 - 14:45 |
Erik Holmes: (Virtual Talk) Shapes of lattices in number theory ↓ Given a rank-$n$ lattice, $\Lambda$, we define the shape
to be its equivalence class under scaling, rotation, and reflection. The
shape lies in the following double coset space, which we refer to as the
space of shapes of rank $n$ lattices:
\[ \mathcal{S}_n = \text{GL}_n(\mathbb{Z}) \setminus
\text{GL}_n(\mathbb{R}) /\text{GO}_n(\mathbb{R}). \]
Now, given a family of lattices we can ask about where they lie in this
space—maybe they lie on an explicit subspace of the space of shapes, or
some collection of subspaces—and once we know where they lie we can ask
about how they are distributed. This question is studied in different
areas of mathematics but in this talk we will focus on lattices coming
from both the additive and multiplicative structures of number fields.
Specifically, we will talk about the shape of the integral lattice and the
unit lattice in families of number fields with prescribed Galois
conditions. We will approach this from the purview of arithmetic
statistics and some of the open questions in this area of number theory. (Online) |

14:50 - 15:10 |
Golnoush Farzanfard: Zero Density for the Riemann zeta function ↓ The Riemann zeta function is a fundamental function in number theory. The study of zeros of the zeta function has important applications in studying the distribution of the prime numbers. Riemann hypothesis conjectures that all non-trivial zeros lie on the critical line, while the trivial zeros occur at negative
even integers. A less ambitious goal than proving there are no zeros is to deter-
mine an upper bound for the number of non-trivial zeros, denoted as $N(\sigma, T)$, within a specific rectangular region defined by $ \sigma < Rs < 1$ and $0 < Im s < T$ . Previous works by various authors like Ingham and Ramare have provided bounds for $N(\sigma, T)$. In 2018, Habiba Kadiri, Allysa Lumley, and Nathan Ng presented a result that provides a better estimate for $N(\sigma, T)$. In this talk I
will give an overview of the method they provide to deduce an upper bound
for $N(\sigma, T)$. My thesis will improve their upper bound. I will do this by revisiting the argument of Habiba Kadiri, Allysa Lumley, and
Nathan Ng but using some improvements in the estimation of the zeta function. (TCPL 201) |

15:10 - 15:35 | Coffee Break (TCPL Foyer) |

15:35 - 16:30 |
Jason Bell: Transcendental dynamical degrees of birational maps ↓ The degree of a dominant rational map \(f:\mathbb{P}^n\to \mathbb{P}^n\) is the common degree of its homogeneous components. By considering iterates of \(f\), one can form a sequence \({\rm deg}(f^n)\), which is submultiplicative and hence has the property that there is some $\lambda\ge 1$ such that $({\rm deg}(f^n))^{1/n}\to \lambda$. The quantity $\lambda$ is called the first dynamical degree of $f$. We’ll give an overview of the significance of the dynamical degree in complex dynamics and describe an example of a birational self-map of $\mathbb{P}^3$ in which this dynamical degree is provably transcendental. This is joint work with Jeffrey Diller, Mattias Jonsson, and Holly Krieger. (Online) |

16:35 - 17:00 |
Abbas Maarefparvar: On Divisibility of Class Numbers of Cubic Fields by Three ↓ In this talk, inspired by a theorem of Ishida, I show that if a pure cubic number field $K=\mathbb{Q}(\sqrt[3]{m})$, with $m \neq 1$ a cube-free integer, has at least three ramified primes then its class number is divisible by three. The proof is based on the Galois cohomology which can be used also to get an alternative proof for Ishida's result. (TCPL 201) |

17:05 - 17:30 |
James Steele: Categorical Structure in the Local Langlands Correspondence for $p$-adic Groups ↓ The local Langlands correspondence posits finite-to-one map between the set of equivalence classes of smooth irreducible $\mathbb{C}$-representations of a connected reductive algebraic group $G$, over a non-archimedean field $F$, and the so-called Langlands parameters for $G$, which may be thought of as generalisations of the Galois representations associated with the Langlands dual group $\widehat{G}$. The conjecture seeks to uncover a deep relationship between the disciplines of harmonic analysis and number theory through the language of $L$-functions. In his work from the 90’s, David Vogan reformulated the local Langlands correspondence as a bijection between those smooth irreducible representations $G$ and certain irreducible equivariant perverse sheaves on moduli spaces built from the corresponding Langlands parameters. In this talk, we recall how the $L$-functions arise in the Langlands Programme and describe how Vogan’s conception of the theory hints at a possible categorical local Langlands correspondence. (TCPL 201) |

17:35 - 18:00 |
Greg Knapp: Exponential Relations Among Algebraic Integer Conjugates ↓ Products of the form $\alpha_1^{c_1}\cdots\alpha_n^{c_n}$ where the $\alpha_i$ are algebraic are of interest across much of number theory, especially since Baker's results on linear forms in logarithms are widely applicable. In this talk, we explore the scenario where $\alpha_1,\dots,\alpha_n$ consist only of algebraic integer conjugates, though the $\alpha_i$ need not comprise a full set of algebraic integer conjugates. In particular, for some integers $d \geq 2$ and $1 \leq k \leq d-1$ we describe the set $E_{k,d}$ of all tuples $(c_2,\dots,c_{k+1}) \in (\mathbb{R}_{\geq 0})^k$ for which $|\alpha_1||\alpha_2|^{c_2}\cdots|\alpha_{k+1}|^{c_{k+1}} \geq 1$ for every tuple of degree $d$ algebraic integer conjugates $\alpha_1,\dots,\alpha_d$ which are written in descending order of absolute value. Furthermore, for any fixed tuple $(c_2,\dots,c_{k+1}) \in E_{k,d}$, we ask whether or not there exists a tuple of degree $d$ algebraic integer conjugates $\alpha_1,\dots,\alpha_d$ (written in descending order of absolute value) so that $|\alpha_1||\alpha_2|^{c_2}\cdots|\alpha_{k+1}|^{c_{k+1}} = 1$. This talk features joint work with Seda Albayrak, Samprit Ghosh, and Khoa Nguyen. (TCPL 201) |

18:00 - 19:30 |
Dinner ↓ A buffet dinner is served daily between 5:30pm and 7:30pm in the Vistas Dining Room, the top floor of the Sally Borden Building. Note that BIRS does not pay for meals for 2-day workshops. (Vistas Dining Room) |

Sunday, March 24 | |
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07:00 - 09:00 | Breakfast (Vistas Dining Room) |

09:00 - 09:55 |
Chantal David: Equidistribution of quartic Gauss sums at primes arguments ↓ Gauss sums are fundamental objects in number theory. Quadratic Gauss sums were studied by Gauss who gave a simple formula depending only on the argument of the Gauss sums modulo 4. Higher degree Gauss sums behave differently. It was conjectured by Kummer that the cosines of the angles of (normalized) cubic Gauss at prime arguments are not equidistributed, and exhibit a bias towards positive values. This was disproved by Heath-Brown and Patterson in 1979, and they showed that (normalized) cubic Gauss at prime arguments are equidistributed. This was later generalized by Patterson to general \(n\)th-order Gauss sums.
We explain in this talk what is involved in proving those results, and how to improve the results of Patterson for the distribution of quartic Gauss sums at prime arguments. Joint work with A. Dunn, A. Hamieh and H. Lin. (TCPL 201) |

10:05 - 10:30 |
Sarah Dijols: Parabolically induced representations of p-adic $G_2$ distinguished by $SO_4$ ↓ I will explain how the Geometric Lemma allows us to classify parabolically
induced representations of the p-adic group $G_2$ distinguished by $SO_4$.
In particular, I will describe a new approach, in progress, where we use
the structure of the p-adic octonions and their quaternionic subalgebras to
describe the double coset space $P \backslash G_2 / SO_4$, where $P$
stands for the maximal parabolic subgroups of $G_2$. (TCPL 201) |

10:30 - 11:00 |
Checkout by 11 ↓ 2-day workshop participants are welcome to use BIRS facilities (TCPL) until 15:00 on Sunday, although participants are still required to checkout of the guest rooms by 11 M. There is no coffee break service on Sunday afternoon, but self-serve coffee and tea are always available in the 2nd floor lounge, Corbett Hall. (Front Desk – Professional Development Centre) |

10:30 - 11:00 | Coffee Break (TCPL Foyer) |

11:05 - 11:55 |
Jean-Francois Biasse: Norm relations and computational problems in number fields ↓ In this talk, I will discuss recent work on how to reduce computational problems to subfield calculations via the framework of norm relations. For example, this enables efficient class group and $S$-unit group computations in large degree number fields. This also enables the search for small generators of principle ideals in fields of large degree, which has applications to the computation of approximate short vectors in ideal lattices (a topic with applications to cryptography). (TCPL 201) |

12:00 - 13:00 |
Lunch ↓ A buffet lunch is served daily between 11:30am and 1:30pm in the Vistas Dining Room, the top floor of the Sally Borden Building. Note that BIRS does not pay for meals for 2-day workshops. (Vistas Dining Room) |