ITP-quantumseminare February 2025

itp-quantumseminare@lists.phys.ethz.ch

1 participants
4 discussions

Monday's QIT seminar at 16:45 in HIT K52
by Ladina Hausmann 19 Feb '25

19 Feb '25

Hi all, Next week our visitor Andrzej Dragan will talk about “Covariant quantum field theory of tachyons”, see below for the abstract. The talk will take place on Monday at 16:45 in HIT K 52. Best, Ladina *** Title: Covariant quantum field theory of tachyons Abstract: Three major misconceptions concerning quantized tachyon fields, the energy spectrum unbounded from below, the frame-dependent and unstable vacuum state, and the noncovariant commutation rules, are shown to be a result of misrepresenting the Lorentz group in a too small Hilbert space. By doubling this space we establish an explicitly covariant framework that allows for the proper quantization of the tachyon fields eliminating all of these issues. Our scheme that is derived to maintain the relativistic covariance also singles out the two-state formalism developed by Aharonov et al. [Phys. Rev. 134, B1410 (1964)] as a preferred interpretation of the quantum theory.

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Tuesday's QIT seminar at 17:15 in HIT E41.1
by Ladina Hausmann 13 Feb '25

13 Feb '25

Hi all, Next Tuesday, Tim Ehrensberger will talk about his semester thesis titled “A Relational Measurement Model”. See below for the abstract. The talk will take place at 17:15 in HIT E 41.1. Best, Ladina *** Title: A Relational Measurement Model Abstract: In quantum theory, there are exactly two possible descriptions of a process - collapse and unitary evolution. In the case where the process is a measurement, there is disagreement in the literature as to which of the two descriptions is correct. This disagreement is called the “measurement problem”. The specification of a unitary evolution depends on fixed basis elements of the relevant Hilbert space. In quantum theory, however, these basis elements can only be determined up to a prefactor. In the present work, I argue that this indeterminacy in the basis leads to an additional source of disagreement in the measurement problem. The indeterminacy in the basis means that many different unitary evolutions are possible as descriptions. Interestingly, the average of these possible unitary evolutions gives the same description as collapse. This leads to the following idea: The more of the possible unitary evolutions are considered for this average, the more we can speak of obtaining objective measurement results. This idea is developed in the paper into a kind of meta-interpretation that can resolve the disagreement in the measurement problem in a gradual way.

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No QIT seminar next week
by Ladina Hausmann 06 Feb '25

06 Feb '25

Hi all, there is no QIT seminar planned for next week. Best, Ladina

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Monday's QIT seminar at 16:00 in HIT E 41.1
by Ladina Hausmann 03 Feb '25

03 Feb '25

Hi all, next Monday Kai Ott will present his master thesis at IBM entitled “Decision-tree decoders for general quantum LDPC codes”. The talk will take place at 16:00 in HIT E41.1 and on zoom https://ethz.zoom.us/j/362994444, see below for the abstract. Best, Ladina **** Title: Decision-tree decoders for general quantum LDPC codes Abstract: As diverse approaches to fault-tolerant quantum computing rapidly evolve, flexible decoders for a wide range of settings are becoming increasingly desirable. We introduce Decision Tree Decoders (DTDs), a new class of decoding algorithms for general quantum low-density parity-check (qLDPC) codes that require only sparsity of the binary check matrix. DTDs construct corrections incrementally by adding faults one-by-one, forming a path through a Decision Tree (DT). Each DTD algorithm is defined by its strategy for exploring the tree, with well-designed algorithms typically needing to explore only a small portion before finding a correction. We propose two explicit DTD algorithms for general qLDPC codes: (1) A provable decoder: Guaranteed to find a minimum-weight correction. While it can be slow in the worst case, numerical results show surprisingly fast median-case runtime, exploring only w DT nodes to find a correction for weight-w errors in notable qLDPC codes, such as bivariate bicycle and color codes. This decoder may be valuable for ensemble decoding and determining provable code distances. The tools underpinning this decoder can also be repurposed to compute all minimum-weight logical operators of a code. (2) A heuristic decoder: Achieves higher accuracy and faster performance than BP-OSD on the gross code with circuit noise in realistic parameter regimes.

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ITP-quantumseminare February 2025