IceCube Search for Neutrinos Coincident with Compact Binary Mergers from LIGO-Virgo's First Gravitational-Wave Transient Catalog

Using the IceCube Neutrino Observatory, we search for high-energy neutrino emission coincident with compact binary mergers observed by the LIGO and Virgo gravitational wave (GW) detectors during their first and second observing runs. We present results from two searches targeting emission coincident with the sky localization of each gravitational wave event within a 1000 second time window centered around the reported merger time. One search uses a model-independent unbinned maximum likelihood analysis, which uses neutrino data from IceCube to search for point-like neutrino sources consistent with the sky localization of GW events. The other uses the Low-Latency Algorithm for Multi-messenger Astrophysics, which incorporates astrophysical priors through a Bayesian framework and includes LIGO-Virgo detector characteristics to determine the association between the GW source and the neutrinos. No significant neutrino coincidence is seen by either search during the first two observing runs of the LIGO-Virgo detectors. We set upper limits on the time-integrated neutrino emission within the 1000 second window for each of the 11 GW events. These limits range from 0.02-0.7 $\mathrm{GeV~cm^{-2}}$. We also set limits on the total isotropic equivalent energy, $E_{\mathrm{iso}}$, emitted in high-energy neutrinos by each GW event. These limits range from 1.7 $\times$ 10$^{51}$ - 1.8 $\times$ 10$^{55}$ erg. We conclude with an outlook for LIGO-Virgo observing run O3, during which both analyses are running in real time

Characteristics of the diffuse astrophysical electron and tau neutrino flux with six years of IceCube high energy cascade data

We report on the first measurement of the astrophysical neutrino flux using particle showers (cascades) in IceCube data from 2010 -- 2015. Assuming standard oscillations, the astrophysical neutrinos in this dedicated cascade sample are dominated ($\sim 90 \%$) by electron and tau flavors. The flux, observed in the sensitive energy range from $16\,\mathrm{TeV}$ to $2.6\,\mathrm{PeV}$, is consistent with a single power-law model as expected from Fermi-type acceleration of high energy particles at astrophysical sources. We find the flux spectral index to be $\gamma=2.53\pm0.07$ and a flux normalization for each neutrino flavor of $\phi_{astro} = 1.66^{+0.25}_{-0.27}$ at $E_{0} = 100\, \mathrm{TeV}$, in agreement with IceCube's complementary muon neutrino results and with all-neutrino flavor fit results. In the measured energy range we reject spectral indices $\gamma\leq2.28$ at $\ge3\sigma$ significance level. Due to high neutrino energy resolution and low atmospheric neutrino backgrounds, this analysis provides the most detailed characterization of the neutrino flux at energies below $\sim100\,{\rm{TeV}}$ compared to previous IceCube results. Results from fits assuming more complex neutrino flux models suggest a flux softening at high energies and a flux hardening at low energies (p-value $\ge 0.06$). The sizable and smooth flux measured below $\sim 100\,{\rm{TeV}}$ remains a puzzle. In order to not violate the isotropic diffuse gamma-ray background as measured by the Fermi-LAT, it suggests the existence of astrophysical neutrino sources characterized by dense environments which are opaque to gamma-rays.Comment: 4 figures, 4 tables, includes supplementary materia

Multimessenger Gamma-Ray and Neutrino Coincidence Alerts using HAWC and IceCube sub-threshold Data

The High Altitude Water Cherenkov (HAWC) and IceCube observatories, through the Astrophysical Multimessenger Observatory Network (AMON) framework, have developed a multimessenger joint search for extragalactic astrophysical sources. This analysis looks for sources that emit both cosmic neutrinos and gamma rays that are produced in photo-hadronic or hadronic interactions. The AMON system is running continuously, receiving sub-threshold data (i.e. data that is not suited on its own to do astrophysical searches) from HAWC and IceCube, and combining them in real-time. We present here the analysis algorithm, as well as results from archival data collected between June 2015 and August 2018, with a total live-time of 3.0 years. During this period we found two coincident events that have a false alarm rate (FAR) of $<1$ coincidence per year, consistent with the background expectations. The real-time implementation of the analysis in the AMON system began on November 20th, 2019, and issues alerts to the community through the Gamma-ray Coordinates Network with a FAR threshold of $<4$ coincidences per year.Comment: 14 pages, 5 figures, 3 table

Search for Astrophysical Tau-Neutrinos in Six Years of High-Energy Starting Events in the IceCube Detector

Astrophysikalische Neutrinos können in der Wechselwirkung kosmischer Strahlungsteilchen mit Materie oder Photonen nahe derer Quellen entstehen. Die auf der Erde erwartete Flavor-Zusammensetzung kann mögliche Neutrino Produktionsmechanismen einschränken. Tau-Neutrinos sind aufgrund von Flavor-Oszillationen über kosmische Distanzen zu erwarten. Das IceCube Neutrino Observatorium hat astrophysikalische Neutrinos bei Energien zwischen ~60 TeV und ~10 PeV entdeckt. Die gemessene Flavor-Zusammensetzung ist kompatibel mit ~1:1:1, wie vom Pion Produktionsszenario erwartet wird. Die Elektron- und Tau-Neutrino Anteile sind experimentell jedoch weitgehend unbestimmt. Das Ziel der in dieser Dissertation präsentierten Arbeit ist die erste Identifikation eines Tau-Neutrinos in IceCube. Die Suche basiert auf der “Doppel-Kaskaden” Ereignistopologie, die durch zwei aufeinanderfolgende Teilchenschauer aufgrund der Tau-Neutrino Wechselwirkung bzw. des Tau-Zerfalls beschrieben ist. Tau-Neutrinos werden durch die Rekonstruktion dieser Ereignistopologie identifiziert. Der Abstand zwischen beiden Kaskaden entspricht der Tau-Zerfallslänge. Tau-Neutrinos werden oberhalb einer deponierten Energie von ~200 TeV mit einer Effizienz von ~30-50% bei einer Untergrundkontamination von ~5-25% identifiziert. Die Tau-Zerfallslänge wird oberhalb der Auflösungsgrenze von ~10 m auf ~2 m genau bestimmt. In Abhängigkeit des angenommenen Neutrino-Energiespektrums werden ~1-3 identifizierbare Tau-Neutrinos und ~1 Untergrundereignis erwartet. Kein Doppel-Kaskaden Ereignis wird in sechs Jahren experimenteller Daten beobachtet. Der astrophysikalische Tau-Neutrino Fluss wird durch ein oberes Limit von 2.68x10^{-18}(E/100 TeV)^{-2.97} GeV^{-1} cm^{-2} sr^{-1} s^{-1} mit einem Konfidenzniveau von 90% beschränkt. Die gemessene Flavor-Zusammensetzung ~0.51:0.49:0 ist mit dem Pion Produktionsszenario kompatibel. Die Ergebnisse beinhalten die bislang sensitivste Suche nach hochenergetischen Tau-Neutrinos in IceCube.Astrophysical neutrinos may be produced in interactions of cosmic rays with ambient matter or photons near their sources. The observable flavor composition on Earth can constrain possible production scenarios. The appearance of tau-neutrinos due to neutrino oscillations over cosmic baselines is a clear astrophysical signature. A diffuse flux of astrophysical neutrinos between ~60 TeV to ~10 PeV energy was discovered with the IceCube Neutrino Observatory. The observed flavor composition is compatible with ~1:1:1 expected from pion production and decay at the sources, although the experimental constraints on the electron- and tau-neutrino fractions are weak. The work presented in this thesis aims to identify a tau-neutrino interaction in IceCube for the first time. The search is based on the “double cascade” event topology, which is unique to the tau-flavor and characterized by two consecutive particle showers from the charged-current interaction of a tau-neutrino with a nucleus in the ice and the subsequent decay of the tau-lepton. Tau-neutrinos are identified by reconstructing this event topology, for which the distance between both cascades is an estimator of the tau decay length. Above ~200 TeV deposited energy, the identification efficiency is between ~30-50% and the background contamination ~5-25%. The tau decay length is resolved to ~2 m above the experimental resolution limit of ~10 m. This search is expected to yield ~1-3 identifiable tau-neutrino interactions and ~1 background event, depending on the assumed neutrino energy spectrum. No double cascade event is observed in six years of detector data. The astrophysical tau-neutrino flux is constrained by an upper limit of 2.68x10^{-18}(E/100 TeV)^{-2.97} GeV^{-1} cm^{-2} sr^{-1} s^{-1} at 90% confidence level. The measured flavor composition of ~0.51:0.49:0 is compatible with the pion production scenario. The results entail the most sensitive search for highly energetic tau-neutrinos in IceCube so far

Search for Astrophysical Tau Neutrinos in Six Years of High-Energy Starting Events in IceCube

The IceCube Neutrino Observatory at the geographic South Pole is a cubic kilometer Cherenkovdetector built to measure high-energy neutrinos from cosmic sources. It has reported the detection of a diffuse flux of astrophysical neutrinos in the energy range from ∼ 10 TeV to ∼ 10 PeV consistent with a neutrino flavor ratio of $\nu_{e} : \nu_{\mu} : \nu_{\tau} : \simeq$ $1 : 1 : 1$ as expected from pion decay in astrophysical sources after propagation to Earth. However, no tau neutrino has been identified so far. Its observation would be a smoking gun for astrophysical neutrinos and constrain their possible sources. The double bang channel is most promising for identifying tau neutrino interactions. Its event signature is unique to the tau flavor, linking two consecutive particle showers from the charged current interaction of a tau neutrino with an ice nucleus and the subsequent decay of the produced tau lepton. It can only be well resolved at deposited energies above a few 100 TeVwhere the average tau decay length is larger than 20 m. Results are presented from an analysis which uses an optimized direct reconstruction of the double bang event signature using six years of high-energy starting events (HESE) in IceCube. It is the most recent search for tau neutrinos allowing a measurement of the high-energy flavor ratio which, for the first time, is sensitive to thetau neutrino fraction

Improving Future High-Energy Tau Neutrino Searches in IceCube

One of the prime goals of the IceCube Neutrino Observatory is to identify tau neutrinos in the astrophysical neutrino flux. The most recent tau neutrino search is based on the high-energy starting event (HESE) sample and has not found any events that could be classified as tau neutrinos. However, this sample rejects all events in the outer detector region to suppress atmospheric background. Given the low expected number of identifiable tau neutrino events it is desirable to combine different suitable event selections in future searches. Here we present an approach where we use an event selection based on a shower-like event signature rather than a fiducial volume veto. This retains events in the outer parts of the detector while greatly reducing background from track-like events. We identify tau neutrino events by means of direct reconstruction of the double cascade topology. Based on Monte Carlo studies, combining this sample and the HESE sample will enhance the number of identifiable tau neutrino events by∼20-45% for a given observation time at a similar background level

Mg-Al-LDH, Component of the Secondary Phases

The IceCube Neutrino Observatory has observed a diffuse flux of TeV-PeV astrophysical neutrinos at 5.7σ significance from an all-flavor search. The direct detection of tau neutrinos in this flux has yet to occur. Tau neutrinos become distinguishable from other flavors in IceCube at energies above a few hundred TeV, when the cascade from the tau neutrino charged current interaction becomes resolvable from the cascade from the tau lepton decay. This paper presents results from the first dedicated search for tau neutrinos with energies between 214 TeV and 72 PeV in the full IceCube detector. The analysis searches for IceCube optical sensors that observe two separate pulses in a single event - one from the tau neutrino interaction and a second from the tau decay. No candidate events were observed in three years of IceCube data. For the first time, a differential upper limit on astrophysical tau neutrinos is derived around the PeV energy region, which is nearly 3 orders of magnitude lower in energy than previous limits from dedicated tau neutrino searches

Measurement of atmospheric tau neutrino appearance with IceCube DeepCore

We present a measurement of atmospheric tau neutrino appearance from oscillations with three years of data from the DeepCore subarray of the IceCube Neutrino Observatory. This analysis uses atmospheric neutrinos from the full sky with reconstructed energies between 5.6 and 56 GeV to search for a statistical excess of cascadelike neutrino events which are the signature of nu(tau) interactions. For CC thorn NC (CC-only) interactions, we measure the tau neutrino normalization to be 0.73(-0.24)(+0.30) (0.57(-0.30)(+0.36)) and exclude the absence of tau neutrino oscillations at a significance of 3.2 sigma (2.0 sigma) These results are consistent with, and of similar precision to, a confirmatory IceCube analysis also presented, as well as measurements performed by other experiments

Detection of the temporal variation of the Sun's cosmic ray shadow with the IceCube detector

We report on the observation of a deficit in the cosmic ray flux from the directions of the Moon and Sun with five years of data taken by the IceCube Neutrino Observatory. Between May 2010 and May 2011 the IceCube detector operated with 79 strings deployed in the glacial ice at the South Pole, and with 86 strings between May 2011 and May 2015. A binned analysis is used to measure the relative deficit and significance of the cosmic ray shadows. Both the cosmic ray Moon and Sun shadows are detected with high statistical significance ($>10\sigma$) for each year. The results for the Moon shadow are consistent with previous analyses and verify the stability of the IceCube detector over time. This work represents the first observation of the Sun shadow with the IceCube detector. We show that the cosmic ray shadow of the Sun varies with time. These results open the possibility to study cosmic ray transport near the Sun with future data from IceCube

Formation of a Renewable Amine and an Alcohol via Transformations of 3‑Acetamido-5-acetylfuran

The reactivity of the renewable amide 3-acetamido-5-acetylfuran (3A5AF) was explored. Hydrolysis of the amido group to yield the amino-substituted furan, 2-acetyl-4-aminofuran (<b>1</b>), was achieved via NaOH catalysis. Reduction of the acetyl group could be achieved stoichiometrically using NaBH₄ or catalytically via transfer hydrogenation using an Ir catalyst. The product alcohol, 3-acetamido-5-(1-hydroxylethyl)­furan (<b>2</b>), underwent dehydration during analysis via GC-MS to yield an alkene (<b>3</b>). The potential reactivity of 3A5AF and <b>1</b> toward carbon dioxide was studied, but no reaction was observed due to the inherent acidity of 3A5AF and <b>1</b> despite the latter being an amine. The computationally determined p<i>K</i>_a values for 3A5AF and <b>1</b> are reported. Interestingly, in this work, tautomerism of 3A5AF was observed in CD₃OD as evidenced by H–D exchange within the acetyl group