In The Standard Model of particle physics (SM), the coupling between the leptons and the gauge bosons is independent of the lepton generation. This SM feature is called Lepton Flavour Universality (LFU) and finding processes that violate it could be a sign of new physics (NP). Recent experimental results on LFU tests with b → cℓνℓ and b → sℓℓ transitions show a tension from the theoretical predictions. This thesis aims to test LFU by studying two different processes involving D and B meson decays and using data recorded by the LHCb experiment.
The LHCb experiment is dedicated to perform heavy flavour physics measurements and it is an excellent place to search for indirect evidences of NP. The LHCb experiment collected data from proton-proton collisions in two runs, Run 1 (2010-2012) and Run 2 (2015-2018). The combination of the two data samples corresponds to an integrated luminosity of 9 fb−1. The LHCb Upgrade I detector started to take data in 2022, aiming to record an integrated luminosity of 50 fb−1 (300 fb−1) by the end of 2030 (2040). It is programmed to run at an instantaneous luminosity of 2×1033 cm2 s−1, implying a higher multiplicity of inelastic pp collisions. The LHCb Upgrade I features a fully software-based trigger system, making software development and trigger line migration crucial. In this thesis, aiming to optimise LFU studies in Hb → Hcτ+ντ decays, where the τ lepton is reconstructed by its τ+ → π+π−π+ντ decay and Hb (Hc) is a b-(c-) hadron, trigger lines for these processes are implemented.
The goal of the first LFU test is to measure the branching fraction ratio Rμ/e, defined as Rμ/e = B(D0 → K−μ+νμ)/B(D0 → K−e+νe). D0 candidates are selected from D∗+ → D0π+ decays and the undetected neutrino is accounted for using two reconstruction methods. The value of Rμ/e is obtained as the ratio of the signal D0 → K−ℓ+νℓ decays multiplied by their respective efficiencies. The value of Rμ/e is blinded, resulting in x.xxx ± 0.003 ± 0.013, where the first uncertainty is due to statistics and the second contribution is an estimation of the systematic uncertainty.
The second study aims to test LFU considering B− → D(∗)0τ−ντ decays, where the τ is reconstructed using τ+ → π+π−π+ντ decays. The observables sensitive to LFU R(D0) and R(D∗0), defined as R(D(∗)0) = B(B− → D(∗)0τ−ντ )/B(B− → D(∗)0ℓ−νℓ), are measured simultaneously. To select signal candidates, it is of paramount importance to model the main background contributions. These are due to doubly-charmed decays, B → DDX, where a D+ s , a D+ or a D0 meson decays inclusively into 3 pions. In this thesis, a model to control inclusive D+ s → π+π−π+(X) decays is implemented. This is a reweighting procedure to correct the simulation accounting for the main D+ s → π+π−π+(X) decay modes. The relative branching fractions obtained from the model agree with the PDG [1] within uncertainties. Finally, the blinded results for R(D0) and R(D∗0) are respectively x.xx±0.093±0.034% and x.xx±0.024±0.029%, where the first contribution to the uncertainty is due to statistics and the second is the systematic uncertainty.
This thesis is structured as follows. The introduction is reported in Ch. 1. The hypotheses are reported in detail in Ch. 2, which reports the theoretical principles, and in Ch. 3, which reports the current experimental status. The objectives, methodology and results of the thesis are addressed in the specific sections of the analyses chapters, Ch. 5 and 6. For the the D0 → K−ℓ+νℓ analysis the objectives and methodology are reported in Sec. 5.1 and the results are reported in Sec. 5.9, while for the R(D(∗)0) the objectives and methodology are in Sec. 6.1 and the results in Sec. 6.11. Besides, the description of the LHCb detector and how its data are recorded is reported in Ch. 4.
The LHCb Upgrade I detector description and the trigger selection for the upgrade are reported in Ch. 7. Finally, the thesis conclusions are reported in Ch. 8 and the thesis summary in Galician in Appendix C. All the abbreviations and acronyms used throughout this thesis are listed after the lists of figures and tables. Finally, at the end of the document the bibliography is reported.
No Modelo Est´andar de F´ısica de Part´ıculas (SM) o acoplamento entre os lept´ons e os bos´ons gauge ´e independente da xeraci´on ´a que pertencen os lept´ons. Esta caracter´ıstica do SM ch´amase Universalidade Lept´onica de Sabor (LFU) e atopar procesos que a infrinxan poder´ıa ser un sinal de nova f´ısica (NP). Os resultados experimentais recentes en probas de LFU con transici´ons b → cℓνℓ e b → sℓℓ mostran unha tensi´on coas predici´ons te´oricas. Esta tese pretende probar LFU estudando dous procesos diferentes que implican desintegraci´ons de mes´ons D e B, utilizando os datos tomados polo experimento LHCb do CERN.
O experimento LHCb est´a dese˜nado para realizar medici´ons de part´ıculas pesadas e ´e un excelente lugar para buscar evidencias indirectas de NP. O experimento recolleu datos de colisi´ons prot´on-prot´on en d´uas etapas, Run 1 (2010-2012) e Run 2 (2015-2018).
A combinaci´on das d´uas mostras de datos corresponde a unha luminosidade integrada de 9 fb−1. O detector LHCb Upgrade I comezou a tomar datos en 2022, co obxectivo de acumular unha luminosidade integrada de 50 fb−1 (300 fb−1) para finais de 2030 (2040). O detector est´a programado para funcionar cunha luminosidade instant´anea de 2 × 1033 cm2 s−1, o que implica unha maior multiplicidade das colisi´ons inel´asticas de pp.
O LHCb Upgrade I presenta un sistema de trigger totalmente baseado en software, o que fai que o desenvolvemento do mesmo e o dese˜no das li˜nas de trigger sexan cruciais. Nesta tese, co obxectivo de optimizar os estudos de LFU en desintegraci´ons Hb → Hcτ+ντ , onde o τ lepton ´e reconstru´ıdo pola s´ua desintegraci´on τ+ → π+π−π+ντ e Hb (Hc) ´e un hadr´on con un quark b (c), prop´o˜nense e desenv´olvense li˜nas de trigger para estes procesos.
O obxectivo da primeira proba de LFU desta tese ´e medir a raz´on de fracci´on de ramificaci´on Rμ/e, definida como Rμ/e = B(D0 → K−μ+νμ)/B(D0 → K−e+νe). Os candidatos D0 son seleccionados de desintegraci´ons de D∗+ → D0π+ e o neutrino non detectado ´e contabilizado mediante dous m´etodos de reconstruci´on independentes. O valor de Rμ/e obtense como a relaci´on entre o numero das d´uas canles de sinal D0 → K−ℓ+νℓ multiplicados polas s´uas respectivas eficiencias. O valor de Rμ/e est´a cegado e resulta en x.xxx ± 0, 003 ± 0, 013, onde a primeira incerteza ´e de natureza estat´ıstica e a segunda ´e unha estimaci´on dos efectos sistem´aticos.
O segundo estudo ten como obxectivo probar LFU tendo en conta as desintegraci´ons B → D(∗)0τ+ντ , onde o τ ´e reconstru´ıdo empregando desintegraci´ons τ+ → π+π−π+ντ .
Os observables sensibles a LFU son as raz´ons de fracci´ons de ramificaci´on R(D0) e R(D∗0), definidas como R(D(∗)0) = B(B → ¯D(∗)0τ+ντ )/ B(B → ¯D (∗)0ℓ+νℓ). Estas m´ıdense simult ´aneamente. Para separar os decaimentos do sinal ´e de suma importancia modelar as principais contribuci´ons de fondo. Estas d´ebense a desintegraci´ons dobremente encan tadas, onde un mes´on D+ s , un D+ ou un D0 decae no v´ertice de desintegraci´on 3π. Nesta tese, proponse un modelo para controlar os decaementos inclusivos D+ s → π+π−π+(X).
Este ´e un procedemento de reponderaci´on para corrixir os eventos de simulaci´on polos principais modos de decaimento D+ s → π+π−π+(X). As fracci´ons de ramificaci´on relativas obtidas do modelo concordan co PDG [1] dentro das s´uas incertezas. Finalmente, os resultados cegados para R(D0) e R(D∗0) son, respectivamente, x.xx ± 0.093 ± 0.034% e x.xx ± 0.024 ± 0.029%, onde a primeira contribuci´on ´a incerteza ´e debido ´a estat´ıstica e a segunda ´e a incerteza sistem´atica.
Esta tese estrut´urase do seguinte xeito. A introduci´on aparece en Cap´ıtulo 1. As hip´oteses inf´ormanse en detalle no Cap´ıtulo 2, que informa dos principios te´oricos, e en Cap´ıtulo 3, que informa do estado experimental actual. Os obxectivos, a metodolox´ıa e os resultados da tese ab´ordanse nas secci´ons espec´ıficas dos cap´ıtulos de an´alise, Cap ´ıtulo 5 e Cap´ıtulo 6. Para a an´alise dos decaementos D0 → K−ℓ+νℓ, os obxectivos e a metodolox´ıa ind´ıcanse en Secci´on 5.1 e a os resultados aparecen en Secci´on 5.9, mentres que para o R(D(∗)0) os obxectivos e a metodolox´ıa est´an en Secci´on 6.1 e os resultados en Secci´on 6.11. Ademais, a descrici´on do detector LHCb e como se rexistran os seus datos ind´ıcase en Cap´ıtulo 4. Os detalles do detector LHCb Upgrade I e a selecci´on do trigger para a actualizaci´on do detector inf´ormanse en Cap´ıtulo 7. Finalmente, as conclusi´ons da tese aparecen en Cap´ıtulo 8 e o resumo da tese en galego no Ap´endice C. Todas as abreviaturas e acr´onimos empregados ao longo desta tese est´an listados no despois das listas de figuras e t´aboas. Finalmente, ao final do documento inf´ormase da bibliograf´ıa.
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