Measurement of electrons from heavy-flavour hadron decays in p-Pb collisions at $\\sqrt{s_{NN}} = 5.02$ TeV using TPC and EMCal detectors with ALICE at LHC

Heavy-ion collisions are a powerful tool to study hot and dense QCD matter, the so-called Quark Gluon Plasma (QGP). Since heavy quarks (charm and beauty) are dominantly produced in the early stages of the collision, they experience the complete evolution of the system. Measurements of electrons from heavy-flavour hadron decay is one possible way to study the interaction of these particles with the QGP. With ALICE at LHC, electrons can be identified with high efficiency and purity. A strong suppression of heavy-flavour decay electrons has been observed at high $p_{m T}$ in Pb-Pb collisions at 2.76 TeV. Measurements in p-Pb collisions are crucial to understand cold nuclear matter effects on heavy-flavour production in heavy-ion collisions. The spectrum of electrons from the decays of hadrons containing charm and beauty was measured in p-Pb collisions at $\\sqrt = 5.02$ TeV. The heavy flavour decay electrons were measured by using the Time Projection Chamber (TPC) and the Electromagnetic Calorimeter (EMCal) detectors from ALICE in the transverse-momentum range $2 < p_ < 20$ GeV/c. The measurements were done in two different data set: minimum bias collisions and data using the EMCal trigger. The non-heavy flavour electron background was removed using an invariant mass method. The results are compatible with one ($R_ \\approx$ 1) and the cold nuclear matter effects in p-Pb collisions are small for the electrons from heavy-flavour hadron decays.

Noise and PSRR improvement technique for TPC readout front-end in CMOS. technology.

ALICE is one of four major experiments of particle accelerator LHC installed in the European laboratory CERN. The management committee of the LHC accelerator has just approved a program update for this experiment. Among the upgrades planned for the coming years of the ALICE experiment is to improve the resolution and tracking efficiency maintaining the excellent particles identification ability, and to increase the read-out event rate to 100 KHz. In order to achieve this, it is necessary to update the Time Projection Chamber detector (TPC) and Muon tracking (MCH) detector modifying the read-out electronics, which is not suitable for this migration. To overcome this limitation the design, fabrication and experimental test of new ASIC named SAMPA has been proposed . This ASIC will support both positive and negative polarities, with 32 channels per chip and continuous data readout with smaller power consumption than the previous versions. This work aims to design, fabrication and experimental test of a readout front-end in 130nm CMOS technology with configurable polarity (positive/negative), peaking time and sensitivity. The new SAMPA ASIC can be used in both chambers (TPC and MCH). The proposed front-end is composed of a Charge Sensitive Amplifier (CSA) and a Semi-Gaussian shaper. In order to obtain an ASIC integrating 32 channels per chip, the design of the proposed front-end requires small area and low power consumption, but at the same time requires low noise. In this sense, a new Noise and PSRR (Power Supply Rejection Ratio) improvement technique for the CSA design without power and area impact is proposed in this work. The analysis and equations of the proposed circuit are presented which were verified by electrical simulations and experimental test of a produced chip with 5 channels of the designed front-end. The measured equivalent noise charge was <550e for 30mV/fC of sensitivity at a input capacitance of 18.5pF. The total core area of the front-end was 2300?m × 150?m, and the measured total power consumption was 9.1mW per channel.

Qualidade de vida relacionada à saúde e uso de tecnologia de comunicação alternativa por pessoas com câncer de cabeça e pescoço

O tratamento do câncer de cabeça e pescoço e a dificuldade de comunicação decorrente da laringectomia interferem de maneira significativa na qualidade de vida das pessoas acometidas, principalmente quanto aos aspectos funcionais, psicológicos e sociais. Este estudo teve como o objetivo avaliar a qualidade de vida relacionada à saúde (QVRS) de pessoas com câncer de cabeça e pescoço. Trata-se de um estudo exploratório com metodologia quantitativa, do tipo transversal. A coleta de dados foi realizada no período de maio a setembro de 2015, com 100 pessoas com câncer de cabeça e pescoço, divididas em dois grupos: G1: pessoas laringectomizadas, G2: pessoas não laringectomizadas. Para isto, foi utilizado um aplicativo de comunicação alternativa instalado em tablet e foram aplicados o Critério de Classificação Econômica Brasil (CCEB) e a escala Functional Assessment Cancer Therapy (FACT-H&N). Para a análise dos dados foram utilizados o teste exato de Fisher, teste de Kruskal-Wallis, Ancova e estatística descritiva. Como resultados observou-se a prevalência de pessoas do sexo masculino, com faixa etária entre 59 e 74 anos , casadas, aposentadas não ativas, com baixa escolaridade e baixo nível socioeconômico. Os sujeitos participantes de ambos os grupos avaliaram sua qualidade de vida global, de um modo geral, como satisfatória sendo que as funções mais acometidas foram: bem estar emocional e bem estar funcional. Quanto às comparações dos escores finais da escala, observa-se que os participantes do G1 apresentaram melhor QVRS do que os do G2 no escore FACT-G total score, o G1 apresentou melhor QVRS do que o G2, enquanto no FACT-H&N Total score e TOI o G2 apresentou resultados ligeiramente melhores, porém sem significância estatística. Quanto ao uso do LIVOX, todos os participantes que apresentaram alguma dificuldade no seu uso tinham mais de 58 anos e se declararam aposentados não ativos (p=0,04). Conclui-se que é importante o oferecimento, tanto no pré quanto no pós operatório, de cuidados que possam avaliar e melhorar a qualidade de vida relacionada à saúde das pessoas com câncer de cabeça e pescoço

Field and laboratory performance evaluation of a field-blended rubber asphalt.

ALICE is one of four major experiments of particle accelerator LHC installed in the European laboratory CERN. The management committee of the LHC accelerator has just approved a program update for this experiment. Among the upgrades planned for the coming years of the ALICE experiment is to improve the resolution and tracking efficiency maintaining the excellent particles identification ability, and to increase the read-out event rate to 100 KHz. In order to achieve this, it is necessary to update the Time Projection Chamber detector (TPC) and Muon tracking (MCH) detector modifying the read-out electronics, which is not suitable for this migration. To overcome this limitation the design, fabrication and experimental test of new ASIC named SAMPA has been proposed . This ASIC will support both positive and negative polarities, with 32 channels per chip and continuous data readout with smaller power consumption than the previous versions. This work aims to design, fabrication and experimental test of a readout front-end in 130nm CMOS technology with configurable polarity (positive/negative), peaking time and sensitivity. The new SAMPA ASIC can be used in both chambers (TPC and MCH). The proposed front-end is composed of a Charge Sensitive Amplifier (CSA) and a Semi-Gaussian shaper. In order to obtain an ASIC integrating 32 channels per chip, the design of the proposed front-end requires small area and low power consumption, but at the same time requires low noise. In this sense, a new Noise and PSRR (Power Supply Rejection Ratio) improvement technique for the CSA design without power and area impact is proposed in this work. The analysis and equations of the proposed circuit are presented which were verified by electrical simulations and experimental test of a produced chip with 5 channels of the designed front-end. The measured equivalent noise charge was <550e for 30mV/fC of sensitivity at a input capacitance of 18.5pF. The total core area of the front-end was 2300?m × 150?m, and the measured total power consumption was 9.1mW per channel.