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Q2908083 Inglês
Stanford physicists make new form of matter
The laser-cooled quantum gas opens exciting new realms of unconventional superconductivity
By Max McClure Stanford University News

Within the exotic world of macroscopic quantum effects, where fluids flow uphill, wires conduct without electrical resistance and magnets levitate, there is an even stranger family of “unconventional” phenomena: strongly interacting fermions, a class of particles that are often very difficult to understand on the quantum level. These materials often defy explanation by current theoretical physics, but hold enormous promise for the development of futuristic technologies as room-temperature superconductors, ultrasensitive microscopes and quantum computation. Last week the scientific world was appalled when a Stanford team made the announcement in Physical Review Letters that they had created the world’s first dipolar quantum fermionic gas– “an entirely new form of quantum matter,” as Stanford applied physics Professor and lead author Benjamin Lev puts it. Lev affirmed that this development represents a major step toward understanding the behavior of these systems of particles. Until now, research efforts had focused on cooling bosons – fundamentally different from fermions, and much easier to work with. But now the Stanford team extended these techniques to gases made of the most magnetic atom: a fermionic isotope of dysprosium with magnetic energies 440 times larger than previously cooled gases. He explained that when the thermal energy of some substances drops below a certain critical point, it used to be impossible to consider its component particles separately since the material becomes strongly correlated and its quantum effects become difficult to understand and study. Nevertheless, making the material out of a gas of atoms allows it to become visible. These quantum gases, the coldest objects known to man, are where researchers can observe zero-viscosity fluids – superfluids – that are mathematical cousins of superconductors. Thus far, the result of the Lev lab’s high-tech efforts is a tiny ball of ultracold quantum dipolar fluid. But the researchers have reason to believe that the humble substance will exhibit the seemingly contradictory characteristics of both crystals and superfluids. This combination could lead to quantum liquid crystals. Or it could yield a supersolid – a hypothetical state of matter that would, in theory at least, be a solid with superfluid characteristics. The researchers have already begun developing a microscope to make use of the dipolar quantum fluid’s unique characteristics. It is the “cryogenic atom chip microscope”, a magnetic probe that should measure magnetic fields with unprecedented sensitivity and resolution. “This kind of probe may even allow for a more stable form of quantum computation that uses exotic quantum matter to process information, known as a topologically protected quantum computer”, said Lev. “So this new approach is really incredibly exciting.” 

Available at: <http://news.stanford.edu/news/2012/june/lev-new- -matter-060512.html>. Retrieved on: 5 June 2012. Adapted.

According to the text, this new material has the opposing qualities of being

Alternativas
Q2908082 Inglês
Stanford physicists make new form of matter
The laser-cooled quantum gas opens exciting new realms of unconventional superconductivity
By Max McClure Stanford University News

Within the exotic world of macroscopic quantum effects, where fluids flow uphill, wires conduct without electrical resistance and magnets levitate, there is an even stranger family of “unconventional” phenomena: strongly interacting fermions, a class of particles that are often very difficult to understand on the quantum level. These materials often defy explanation by current theoretical physics, but hold enormous promise for the development of futuristic technologies as room-temperature superconductors, ultrasensitive microscopes and quantum computation. Last week the scientific world was appalled when a Stanford team made the announcement in Physical Review Letters that they had created the world’s first dipolar quantum fermionic gas– “an entirely new form of quantum matter,” as Stanford applied physics Professor and lead author Benjamin Lev puts it. Lev affirmed that this development represents a major step toward understanding the behavior of these systems of particles. Until now, research efforts had focused on cooling bosons – fundamentally different from fermions, and much easier to work with. But now the Stanford team extended these techniques to gases made of the most magnetic atom: a fermionic isotope of dysprosium with magnetic energies 440 times larger than previously cooled gases. He explained that when the thermal energy of some substances drops below a certain critical point, it used to be impossible to consider its component particles separately since the material becomes strongly correlated and its quantum effects become difficult to understand and study. Nevertheless, making the material out of a gas of atoms allows it to become visible. These quantum gases, the coldest objects known to man, are where researchers can observe zero-viscosity fluids – superfluids – that are mathematical cousins of superconductors. Thus far, the result of the Lev lab’s high-tech efforts is a tiny ball of ultracold quantum dipolar fluid. But the researchers have reason to believe that the humble substance will exhibit the seemingly contradictory characteristics of both crystals and superfluids. This combination could lead to quantum liquid crystals. Or it could yield a supersolid – a hypothetical state of matter that would, in theory at least, be a solid with superfluid characteristics. The researchers have already begun developing a microscope to make use of the dipolar quantum fluid’s unique characteristics. It is the “cryogenic atom chip microscope”, a magnetic probe that should measure magnetic fields with unprecedented sensitivity and resolution. “This kind of probe may even allow for a more stable form of quantum computation that uses exotic quantum matter to process information, known as a topologically protected quantum computer”, said Lev. “So this new approach is really incredibly exciting.” 

Available at: <http://news.stanford.edu/news/2012/june/lev-new- -matter-060512.html>. Retrieved on: 5 June 2012. Adapted.

In the text, the word in bold-face type is similar to the one in italics in

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Q2908081 Inglês
Stanford physicists make new form of matter
The laser-cooled quantum gas opens exciting new realms of unconventional superconductivity
By Max McClure Stanford University News

Within the exotic world of macroscopic quantum effects, where fluids flow uphill, wires conduct without electrical resistance and magnets levitate, there is an even stranger family of “unconventional” phenomena: strongly interacting fermions, a class of particles that are often very difficult to understand on the quantum level. These materials often defy explanation by current theoretical physics, but hold enormous promise for the development of futuristic technologies as room-temperature superconductors, ultrasensitive microscopes and quantum computation. Last week the scientific world was appalled when a Stanford team made the announcement in Physical Review Letters that they had created the world’s first dipolar quantum fermionic gas– “an entirely new form of quantum matter,” as Stanford applied physics Professor and lead author Benjamin Lev puts it. Lev affirmed that this development represents a major step toward understanding the behavior of these systems of particles. Until now, research efforts had focused on cooling bosons – fundamentally different from fermions, and much easier to work with. But now the Stanford team extended these techniques to gases made of the most magnetic atom: a fermionic isotope of dysprosium with magnetic energies 440 times larger than previously cooled gases. He explained that when the thermal energy of some substances drops below a certain critical point, it used to be impossible to consider its component particles separately since the material becomes strongly correlated and its quantum effects become difficult to understand and study. Nevertheless, making the material out of a gas of atoms allows it to become visible. These quantum gases, the coldest objects known to man, are where researchers can observe zero-viscosity fluids – superfluids – that are mathematical cousins of superconductors. Thus far, the result of the Lev lab’s high-tech efforts is a tiny ball of ultracold quantum dipolar fluid. But the researchers have reason to believe that the humble substance will exhibit the seemingly contradictory characteristics of both crystals and superfluids. This combination could lead to quantum liquid crystals. Or it could yield a supersolid – a hypothetical state of matter that would, in theory at least, be a solid with superfluid characteristics. The researchers have already begun developing a microscope to make use of the dipolar quantum fluid’s unique characteristics. It is the “cryogenic atom chip microscope”, a magnetic probe that should measure magnetic fields with unprecedented sensitivity and resolution. “This kind of probe may even allow for a more stable form of quantum computation that uses exotic quantum matter to process information, known as a topologically protected quantum computer”, said Lev. “So this new approach is really incredibly exciting.” 

Available at: <http://news.stanford.edu/news/2012/june/lev-new- -matter-060512.html>. Retrieved on: 5 June 2012. Adapted.

In the second paragraph of the text, it is clear that

Alternativas
Q2908080 Inglês
Stanford physicists make new form of matter
The laser-cooled quantum gas opens exciting new realms of unconventional superconductivity
By Max McClure Stanford University News

Within the exotic world of macroscopic quantum effects, where fluids flow uphill, wires conduct without electrical resistance and magnets levitate, there is an even stranger family of “unconventional” phenomena: strongly interacting fermions, a class of particles that are often very difficult to understand on the quantum level. These materials often defy explanation by current theoretical physics, but hold enormous promise for the development of futuristic technologies as room-temperature superconductors, ultrasensitive microscopes and quantum computation. Last week the scientific world was appalled when a Stanford team made the announcement in Physical Review Letters that they had created the world’s first dipolar quantum fermionic gas– “an entirely new form of quantum matter,” as Stanford applied physics Professor and lead author Benjamin Lev puts it. Lev affirmed that this development represents a major step toward understanding the behavior of these systems of particles. Until now, research efforts had focused on cooling bosons – fundamentally different from fermions, and much easier to work with. But now the Stanford team extended these techniques to gases made of the most magnetic atom: a fermionic isotope of dysprosium with magnetic energies 440 times larger than previously cooled gases. He explained that when the thermal energy of some substances drops below a certain critical point, it used to be impossible to consider its component particles separately since the material becomes strongly correlated and its quantum effects become difficult to understand and study. Nevertheless, making the material out of a gas of atoms allows it to become visible. These quantum gases, the coldest objects known to man, are where researchers can observe zero-viscosity fluids – superfluids – that are mathematical cousins of superconductors. Thus far, the result of the Lev lab’s high-tech efforts is a tiny ball of ultracold quantum dipolar fluid. But the researchers have reason to believe that the humble substance will exhibit the seemingly contradictory characteristics of both crystals and superfluids. This combination could lead to quantum liquid crystals. Or it could yield a supersolid – a hypothetical state of matter that would, in theory at least, be a solid with superfluid characteristics. The researchers have already begun developing a microscope to make use of the dipolar quantum fluid’s unique characteristics. It is the “cryogenic atom chip microscope”, a magnetic probe that should measure magnetic fields with unprecedented sensitivity and resolution. “This kind of probe may even allow for a more stable form of quantum computation that uses exotic quantum matter to process information, known as a topologically protected quantum computer”, said Lev. “So this new approach is really incredibly exciting.” 

Available at: <http://news.stanford.edu/news/2012/june/lev-new- -matter-060512.html>. Retrieved on: 5 June 2012. Adapted.

According to the text, fermions

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Q2908079 Matemática Financeira

Um produto teve seu preço original aumentado em 10% e passou a custar P reais.

Se, em vez de ser aumentado em 10%, o preço original do produto sofresse um desconto de 20%, o produto passaria a custar, em reais,

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Q2908077 Matemática

Em um grande campo, há nove torres e cada uma delas deve ser conectada às demais por meio de cabos.

Se a conexão entre duas torres quaisquer sempre fizer uso de exatamente 20 cabos, quantos cabos serão necessários para ligar todas as nove torres entre si?

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Q2900888 Noções de Informática

A questão deve ser respondida com base nas suítes Microsoft Office 2003 e LibreOffice 3, versões para o Brasil, em ambientes operacionais MS-Windows.

Na configuração padrão do aplicativo Microsoft Word, um texto selecionado para cópia, por meio do comando Copiar do menu Editar, poderá ser colado em outro documento do Word que esteja aberto, utilizando-se o atalho de teclado

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Q2900886 Noções de Informática

A questão deve ser respondida com base nas suítes Microsoft Office 2003 e LibreOffice 3, versões para o Brasil, em ambientes operacionais MS-Windows.

Qual aplicativo da suíte Microsoft Office tem como correspondente o aplicativo Writer da suíte LibreOffice?

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Q2900885 Noções de Informática

A questão deve ser respondida com base nas suítes Microsoft Office 2003 e LibreOffice 3, versões para o Brasil, em ambientes operacionais MS-Windows.

O aplicativo Outlook da suíte Microsoft Office disponibiliza no menu Ferramentas, como padrão, vários comandos para acesso a ferramentas de manipulação de mensagens de correio eletrônico, dentre os quais NÃO se inclui o seguinte:

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Ano: 2012 Banca: CESGRANRIO Órgão: TERMOBAHIA
Q1239394 Química
A fiscalização do Ministério do Trabalho, ao realizar uma diligência numa indústria de produção de verniz de poliuretano, inspeciona o compressor de ar comprimido de 350 litros e pressão de 175 psi. 
Qual o documento que o estabelecimento deve possuir, devidamente atualizado e de fácil acesso para a fiscalização?
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Ano: 2012 Banca: CESGRANRIO Órgão: TERMOBAHIA
Q1229335 Química
Os equipamentos responsáveis pela alimentação contínua de ar aquecido para as ventaneiras de um alto-forno recebem o nome de 
Alternativas
Ano: 2012 Banca: CESGRANRIO Órgão: TERMOBAHIA
Q1226513 Mecânica
Em função das exigências de qualidade de uma junta soldada, um defeito pode ser considerado prejudicial para a utilização dessa junta. Em soldas de aço, as trincas são consideradas fortes concentradores de tensão. 
Em relação à fissuração a frio, o risco de aparecimento de trincas aumenta com o 
Alternativas
Ano: 2012 Banca: CESGRANRIO Órgão: TERMOBAHIA
Q1225494 Metalurgia
Em relação à laminação a quente, a laminação a frio gera 
Alternativas
Ano: 2012 Banca: CESGRANRIO Órgão: TERMOBAHIA
Q1207951 Eletrotécnica
Nos quadros de distribuição em baixa tensão, é estabelecido por norma que a tensão nominal é o valor máximo de tensão que pode ser aplicado entre as barras (fases) do quadro, sem que ocorra arco elétrico ou fuga de corrente. 
Essa característica é verificada através do seguinte ensaio: 
Alternativas
Ano: 2012 Banca: CESGRANRIO Órgão: TERMOBAHIA
Q1197643 Eletrotécnica
De acordo com a NBR 5419, o SPDA externo não isolado do volume a proteger é aquele no qual os
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Ano: 2012 Banca: CESGRANRIO Órgão: TERMOBAHIA
Q1197622 Eletrotécnica
Em um transformador, o enrolamento primário recebe tensão de uma determinada fonte, porém o enrolamento secundário não apresenta tensão, de maneira que a carga ligada a ele não recebe corrente elétrica. Desligando-se a carga e a fonte, um ohmímetro é ligado no enrolamento secundário para que seja verificada a situação desse transformador. 
Se o ohmímetro indicar leitura de resistência infinita, significa que o(s) enrolamento(s) 
Alternativas
Ano: 2012 Banca: CESGRANRIO Órgão: TERMOBAHIA
Q1197572 Eletrotécnica
Qual é o equipamento elétrico utilizado nas instalações elétricas industriais em cargas dinâmicas que precisa manter o torque (conjugado) constante com alterações na rotação quando o motor estiver com carga?
Alternativas
Ano: 2012 Banca: CESGRANRIO Órgão: TERMOBAHIA
Q1197378 Eletrotécnica
De acordo com a NBR 5410:2004, em qualquer ponto de utilização da instalação, a queda de tensão verificada não deve ser superior aos seguintes valores, dados em relação ao valor da tensão nominal da instalação: 
• 7%, calculados a partir dos terminais secundários do transformador MT/BT, no caso de transformador de propriedade da(s) unidade(s) consumidora(s); 
• 7%, calculados a partir dos terminais secundários do transformador MT/BT da empresa distribuidora de eletricidade, quando o ponto de entrega for aí localizado. 
A queda de tensão em percentual (%), nos circuitos terminais, não pode ser superior a 
Alternativas
Ano: 2012 Banca: CESGRANRIO Órgão: TERMOBAHIA
Q1182787 Mecânica
Como se chama a camada de material a ser removida de uma superfície quando esta for usinada? 
Alternativas
Ano: 2012 Banca: CESGRANRIO Órgão: TERMOBAHIA
Q1181530 Química
X, Y, e Z representam três átomos distintos. X e Y são isótopos, X e Z são isótonos, Y e Z são isóbaros, o número de massa de X é 50, e a soma dos números de prótons e a de nêutrons de X, Y, e Z valem, respectivamente, 55 e 97. O número de massa e o número atômico de Y são, respectivamente, 
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Respostas
121: C
122: D
123: B
124: B
125: E
126: B
127: E
128: D
129: A
130: A
131: A
132: A
133: B
134: B
135: B
136: D
137: C
138: A
139: E
140: A