Questões de Concurso
Sobre interpretação de texto | reading comprehension em inglês
Foram encontradas 9.518 questões
Ano: 2014
Banca:
UFSBA
Órgão:
UFBA
Provas:
UFBA - 2014 - UFBA - Assistente Social
|
UFSBA - 2014 - UFBA - Nutricionista |
Q481482
Inglês
Um número cada vez maior de moradores de Los Angeles sintonizam conversas de rádio entre policiais e usam o Twitter para divulgar o que ouvem.
Ano: 2014
Banca:
UFSBA
Órgão:
UFBA
Provas:
UFBA - 2014 - UFBA - Assistente Social
|
UFSBA - 2014 - UFBA - Nutricionista |
Q481481
Inglês
O casal de chineses sabe que, no futuro, terá de arcar com a compra de um apartamento para o filho, a fim de que ele possa conseguir uma esposa.
Q481480
Inglês
It has been a long time since Liu Jinghu and his wife enjoyed a weekend to themselves. Saturdays and Sundays in smoggy Beijing are dedicated to their only child, 2-year-old son Xiaojing: there are early-childhood exercise classes; singing sessions with other families; Lego‑building sprees in a living room scattered with toys. Then there’s the specter of expensive tutoring to get their
5 – toddlerinto a good school and, furtherinto the future, the pressure to buy their son an apartment so he can persuade a woman to marry him. That property burden could cost Liu, a software‑development manager, and his wife, a human-resources specialist, two decades’ worth of salary. Such are the costs of raising a kid today in middle-class China.Liu Jinghu e sua esposa costumam divertir-se apenas nos fins de semana, quando seu único filho, Xiaojing,fica aos cuidados de amigos.
Ano: 2013
Banca:
CEPERJ
Órgão:
SEEDUC-RJ
Prova:
CEPERJ - 2013 - SEDUC-RJ - Professor - Língua Inglesa |
Q480625
Inglês
Texto associado
Now, read through the text below, adapted from The New York
Times and based on its contents
answer question.
The most suitable title for the New York Times text, bearing in mind its overall communicative function, is “Rio:
Ano: 2013
Banca:
CEPERJ
Órgão:
SEEDUC-RJ
Prova:
CEPERJ - 2013 - SEDUC-RJ - Professor - Língua Inglesa |
Q480624
Inglês
Texto associado
Now, read through the text below, adapted from The New York
Times and based on its contents
answer question.
The choice of lexical items in the third paragraph implies that the author:
Ano: 2013
Banca:
CEPERJ
Órgão:
SEEDUC-RJ
Prova:
CEPERJ - 2013 - SEDUC-RJ - Professor - Língua Inglesa |
Q480623
Inglês
Texto associado
Now, read through the text below, adapted from The New York
Times and based on its contents
answer question.
The main communicative function of the second paragraph is to:
Ano: 2013
Banca:
CEPERJ
Órgão:
SEEDUC-RJ
Prova:
CEPERJ - 2013 - SEDUC-RJ - Professor - Língua Inglesa |
Q480616
Inglês
Texto associado
Now, read through the text below, adapted from The New York
Times and based on its contents
answer question.
Demonstrative pronouns in English may be used in different ways to refer to segments of a text or ideas within a text. In the excerpt “This was part of why my 7-year-old daughter and I traveled to Rio in December.”, (lines 8-9) the pronoun this refers to the fact that the writer wanted to:
Ano: 2013
Banca:
CEPERJ
Órgão:
SEEDUC-RJ
Prova:
CEPERJ - 2013 - SEDUC-RJ - Professor - Língua Inglesa |
Q480612
Inglês
Question address both the teaching of English as a foreign language and the Parâmetros Curriculares Nacionais (PCNs)
According to Thornbury (1997:151), a number of factors can determine the selection of vocabulary items for teaching. One of them is Coverage, which refers to how:
According to Thornbury (1997:151), a number of factors can determine the selection of vocabulary items for teaching. One of them is Coverage, which refers to how:
Ano: 2013
Banca:
CEPERJ
Órgão:
SEEDUC-RJ
Prova:
CEPERJ - 2013 - SEDUC-RJ - Professor - Língua Inglesa |
Q480611
Inglês
Question address both the teaching of English as a foreign language and the Parâmetros Curriculares Nacionais (PCNs)
The use of authentic materials in the reading classroom is seen as essential for the development of learner reading skills and, according to Nuttall (1996:172), real texts provide for realistic needs of real people. This said, one of the main advantages of using authentic materials in the classroom is the effect generated on:
The use of authentic materials in the reading classroom is seen as essential for the development of learner reading skills and, according to Nuttall (1996:172), real texts provide for realistic needs of real people. This said, one of the main advantages of using authentic materials in the classroom is the effect generated on:
Ano: 2013
Banca:
CEPERJ
Órgão:
SEEDUC-RJ
Prova:
CEPERJ - 2013 - SEDUC-RJ - Professor - Língua Inglesa |
Q480610
Inglês
Question address both the teaching of English as a foreign language and the Parâmetros Curriculares Nacionais (PCNs)
Theories, assumptions and beliefs about the nature of language and language learning are de?ned at a speci?c level, which encompasses a number of:
Theories, assumptions and beliefs about the nature of language and language learning are de?ned at a speci?c level, which encompasses a number of:
Ano: 2013
Banca:
CEPERJ
Órgão:
SEEDUC-RJ
Prova:
CEPERJ - 2013 - SEDUC-RJ - Professor - Língua Inglesa |
Q480609
Inglês
Question address both the teaching of English as a foreign language and the Parâmetros Curriculares Nacionais (PCNs)
Despite the problems created by big classes, there are things which teachers can do to overcome them (Harmer, 1998:128). The author provides a list of such activities and advises teachers to avoid:
Despite the problems created by big classes, there are things which teachers can do to overcome them (Harmer, 1998:128). The author provides a list of such activities and advises teachers to avoid:
Ano: 2013
Banca:
CEPERJ
Órgão:
SEEDUC-RJ
Prova:
CEPERJ - 2013 - SEDUC-RJ - Professor - Língua Inglesa |
Q480608
Inglês
Question address both the teaching of English as a foreign language and the Parâmetros Curriculares Nacionais (PCNs)
According to the PCNs, one of the contributions of Cognitivism to the teaching of foreign languages is expressed by the:
According to the PCNs, one of the contributions of Cognitivism to the teaching of foreign languages is expressed by the:
Ano: 2013
Banca:
CEPERJ
Órgão:
SEEDUC-RJ
Prova:
CEPERJ - 2013 - SEDUC-RJ - Professor - Língua Inglesa |
Q480607
Inglês
Questio address both the teaching of English as a foreign language and the Parâmetros Curriculares Nacionais (PCNs)
Match each teaching model on the left to its corresponding characteristic on the right:
Teaching models
1- Audio-lingualism teaching
2- Communicative language teaching
3- Grammar-translation
4- Task-based learning
Characteristics
( ) use of authentic texts; emphasis on the development of communication skills
( ) use of bilingual word lists; emphasis on the development of reading and writing skills
( ) use of drills; emphasis on the development of oral skills
( ) use of problem solving and situations; emphasis on the successful completion of activities
The only correct sequence is expressed by:
Match each teaching model on the left to its corresponding characteristic on the right:
Teaching models
1- Audio-lingualism teaching
2- Communicative language teaching
3- Grammar-translation
4- Task-based learning
Characteristics
( ) use of authentic texts; emphasis on the development of communication skills
( ) use of bilingual word lists; emphasis on the development of reading and writing skills
( ) use of drills; emphasis on the development of oral skills
( ) use of problem solving and situations; emphasis on the successful completion of activities
The only correct sequence is expressed by:
Ano: 2013
Banca:
CEPERJ
Órgão:
SEEDUC-RJ
Prova:
CEPERJ - 2013 - SEDUC-RJ - Professor - Língua Inglesa |
Q480606
Inglês
Question address both the teaching of English as a foreign language and the Parâmetros Curriculares Nacionais (PCNs)
. The three basic building blocks for successful foreign language teaching and learning may be described as Engage, Study and Activate (Harmer, 1997:32).
The main aim of Activate is to:
. The three basic building blocks for successful foreign language teaching and learning may be described as Engage, Study and Activate (Harmer, 1997:32).
The main aim of Activate is to:
Ano: 2015
Banca:
CETRO
Órgão:
AMAZUL
Provas:
CETRO - 2015 - AMAZUL - Analista em Desenvolvimento de Tecnologia Nuclear - Advogado
|
CETRO - 2015 - AMAZUL - Analista Administrativo |
CETRO - 2015 - AMAZUL - Engenheiro de Segurança do Trabalho |
CETRO - 2015 - AMAZUL - Assistente Social |
CETRO - 2015 - AMAZUL - Arquiteto |
CETRO - 2015 - AMAZUL - Contador |
CETRO - 2015 - AMAZUL - Cirurgião Dentista |
CETRO - 2015 - AMAZUL - Auditor |
CETRO - 2015 - AMAZUL - Analista de desenvolvimento de sistemas - Tecnólogo |
CETRO - 2015 - AMAZUL - Analista de Recursos Humanos |
CETRO - 2015 - AMAZUL - Tecnólogo em Logística |
CETRO - 2015 - AMAZUL - Enfermeiro do Trabalho |
CETRO - 2015 - AMAZUL - Psicologia |
Q479342
Inglês
Texto associado
Background
The Naval Nuclear Propulsion Program (NNPP) started in 1948. Since that time, the NNPP has provided safe and effective propulsion systems to power submarines, surface combatants, and aircraft carriers. Today, nuclear propulsion enables virtually undetectable US Navy submarines, including the sea-based leg of the strategic triad, and provides essentially inexhaustible propulsion power independent of forward logistical support to both our submarines and aircraft carriers. Over forty percent of the Navy's major combatant ships are nuclear-powered, and because of their demonstrated safety and reliability, these ships have access to seaports throughout the world. The NNPP has consistently sought the best way to affordably meet Navy requirements by evaluating, developing, and delivering a variety of reactor types, fuel systems, and structural materials. The Program has investigated many different fuel systems and reactor design features, and has designed, built, and operated over thirty different reactor designs in over twenty plant types to employ the most promising of these developments in practical applications. Improvements in naval reactor design have allowed increased power and energy to keep pace with the operational requirements of the modern nuclear fleet, while maintaining a conservative design approach that ensures reliability and safety to the crew, the public, and the environment. As just one example of the progress that has been made, the earliest reactor core designs in the NAUTILUS required refueling after about two years while modern reactor cores can last the life of a submarine, or over thirty years without refueling. These improvements have been the result of prudent, conservative engineering, backed by analysis, testing, and prototyping. The NNPP was also a pioneer in developing basic technologies and transferring technology to the civilian nuclear electric power industry. For example, the Program demonstrated the feasibility of commercial nuclear power generation in this country by designing, constructing and operating the Shipping port Atomic Power Station in Pennsylvania and showing the feasibility of a thorium-based breeder reactor.
In: Report on Low Enriched Uranium for Naval Reactor Cores. Page 1. Report to Congress, January 2014. Office of Naval Reactors. US Dept. of Energy. DC 2058 http://fissilematerials.org/library/doe14.pdf
The Naval Nuclear Propulsion Program (NNPP) started in 1948. Since that time, the NNPP has provided safe and effective propulsion systems to power submarines, surface combatants, and aircraft carriers. Today, nuclear propulsion enables virtually undetectable US Navy submarines, including the sea-based leg of the strategic triad, and provides essentially inexhaustible propulsion power independent of forward logistical support to both our submarines and aircraft carriers. Over forty percent of the Navy's major combatant ships are nuclear-powered, and because of their demonstrated safety and reliability, these ships have access to seaports throughout the world. The NNPP has consistently sought the best way to affordably meet Navy requirements by evaluating, developing, and delivering a variety of reactor types, fuel systems, and structural materials. The Program has investigated many different fuel systems and reactor design features, and has designed, built, and operated over thirty different reactor designs in over twenty plant types to employ the most promising of these developments in practical applications. Improvements in naval reactor design have allowed increased power and energy to keep pace with the operational requirements of the modern nuclear fleet, while maintaining a conservative design approach that ensures reliability and safety to the crew, the public, and the environment. As just one example of the progress that has been made, the earliest reactor core designs in the NAUTILUS required refueling after about two years while modern reactor cores can last the life of a submarine, or over thirty years without refueling. These improvements have been the result of prudent, conservative engineering, backed by analysis, testing, and prototyping. The NNPP was also a pioneer in developing basic technologies and transferring technology to the civilian nuclear electric power industry. For example, the Program demonstrated the feasibility of commercial nuclear power generation in this country by designing, constructing and operating the Shipping port Atomic Power Station in Pennsylvania and showing the feasibility of a thorium-based breeder reactor.
In: Report on Low Enriched Uranium for Naval Reactor Cores. Page 1. Report to Congress, January 2014. Office of Naval Reactors. US Dept. of Energy. DC 2058 http://fissilematerials.org/library/doe14.pdf
According to the text, the Naval Nuclear Propulsion Program – NNPP
I. investigates more efficient fuels and reactors for the Navy.
II. is concerned about how to spend the financial resources received.
III. has also contributed with the civilian power industry.
The correct assertion(s) is(are)
I. investigates more efficient fuels and reactors for the Navy.
II. is concerned about how to spend the financial resources received.
III. has also contributed with the civilian power industry.
The correct assertion(s) is(are)
Ano: 2015
Banca:
CETRO
Órgão:
AMAZUL
Provas:
CETRO - 2015 - AMAZUL - Analista em Desenvolvimento de Tecnologia Nuclear - Advogado
|
CETRO - 2015 - AMAZUL - Analista Administrativo |
CETRO - 2015 - AMAZUL - Engenheiro de Segurança do Trabalho |
CETRO - 2015 - AMAZUL - Assistente Social |
CETRO - 2015 - AMAZUL - Arquiteto |
CETRO - 2015 - AMAZUL - Contador |
CETRO - 2015 - AMAZUL - Cirurgião Dentista |
CETRO - 2015 - AMAZUL - Auditor |
CETRO - 2015 - AMAZUL - Analista de desenvolvimento de sistemas - Tecnólogo |
CETRO - 2015 - AMAZUL - Analista de Recursos Humanos |
CETRO - 2015 - AMAZUL - Tecnólogo em Logística |
CETRO - 2015 - AMAZUL - Enfermeiro do Trabalho |
CETRO - 2015 - AMAZUL - Psicologia |
Q479339
Inglês
Texto associado
Background
The Naval Nuclear Propulsion Program (NNPP) started in 1948. Since that time, the NNPP has provided safe and effective propulsion systems to power submarines, surface combatants, and aircraft carriers. Today, nuclear propulsion enables virtually undetectable US Navy submarines, including the sea-based leg of the strategic triad, and provides essentially inexhaustible propulsion power independent of forward logistical support to both our submarines and aircraft carriers. Over forty percent of the Navy's major combatant ships are nuclear-powered, and because of their demonstrated safety and reliability, these ships have access to seaports throughout the world. The NNPP has consistently sought the best way to affordably meet Navy requirements by evaluating, developing, and delivering a variety of reactor types, fuel systems, and structural materials. The Program has investigated many different fuel systems and reactor design features, and has designed, built, and operated over thirty different reactor designs in over twenty plant types to employ the most promising of these developments in practical applications. Improvements in naval reactor design have allowed increased power and energy to keep pace with the operational requirements of the modern nuclear fleet, while maintaining a conservative design approach that ensures reliability and safety to the crew, the public, and the environment. As just one example of the progress that has been made, the earliest reactor core designs in the NAUTILUS required refueling after about two years while modern reactor cores can last the life of a submarine, or over thirty years without refueling. These improvements have been the result of prudent, conservative engineering, backed by analysis, testing, and prototyping. The NNPP was also a pioneer in developing basic technologies and transferring technology to the civilian nuclear electric power industry. For example, the Program demonstrated the feasibility of commercial nuclear power generation in this country by designing, constructing and operating the Shipping port Atomic Power Station in Pennsylvania and showing the feasibility of a thorium-based breeder reactor.
In: Report on Low Enriched Uranium for Naval Reactor Cores. Page 1. Report to Congress, January 2014. Office of Naval Reactors. US Dept. of Energy. DC 2058 http://fissilematerials.org/library/doe14.pdf
The Naval Nuclear Propulsion Program (NNPP) started in 1948. Since that time, the NNPP has provided safe and effective propulsion systems to power submarines, surface combatants, and aircraft carriers. Today, nuclear propulsion enables virtually undetectable US Navy submarines, including the sea-based leg of the strategic triad, and provides essentially inexhaustible propulsion power independent of forward logistical support to both our submarines and aircraft carriers. Over forty percent of the Navy's major combatant ships are nuclear-powered, and because of their demonstrated safety and reliability, these ships have access to seaports throughout the world. The NNPP has consistently sought the best way to affordably meet Navy requirements by evaluating, developing, and delivering a variety of reactor types, fuel systems, and structural materials. The Program has investigated many different fuel systems and reactor design features, and has designed, built, and operated over thirty different reactor designs in over twenty plant types to employ the most promising of these developments in practical applications. Improvements in naval reactor design have allowed increased power and energy to keep pace with the operational requirements of the modern nuclear fleet, while maintaining a conservative design approach that ensures reliability and safety to the crew, the public, and the environment. As just one example of the progress that has been made, the earliest reactor core designs in the NAUTILUS required refueling after about two years while modern reactor cores can last the life of a submarine, or over thirty years without refueling. These improvements have been the result of prudent, conservative engineering, backed by analysis, testing, and prototyping. The NNPP was also a pioneer in developing basic technologies and transferring technology to the civilian nuclear electric power industry. For example, the Program demonstrated the feasibility of commercial nuclear power generation in this country by designing, constructing and operating the Shipping port Atomic Power Station in Pennsylvania and showing the feasibility of a thorium-based breeder reactor.
In: Report on Low Enriched Uranium for Naval Reactor Cores. Page 1. Report to Congress, January 2014. Office of Naval Reactors. US Dept. of Energy. DC 2058 http://fissilematerials.org/library/doe14.pdf
According to the text, choose the alternative that presents how long can modern reactor cores stay without refueling.
Ano: 2015
Banca:
CETRO
Órgão:
AMAZUL
Provas:
CETRO - 2015 - AMAZUL - Analista em Desenvolvimento de Tecnologia Nuclear - Advogado
|
CETRO - 2015 - AMAZUL - Analista Administrativo |
CETRO - 2015 - AMAZUL - Engenheiro de Segurança do Trabalho |
CETRO - 2015 - AMAZUL - Assistente Social |
CETRO - 2015 - AMAZUL - Arquiteto |
CETRO - 2015 - AMAZUL - Contador |
CETRO - 2015 - AMAZUL - Cirurgião Dentista |
CETRO - 2015 - AMAZUL - Auditor |
CETRO - 2015 - AMAZUL - Analista de desenvolvimento de sistemas - Tecnólogo |
CETRO - 2015 - AMAZUL - Analista de Recursos Humanos |
CETRO - 2015 - AMAZUL - Tecnólogo em Logística |
CETRO - 2015 - AMAZUL - Enfermeiro do Trabalho |
CETRO - 2015 - AMAZUL - Psicologia |
Q479337
Inglês
Texto associado
Read the text below to answer the questions 11-15.
NASA Researchers Studying Advanced Nuclear Rocket Technologies
January 9, 2013
By using an innovative test facility at NASA’s Marshall Space Flight Center in Huntsville, Ala., researchers are able to use non-nuclear materials to simulate nuclear thermal rocket fuels - ones capable of propelling bold new exploration missions to the Red Planet and beyond. The Nuclear Cryogenic Propulsion Stage team is tackling a three-year project to demonstrate the viability of nuclear propulsion system technologies. A nuclear rocket engine uses a nuclear reactor to heat hydrogen to very high temperatures, which expands through a nozzle to generate thrust. Nuclear rocket engines generate higher thrust and are more than twice as efficient as conventional chemical rocket engines.
The team recently used Marshall’s Nuclear Thermal Rocket Element Environmental Simulator, or NTREES, to perform realistic, non-nuclear testing of various materials for nuclear thermal rocket fuel elements. In an actual reactor, the fuel elements would contain uranium, but no radioactive materials are used during the NTREES tests. Among the fuel options are a graphite composite and a “cermet” composite - a blend of ceramics and metals. Both materials were investigated in previous NASA and U.S. Department of Energy research efforts.
Nuclear-powered rocket concepts are not new; the United States conducted studies and significant ground testing from 1955 to 1973 to determine the viability of nuclear propulsion systems, but ceased testing when plans for a crewed Mars mission were deferred.
The NTREES facility is designed to test fuel elements and materials in hot flowing hydrogen, reaching pressures up to 1,000 pounds per square inch and temperatures of nearly 5,000 degrees Fahrenheit - conditions that simulate space-based nuclear propulsion systems to provide baseline data critical to the research team.
“This is vital testing, helping us reduce risks and costs associated with advanced propulsion technologies and ensuring excellent performance and results as we progress toward further system development and testing,” said Mike Houts, project manager for nuclear systems at Marshall.
A first-generation nuclear cryogenic propulsion system could propel human explorers to Mars more efficiently than conventional spacecraft, reducing crews’ exposure to harmful space radiation and other effects of long-term space missions. It could also transport heavy cargo and science payloads. Further development and use of a first-generation nuclear system could also provide the foundation for developing extremely advanced propulsion technologies and systems in the future - ones that could take human crews even farther into the solar system.
Building on previous, successful research and using the NTREES facility, NASA can safely and thoroughly test simulated nuclear fuel elements of various sizes, providing important test data to support the design of a future Nuclear Cryogenic Propulsion Stage. A nuclear cryogenic upper stage - its liquid- hydrogen propellant chilled to super-cold temperatures for launch - would be designed to be safe during all mission phases and would not be started until the spacecraft had reached a safe orbit and was ready to begin its journey to a distant destination. Prior to startup in a safe orbit, the nuclear system would be cold, with no fission products generated from nuclear operations, and with radiation below significant levels.
“The information we gain using this test facility will permit engineers to design rugged, efficient fuel elements and nuclear propulsion systems,” said NASA researcher Bill Emrich, who manages the NTREES facility at Marshall. “It’s our hope that it will enable us to develop a reliable, cost-effective nuclear rocket engine in the not-too-distant future."
The Nuclear Cryogenic Propulsion Stage project is part of the Advanced Exploration Systems program, which is managed by NASA’s Human Exploration and Operations Mission Directorate and includes participation by the U.S. Department of Energy. The program, which focuses on crew safety and mission operations in deep space, seeks to pioneer new approaches for rapidly developing prototype systems, demonstrating key capabilities and validating operational concepts for future vehicle development and human missions beyond Earth orbit.
Marshall researchers are partnering on the project with NASA’s Glenn Research Center in Cleveland, Ohio; NASA’s Johnson Space Center in Houston; Idaho National Laboratory in Idaho Falls; Los Alamos National Laboratory in Los Alamos, N.M.; and Oak Ridge National Laboratory in Oak Ridge, Tenn.
The Marshall Center leads development of the Space Launch System for NASA. The Science & Technology Office at Marshall strives to apply advanced concepts and capabilities to the research, development and management of a broad spectrum of NASA programs, projects and activities that fall at the very intersection of science and exploration, where every discovery and achievement furthers scientific knowledge and understanding, and supports the agency’s ambitious mission to expand humanity’s reach across the solar system. The NTREES test facility is just one of numerous cutting-edge space propulsion and science research facilities housed in the state-of- the-art Propulsion Research & Development Laboratory at Marshall, contributing to development of the Space Launch System and a variety of other NASA programs and missions.
Available in: http://www.nasa.gov
NASA Researchers Studying Advanced Nuclear Rocket Technologies
January 9, 2013
By using an innovative test facility at NASA’s Marshall Space Flight Center in Huntsville, Ala., researchers are able to use non-nuclear materials to simulate nuclear thermal rocket fuels - ones capable of propelling bold new exploration missions to the Red Planet and beyond. The Nuclear Cryogenic Propulsion Stage team is tackling a three-year project to demonstrate the viability of nuclear propulsion system technologies. A nuclear rocket engine uses a nuclear reactor to heat hydrogen to very high temperatures, which expands through a nozzle to generate thrust. Nuclear rocket engines generate higher thrust and are more than twice as efficient as conventional chemical rocket engines.
The team recently used Marshall’s Nuclear Thermal Rocket Element Environmental Simulator, or NTREES, to perform realistic, non-nuclear testing of various materials for nuclear thermal rocket fuel elements. In an actual reactor, the fuel elements would contain uranium, but no radioactive materials are used during the NTREES tests. Among the fuel options are a graphite composite and a “cermet” composite - a blend of ceramics and metals. Both materials were investigated in previous NASA and U.S. Department of Energy research efforts.
Nuclear-powered rocket concepts are not new; the United States conducted studies and significant ground testing from 1955 to 1973 to determine the viability of nuclear propulsion systems, but ceased testing when plans for a crewed Mars mission were deferred.
The NTREES facility is designed to test fuel elements and materials in hot flowing hydrogen, reaching pressures up to 1,000 pounds per square inch and temperatures of nearly 5,000 degrees Fahrenheit - conditions that simulate space-based nuclear propulsion systems to provide baseline data critical to the research team.
“This is vital testing, helping us reduce risks and costs associated with advanced propulsion technologies and ensuring excellent performance and results as we progress toward further system development and testing,” said Mike Houts, project manager for nuclear systems at Marshall.
A first-generation nuclear cryogenic propulsion system could propel human explorers to Mars more efficiently than conventional spacecraft, reducing crews’ exposure to harmful space radiation and other effects of long-term space missions. It could also transport heavy cargo and science payloads. Further development and use of a first-generation nuclear system could also provide the foundation for developing extremely advanced propulsion technologies and systems in the future - ones that could take human crews even farther into the solar system.
Building on previous, successful research and using the NTREES facility, NASA can safely and thoroughly test simulated nuclear fuel elements of various sizes, providing important test data to support the design of a future Nuclear Cryogenic Propulsion Stage. A nuclear cryogenic upper stage - its liquid- hydrogen propellant chilled to super-cold temperatures for launch - would be designed to be safe during all mission phases and would not be started until the spacecraft had reached a safe orbit and was ready to begin its journey to a distant destination. Prior to startup in a safe orbit, the nuclear system would be cold, with no fission products generated from nuclear operations, and with radiation below significant levels.
“The information we gain using this test facility will permit engineers to design rugged, efficient fuel elements and nuclear propulsion systems,” said NASA researcher Bill Emrich, who manages the NTREES facility at Marshall. “It’s our hope that it will enable us to develop a reliable, cost-effective nuclear rocket engine in the not-too-distant future."
The Nuclear Cryogenic Propulsion Stage project is part of the Advanced Exploration Systems program, which is managed by NASA’s Human Exploration and Operations Mission Directorate and includes participation by the U.S. Department of Energy. The program, which focuses on crew safety and mission operations in deep space, seeks to pioneer new approaches for rapidly developing prototype systems, demonstrating key capabilities and validating operational concepts for future vehicle development and human missions beyond Earth orbit.
Marshall researchers are partnering on the project with NASA’s Glenn Research Center in Cleveland, Ohio; NASA’s Johnson Space Center in Houston; Idaho National Laboratory in Idaho Falls; Los Alamos National Laboratory in Los Alamos, N.M.; and Oak Ridge National Laboratory in Oak Ridge, Tenn.
The Marshall Center leads development of the Space Launch System for NASA. The Science & Technology Office at Marshall strives to apply advanced concepts and capabilities to the research, development and management of a broad spectrum of NASA programs, projects and activities that fall at the very intersection of science and exploration, where every discovery and achievement furthers scientific knowledge and understanding, and supports the agency’s ambitious mission to expand humanity’s reach across the solar system. The NTREES test facility is just one of numerous cutting-edge space propulsion and science research facilities housed in the state-of- the-art Propulsion Research & Development Laboratory at Marshall, contributing to development of the Space Launch System and a variety of other NASA programs and missions.
Available in: http://www.nasa.gov
Consider the verb tense in the following sentence taken from the text.
“Nuclear-powered rocket concepts are not new.”
Choose the alternative in which the extract is in the same verb tense as the one above.
“Nuclear-powered rocket concepts are not new.”
Choose the alternative in which the extract is in the same verb tense as the one above.
Ano: 2015
Banca:
CETRO
Órgão:
AMAZUL
Provas:
CETRO - 2015 - AMAZUL - Analista em Desenvolvimento de Tecnologia Nuclear - Advogado
|
CETRO - 2015 - AMAZUL - Analista Administrativo |
CETRO - 2015 - AMAZUL - Engenheiro de Segurança do Trabalho |
CETRO - 2015 - AMAZUL - Assistente Social |
CETRO - 2015 - AMAZUL - Arquiteto |
CETRO - 2015 - AMAZUL - Contador |
CETRO - 2015 - AMAZUL - Cirurgião Dentista |
CETRO - 2015 - AMAZUL - Auditor |
CETRO - 2015 - AMAZUL - Analista de desenvolvimento de sistemas - Tecnólogo |
CETRO - 2015 - AMAZUL - Analista de Recursos Humanos |
CETRO - 2015 - AMAZUL - Tecnólogo em Logística |
CETRO - 2015 - AMAZUL - Enfermeiro do Trabalho |
CETRO - 2015 - AMAZUL - Psicologia |
Q479335
Inglês
Texto associado
Read the text below to answer the questions 11-15.
NASA Researchers Studying Advanced Nuclear Rocket Technologies
January 9, 2013
By using an innovative test facility at NASA’s Marshall Space Flight Center in Huntsville, Ala., researchers are able to use non-nuclear materials to simulate nuclear thermal rocket fuels - ones capable of propelling bold new exploration missions to the Red Planet and beyond. The Nuclear Cryogenic Propulsion Stage team is tackling a three-year project to demonstrate the viability of nuclear propulsion system technologies. A nuclear rocket engine uses a nuclear reactor to heat hydrogen to very high temperatures, which expands through a nozzle to generate thrust. Nuclear rocket engines generate higher thrust and are more than twice as efficient as conventional chemical rocket engines.
The team recently used Marshall’s Nuclear Thermal Rocket Element Environmental Simulator, or NTREES, to perform realistic, non-nuclear testing of various materials for nuclear thermal rocket fuel elements. In an actual reactor, the fuel elements would contain uranium, but no radioactive materials are used during the NTREES tests. Among the fuel options are a graphite composite and a “cermet” composite - a blend of ceramics and metals. Both materials were investigated in previous NASA and U.S. Department of Energy research efforts.
Nuclear-powered rocket concepts are not new; the United States conducted studies and significant ground testing from 1955 to 1973 to determine the viability of nuclear propulsion systems, but ceased testing when plans for a crewed Mars mission were deferred.
The NTREES facility is designed to test fuel elements and materials in hot flowing hydrogen, reaching pressures up to 1,000 pounds per square inch and temperatures of nearly 5,000 degrees Fahrenheit - conditions that simulate space-based nuclear propulsion systems to provide baseline data critical to the research team.
“This is vital testing, helping us reduce risks and costs associated with advanced propulsion technologies and ensuring excellent performance and results as we progress toward further system development and testing,” said Mike Houts, project manager for nuclear systems at Marshall.
A first-generation nuclear cryogenic propulsion system could propel human explorers to Mars more efficiently than conventional spacecraft, reducing crews’ exposure to harmful space radiation and other effects of long-term space missions. It could also transport heavy cargo and science payloads. Further development and use of a first-generation nuclear system could also provide the foundation for developing extremely advanced propulsion technologies and systems in the future - ones that could take human crews even farther into the solar system.
Building on previous, successful research and using the NTREES facility, NASA can safely and thoroughly test simulated nuclear fuel elements of various sizes, providing important test data to support the design of a future Nuclear Cryogenic Propulsion Stage. A nuclear cryogenic upper stage - its liquid- hydrogen propellant chilled to super-cold temperatures for launch - would be designed to be safe during all mission phases and would not be started until the spacecraft had reached a safe orbit and was ready to begin its journey to a distant destination. Prior to startup in a safe orbit, the nuclear system would be cold, with no fission products generated from nuclear operations, and with radiation below significant levels.
“The information we gain using this test facility will permit engineers to design rugged, efficient fuel elements and nuclear propulsion systems,” said NASA researcher Bill Emrich, who manages the NTREES facility at Marshall. “It’s our hope that it will enable us to develop a reliable, cost-effective nuclear rocket engine in the not-too-distant future."
The Nuclear Cryogenic Propulsion Stage project is part of the Advanced Exploration Systems program, which is managed by NASA’s Human Exploration and Operations Mission Directorate and includes participation by the U.S. Department of Energy. The program, which focuses on crew safety and mission operations in deep space, seeks to pioneer new approaches for rapidly developing prototype systems, demonstrating key capabilities and validating operational concepts for future vehicle development and human missions beyond Earth orbit.
Marshall researchers are partnering on the project with NASA’s Glenn Research Center in Cleveland, Ohio; NASA’s Johnson Space Center in Houston; Idaho National Laboratory in Idaho Falls; Los Alamos National Laboratory in Los Alamos, N.M.; and Oak Ridge National Laboratory in Oak Ridge, Tenn.
The Marshall Center leads development of the Space Launch System for NASA. The Science & Technology Office at Marshall strives to apply advanced concepts and capabilities to the research, development and management of a broad spectrum of NASA programs, projects and activities that fall at the very intersection of science and exploration, where every discovery and achievement furthers scientific knowledge and understanding, and supports the agency’s ambitious mission to expand humanity’s reach across the solar system. The NTREES test facility is just one of numerous cutting-edge space propulsion and science research facilities housed in the state-of- the-art Propulsion Research & Development Laboratory at Marshall, contributing to development of the Space Launch System and a variety of other NASA programs and missions.
Available in: http://www.nasa.gov
NASA Researchers Studying Advanced Nuclear Rocket Technologies
January 9, 2013
By using an innovative test facility at NASA’s Marshall Space Flight Center in Huntsville, Ala., researchers are able to use non-nuclear materials to simulate nuclear thermal rocket fuels - ones capable of propelling bold new exploration missions to the Red Planet and beyond. The Nuclear Cryogenic Propulsion Stage team is tackling a three-year project to demonstrate the viability of nuclear propulsion system technologies. A nuclear rocket engine uses a nuclear reactor to heat hydrogen to very high temperatures, which expands through a nozzle to generate thrust. Nuclear rocket engines generate higher thrust and are more than twice as efficient as conventional chemical rocket engines.
The team recently used Marshall’s Nuclear Thermal Rocket Element Environmental Simulator, or NTREES, to perform realistic, non-nuclear testing of various materials for nuclear thermal rocket fuel elements. In an actual reactor, the fuel elements would contain uranium, but no radioactive materials are used during the NTREES tests. Among the fuel options are a graphite composite and a “cermet” composite - a blend of ceramics and metals. Both materials were investigated in previous NASA and U.S. Department of Energy research efforts.
Nuclear-powered rocket concepts are not new; the United States conducted studies and significant ground testing from 1955 to 1973 to determine the viability of nuclear propulsion systems, but ceased testing when plans for a crewed Mars mission were deferred.
The NTREES facility is designed to test fuel elements and materials in hot flowing hydrogen, reaching pressures up to 1,000 pounds per square inch and temperatures of nearly 5,000 degrees Fahrenheit - conditions that simulate space-based nuclear propulsion systems to provide baseline data critical to the research team.
“This is vital testing, helping us reduce risks and costs associated with advanced propulsion technologies and ensuring excellent performance and results as we progress toward further system development and testing,” said Mike Houts, project manager for nuclear systems at Marshall.
A first-generation nuclear cryogenic propulsion system could propel human explorers to Mars more efficiently than conventional spacecraft, reducing crews’ exposure to harmful space radiation and other effects of long-term space missions. It could also transport heavy cargo and science payloads. Further development and use of a first-generation nuclear system could also provide the foundation for developing extremely advanced propulsion technologies and systems in the future - ones that could take human crews even farther into the solar system.
Building on previous, successful research and using the NTREES facility, NASA can safely and thoroughly test simulated nuclear fuel elements of various sizes, providing important test data to support the design of a future Nuclear Cryogenic Propulsion Stage. A nuclear cryogenic upper stage - its liquid- hydrogen propellant chilled to super-cold temperatures for launch - would be designed to be safe during all mission phases and would not be started until the spacecraft had reached a safe orbit and was ready to begin its journey to a distant destination. Prior to startup in a safe orbit, the nuclear system would be cold, with no fission products generated from nuclear operations, and with radiation below significant levels.
“The information we gain using this test facility will permit engineers to design rugged, efficient fuel elements and nuclear propulsion systems,” said NASA researcher Bill Emrich, who manages the NTREES facility at Marshall. “It’s our hope that it will enable us to develop a reliable, cost-effective nuclear rocket engine in the not-too-distant future."
The Nuclear Cryogenic Propulsion Stage project is part of the Advanced Exploration Systems program, which is managed by NASA’s Human Exploration and Operations Mission Directorate and includes participation by the U.S. Department of Energy. The program, which focuses on crew safety and mission operations in deep space, seeks to pioneer new approaches for rapidly developing prototype systems, demonstrating key capabilities and validating operational concepts for future vehicle development and human missions beyond Earth orbit.
Marshall researchers are partnering on the project with NASA’s Glenn Research Center in Cleveland, Ohio; NASA’s Johnson Space Center in Houston; Idaho National Laboratory in Idaho Falls; Los Alamos National Laboratory in Los Alamos, N.M.; and Oak Ridge National Laboratory in Oak Ridge, Tenn.
The Marshall Center leads development of the Space Launch System for NASA. The Science & Technology Office at Marshall strives to apply advanced concepts and capabilities to the research, development and management of a broad spectrum of NASA programs, projects and activities that fall at the very intersection of science and exploration, where every discovery and achievement furthers scientific knowledge and understanding, and supports the agency’s ambitious mission to expand humanity’s reach across the solar system. The NTREES test facility is just one of numerous cutting-edge space propulsion and science research facilities housed in the state-of- the-art Propulsion Research & Development Laboratory at Marshall, contributing to development of the Space Launch System and a variety of other NASA programs and missions.
Available in: http://www.nasa.gov
According to the text, one of the NASA’s Marshall Space Flight Center cutting-edge research facility is called
Ano: 2015
Banca:
CETRO
Órgão:
AMAZUL
Provas:
CETRO - 2015 - AMAZUL - Analista em Desenvolvimento de Tecnologia Nuclear - Advogado
|
CETRO - 2015 - AMAZUL - Analista Administrativo |
CETRO - 2015 - AMAZUL - Engenheiro de Segurança do Trabalho |
CETRO - 2015 - AMAZUL - Assistente Social |
CETRO - 2015 - AMAZUL - Arquiteto |
CETRO - 2015 - AMAZUL - Contador |
CETRO - 2015 - AMAZUL - Cirurgião Dentista |
CETRO - 2015 - AMAZUL - Auditor |
CETRO - 2015 - AMAZUL - Analista de desenvolvimento de sistemas - Tecnólogo |
CETRO - 2015 - AMAZUL - Analista de Recursos Humanos |
CETRO - 2015 - AMAZUL - Tecnólogo em Logística |
CETRO - 2015 - AMAZUL - Enfermeiro do Trabalho |
CETRO - 2015 - AMAZUL - Psicologia |
Q479334
Inglês
Texto associado
Read the text below to answer the questions 11-15.
NASA Researchers Studying Advanced Nuclear Rocket Technologies
January 9, 2013
By using an innovative test facility at NASA’s Marshall Space Flight Center in Huntsville, Ala., researchers are able to use non-nuclear materials to simulate nuclear thermal rocket fuels - ones capable of propelling bold new exploration missions to the Red Planet and beyond. The Nuclear Cryogenic Propulsion Stage team is tackling a three-year project to demonstrate the viability of nuclear propulsion system technologies. A nuclear rocket engine uses a nuclear reactor to heat hydrogen to very high temperatures, which expands through a nozzle to generate thrust. Nuclear rocket engines generate higher thrust and are more than twice as efficient as conventional chemical rocket engines.
The team recently used Marshall’s Nuclear Thermal Rocket Element Environmental Simulator, or NTREES, to perform realistic, non-nuclear testing of various materials for nuclear thermal rocket fuel elements. In an actual reactor, the fuel elements would contain uranium, but no radioactive materials are used during the NTREES tests. Among the fuel options are a graphite composite and a “cermet” composite - a blend of ceramics and metals. Both materials were investigated in previous NASA and U.S. Department of Energy research efforts.
Nuclear-powered rocket concepts are not new; the United States conducted studies and significant ground testing from 1955 to 1973 to determine the viability of nuclear propulsion systems, but ceased testing when plans for a crewed Mars mission were deferred.
The NTREES facility is designed to test fuel elements and materials in hot flowing hydrogen, reaching pressures up to 1,000 pounds per square inch and temperatures of nearly 5,000 degrees Fahrenheit - conditions that simulate space-based nuclear propulsion systems to provide baseline data critical to the research team.
“This is vital testing, helping us reduce risks and costs associated with advanced propulsion technologies and ensuring excellent performance and results as we progress toward further system development and testing,” said Mike Houts, project manager for nuclear systems at Marshall.
A first-generation nuclear cryogenic propulsion system could propel human explorers to Mars more efficiently than conventional spacecraft, reducing crews’ exposure to harmful space radiation and other effects of long-term space missions. It could also transport heavy cargo and science payloads. Further development and use of a first-generation nuclear system could also provide the foundation for developing extremely advanced propulsion technologies and systems in the future - ones that could take human crews even farther into the solar system.
Building on previous, successful research and using the NTREES facility, NASA can safely and thoroughly test simulated nuclear fuel elements of various sizes, providing important test data to support the design of a future Nuclear Cryogenic Propulsion Stage. A nuclear cryogenic upper stage - its liquid- hydrogen propellant chilled to super-cold temperatures for launch - would be designed to be safe during all mission phases and would not be started until the spacecraft had reached a safe orbit and was ready to begin its journey to a distant destination. Prior to startup in a safe orbit, the nuclear system would be cold, with no fission products generated from nuclear operations, and with radiation below significant levels.
“The information we gain using this test facility will permit engineers to design rugged, efficient fuel elements and nuclear propulsion systems,” said NASA researcher Bill Emrich, who manages the NTREES facility at Marshall. “It’s our hope that it will enable us to develop a reliable, cost-effective nuclear rocket engine in the not-too-distant future."
The Nuclear Cryogenic Propulsion Stage project is part of the Advanced Exploration Systems program, which is managed by NASA’s Human Exploration and Operations Mission Directorate and includes participation by the U.S. Department of Energy. The program, which focuses on crew safety and mission operations in deep space, seeks to pioneer new approaches for rapidly developing prototype systems, demonstrating key capabilities and validating operational concepts for future vehicle development and human missions beyond Earth orbit.
Marshall researchers are partnering on the project with NASA’s Glenn Research Center in Cleveland, Ohio; NASA’s Johnson Space Center in Houston; Idaho National Laboratory in Idaho Falls; Los Alamos National Laboratory in Los Alamos, N.M.; and Oak Ridge National Laboratory in Oak Ridge, Tenn.
The Marshall Center leads development of the Space Launch System for NASA. The Science & Technology Office at Marshall strives to apply advanced concepts and capabilities to the research, development and management of a broad spectrum of NASA programs, projects and activities that fall at the very intersection of science and exploration, where every discovery and achievement furthers scientific knowledge and understanding, and supports the agency’s ambitious mission to expand humanity’s reach across the solar system. The NTREES test facility is just one of numerous cutting-edge space propulsion and science research facilities housed in the state-of- the-art Propulsion Research & Development Laboratory at Marshall, contributing to development of the Space Launch System and a variety of other NASA programs and missions.
Available in: http://www.nasa.gov
NASA Researchers Studying Advanced Nuclear Rocket Technologies
January 9, 2013
By using an innovative test facility at NASA’s Marshall Space Flight Center in Huntsville, Ala., researchers are able to use non-nuclear materials to simulate nuclear thermal rocket fuels - ones capable of propelling bold new exploration missions to the Red Planet and beyond. The Nuclear Cryogenic Propulsion Stage team is tackling a three-year project to demonstrate the viability of nuclear propulsion system technologies. A nuclear rocket engine uses a nuclear reactor to heat hydrogen to very high temperatures, which expands through a nozzle to generate thrust. Nuclear rocket engines generate higher thrust and are more than twice as efficient as conventional chemical rocket engines.
The team recently used Marshall’s Nuclear Thermal Rocket Element Environmental Simulator, or NTREES, to perform realistic, non-nuclear testing of various materials for nuclear thermal rocket fuel elements. In an actual reactor, the fuel elements would contain uranium, but no radioactive materials are used during the NTREES tests. Among the fuel options are a graphite composite and a “cermet” composite - a blend of ceramics and metals. Both materials were investigated in previous NASA and U.S. Department of Energy research efforts.
Nuclear-powered rocket concepts are not new; the United States conducted studies and significant ground testing from 1955 to 1973 to determine the viability of nuclear propulsion systems, but ceased testing when plans for a crewed Mars mission were deferred.
The NTREES facility is designed to test fuel elements and materials in hot flowing hydrogen, reaching pressures up to 1,000 pounds per square inch and temperatures of nearly 5,000 degrees Fahrenheit - conditions that simulate space-based nuclear propulsion systems to provide baseline data critical to the research team.
“This is vital testing, helping us reduce risks and costs associated with advanced propulsion technologies and ensuring excellent performance and results as we progress toward further system development and testing,” said Mike Houts, project manager for nuclear systems at Marshall.
A first-generation nuclear cryogenic propulsion system could propel human explorers to Mars more efficiently than conventional spacecraft, reducing crews’ exposure to harmful space radiation and other effects of long-term space missions. It could also transport heavy cargo and science payloads. Further development and use of a first-generation nuclear system could also provide the foundation for developing extremely advanced propulsion technologies and systems in the future - ones that could take human crews even farther into the solar system.
Building on previous, successful research and using the NTREES facility, NASA can safely and thoroughly test simulated nuclear fuel elements of various sizes, providing important test data to support the design of a future Nuclear Cryogenic Propulsion Stage. A nuclear cryogenic upper stage - its liquid- hydrogen propellant chilled to super-cold temperatures for launch - would be designed to be safe during all mission phases and would not be started until the spacecraft had reached a safe orbit and was ready to begin its journey to a distant destination. Prior to startup in a safe orbit, the nuclear system would be cold, with no fission products generated from nuclear operations, and with radiation below significant levels.
“The information we gain using this test facility will permit engineers to design rugged, efficient fuel elements and nuclear propulsion systems,” said NASA researcher Bill Emrich, who manages the NTREES facility at Marshall. “It’s our hope that it will enable us to develop a reliable, cost-effective nuclear rocket engine in the not-too-distant future."
The Nuclear Cryogenic Propulsion Stage project is part of the Advanced Exploration Systems program, which is managed by NASA’s Human Exploration and Operations Mission Directorate and includes participation by the U.S. Department of Energy. The program, which focuses on crew safety and mission operations in deep space, seeks to pioneer new approaches for rapidly developing prototype systems, demonstrating key capabilities and validating operational concepts for future vehicle development and human missions beyond Earth orbit.
Marshall researchers are partnering on the project with NASA’s Glenn Research Center in Cleveland, Ohio; NASA’s Johnson Space Center in Houston; Idaho National Laboratory in Idaho Falls; Los Alamos National Laboratory in Los Alamos, N.M.; and Oak Ridge National Laboratory in Oak Ridge, Tenn.
The Marshall Center leads development of the Space Launch System for NASA. The Science & Technology Office at Marshall strives to apply advanced concepts and capabilities to the research, development and management of a broad spectrum of NASA programs, projects and activities that fall at the very intersection of science and exploration, where every discovery and achievement furthers scientific knowledge and understanding, and supports the agency’s ambitious mission to expand humanity’s reach across the solar system. The NTREES test facility is just one of numerous cutting-edge space propulsion and science research facilities housed in the state-of- the-art Propulsion Research & Development Laboratory at Marshall, contributing to development of the Space Launch System and a variety of other NASA programs and missions.
Available in: http://www.nasa.gov
Considering the text, read the statements below.
I. Engines powered by expanded hydrogen work better than regular chemical engines.
II. A CERMET composite is made of ceramics, metal and graphite.
III. The Nuclear Cryogenic Propulsion Stage created the technology that took human crews to Mars.
According to the text, the correct assertion(s) is(are)
I. Engines powered by expanded hydrogen work better than regular chemical engines.
II. A CERMET composite is made of ceramics, metal and graphite.
III. The Nuclear Cryogenic Propulsion Stage created the technology that took human crews to Mars.
According to the text, the correct assertion(s) is(are)
Q478529
Inglês
“This twisted ideology is also behind the current federal government shutdown in the US. An opinion poli at the end ofJune 2012 showed that a majority of Americans, while opposing Obamacare, strongly support most of its provisions. Here we encounter Tea Party ideology at its purest: the majority wants to have its ideological cake and eat the real baking. They want the real benefits of healthcare reform, while rejecting its ideological form, which they perceive as a threat to the “freedom ofchoice". They reject the concept offruit, but they want apples, plums and strawberries". Slavoj Zizek
Choose the best summary for the excerpt:
Choose the best summary for the excerpt:
Conheça nossos planos