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In the thermosphere, temperature increases with altitude. | Air temperature changes as altitude increases. | 1entails
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In year's past the air temperatures have steadily dropped as the altitude increases. | Air temperature changes as altitude increases. | 1entails
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Normally, as you rise in altitude, the temperature decreases due to the changes in air pressure. | Air temperature changes as altitude increases. | 1entails
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The speed of sound changes as altitude and air temperature change. | Air temperature changes as altitude increases. | 0neutral
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Under most conditions, the air temperature decreases as altitude increases. | Air temperature changes as altitude increases. | 1entails
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While the air temperature of an indoor environment is normally controlled and is not affected by the altitude change, the indoor air pressure does change with the altitude. | Air temperature changes as altitude increases. | 0neutral
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With increasing altitude the temperatures get colder; | Air temperature changes as altitude increases. | 1entails
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density altitude pressure altitude corrected for air temperature. | Air temperature changes as altitude increases. | 0neutral
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A different kind of metastable nuclear state (isomer) is the fission isomer or shape isomer. | Alkenes with the same atoms but different shapes are called isomers. | 0neutral
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Constitutional isomers have different atomic connectivities. | Alkenes with the same atoms but different shapes are called isomers. | 0neutral
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However, when the corresponding trans isomer is subjected to the same conditions, the major product is 3-methylcyclohexane, a disubstituted alkene. | Alkenes with the same atoms but different shapes are called isomers. | 0neutral
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Isomers (chemistry) Isomers, are two or more chemical compounds that have the same number of each kind of atom, but differ in the way the atoms are arranged. | Alkenes with the same atoms but different shapes are called isomers. | 1entails
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Isomers are molecules with the same atoms, but in a different arrangement. | Alkenes with the same atoms but different shapes are called isomers. | 1entails
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Molecules which have the same formula, but different spatial arrangement of atoms, like this example, are called isomers . | Alkenes with the same atoms but different shapes are called isomers. | 1entails
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Since alkene geometric isomers are also classified as diastereomers, this reaction would also be called diastereoselective. | Alkenes with the same atoms but different shapes are called isomers. | 0neutral
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Stereoisomers Isomers that have their atoms connected in the same order but have different three-dimensional arrangements. | Alkenes with the same atoms but different shapes are called isomers. | 0neutral
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The two trans alkenes react head-to-tail, and the isolated isomers are called truxillic acids. | Alkenes with the same atoms but different shapes are called isomers. | 0neutral
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Three Different Isomers in the Same Crystal. | Alkenes with the same atoms but different shapes are called isomers. | 0neutral
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We have already seen constiturtional isomers (which have atoms bonded to different atoms such as butane and isobutane) and geometric isomers (also stereoisomers) like E and Z in alkenes. | Alkenes with the same atoms but different shapes are called isomers. | 0neutral
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14C and 12C are both isotopes of carbon (they each have six protons -- the atomic number is the same), but they have a different number of neutrons (thus the atomic weight is different). | All carbon atoms have six protons. | 1entails
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All carbon atoms have six protons, but isotopes of carbon can have 12, 13, or 14 neutrons. | All carbon atoms have six protons. | 1entails
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An atom of carbon has six protons and six neutrons. | All carbon atoms have six protons. | 1entails
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An ordinary carbon atom has six protons and six neutrons in its nucleus; | All carbon atoms have six protons. | 1entails
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Both isotopes have six protons, but carbon 12 has six neutrons, while carbon 13 has seven. | All carbon atoms have six protons. | 0neutral
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Carbon has six protons and six electrons. | All carbon atoms have six protons. | 1entails
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Carbon, for example has six protons and six electrons. | All carbon atoms have six protons. | 1entails
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Every atom of hydrogen, for example, has one proton, and every atom of carbon has six protons. | All carbon atoms have six protons. | 1entails
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Every atom that has exactly six protons is a carbon atom. | All carbon atoms have six protons. | 1entails
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For example all carbon atoms contain six protons, all gold atoms contain 79 protons, all lead atoms contain 82 protons. | All carbon atoms have six protons. | 1entails
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For example, all atoms of carbon contain six protons, all atoms of oxygen contain eight protons. | All carbon atoms have six protons. | 1entails
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For example, an atom with six protons in its nucleus is a carbon atom; seven protons makes it nitrogen; eight protons makes it oxygen, and so on. | All carbon atoms have six protons. | 1entails
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For example, any atom with six protons in its nucleus is a carbon atom. | All carbon atoms have six protons. | 1entails
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For example, carbon atoms always have six protons, but may have six, seven, or eight neutrons. | All carbon atoms have six protons. | 1entails
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For example, if an atom has six protons, it can only be carbon. | All carbon atoms have six protons. | 1entails
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For instance, an atom of carbon could be carbon 12, having six protons and neutrons, carbon 13 (six protons and seven neutrons), or carbon 14 (six protons and eight neutrons). | All carbon atoms have six protons. | 1entails
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For instance, carbon has an atomic number of six and therefore has six protons and six electrons. | All carbon atoms have six protons. | 1entails
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If an atom has six protons, it is carbon. | All carbon atoms have six protons. | 1entails
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Introduction Scientists typically get the same answers, such as all chemists saying that carbon atoms have six protons; | All carbon atoms have six protons. | 1entails
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Most carbon atoms in the world have six protons and six neutrons in their nucleus. | All carbon atoms have six protons. | 1entails
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Since the atom now has six protons, it is an atom of carbon. | All carbon atoms have six protons. | 1entails
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The atoms called Carbon form the basis of life and have six protons in the nucleus. | All carbon atoms have six protons. | 1entails
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The element with six protons and six electrons is called carbon. | All carbon atoms have six protons. | 1entails
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This problem is common to all six carbon atoms in the ring. | All carbon atoms have six protons. | 0neutral
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Thus, all carbon isotopes have nearly identical chemical properties because they all have six protons and six electrons, even though carbon atoms may, for example, have 6 or 8 neutrons. | All carbon atoms have six protons. | 1entails
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a carbon atom has six protons, six neutrons, and six electrons; | All carbon atoms have six protons. | 1entails
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e.g., a carbon atom has six protons but may have more or less than usual six neutrons. | All carbon atoms have six protons. | 1entails
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the atom of carbon has six protons and six neutrons, and so on. | All carbon atoms have six protons. | 1entails
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All cells need insulin to carry blood glucose, or sugar, into them for energy. | All cells need glucose for energy. | 1entails
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Carbohydrates are converted to glucose in the body and insulin helps cells utilize glucose for energy. | All cells need glucose for energy. | 1entails
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Carbohydrates turn into glucose, and we need glucose in our cells for energy. | All cells need glucose for energy. | 1entails
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Glucose is an important energy source for the functioning of all the cells of the body. | All cells need glucose for energy. | 1entails
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The cells of the animal body make use of this glucose to derive its energy needs. | All cells need glucose for energy. | 1entails
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The main function of the carbohydrates is eventual conversion to an energy source in the form of glucose, the primary energy source for all cells in the body. | All cells need glucose for energy. | 1entails
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Tissues that do not need to use glucose for energy (for example, muscle cells) start burning the fatty acids. | All cells need glucose for energy. | 0neutral
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We need glucose because it provides energy for our brain, central nervous system, and all of our bodies' cells. | All cells need glucose for energy. | 1entails
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Active transport requires energy from the cell. | All cells need energy for processes like active transport. | 1entails
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Active transport requires the cell to spend energy, usually in the form of ATP . | All cells need energy for processes like active transport. | 1entails
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All cells need energy to carry out their functions, such as making proteins and transporting substances into and out of the cell. | All cells need energy for processes like active transport. | 1entails
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All cells, including both plant and animal cells, need energy for processes such as active transport. | All cells need energy for processes like active transport. | 1entails
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Cells have many mitochondria to supply energy for active transport. | All cells need energy for processes like active transport. | 1entails
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Iron is an integral part of oxygen transport in red blood cells and for the processes in your cells that make energy. | All cells need energy for processes like active transport. | 0neutral
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examination of cell structure and their functions in the processes of energy conservation, photosynthesis, biosynthesis, and cell transport; | All cells need energy for processes like active transport. | 0neutral
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A cell not undergoing division. | All cells undergo cell division during a lifetime, but when this process is out of control, cancer results. | 0neutral
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Cancer cells are not able to undergo apoptosis. | All cells undergo cell division during a lifetime, but when this process is out of control, cancer results. | 0neutral
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Control of cell division was the result of control of nuclear division; | All cells undergo cell division during a lifetime, but when this process is out of control, cancer results. | 0neutral
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Each cell is drawn as it is undergoing asexual cell division. | All cells undergo cell division during a lifetime, but when this process is out of control, cancer results. | 0neutral
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Normal cells and cancer cells go through the same division cycle, but the controls that regulate the process in normal cells are absent in cancer cells. | All cells undergo cell division during a lifetime, but when this process is out of control, cancer results. | 1entails
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The virus may induce the cell to forcefully undergo cell division, which may lead to transformation of the cell and, ultimately, cancer. | All cells undergo cell division during a lifetime, but when this process is out of control, cancer results. | 1entails
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They do not do not undergo cell division. | All cells undergo cell division during a lifetime, but when this process is out of control, cancer results. | 0neutral
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As with all enzymes, pectinases have an optimum temperature and pH at which they are most active. | All enzymes have an optimal temperature and ph. | 1entails
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Each enzyme has its own particular optimal conditions of pH and temperature. | All enzymes have an optimal temperature and ph. | 1entails
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Explain what happens to enzymes if temperature and pH continually increase. | All enzymes have an optimal temperature and ph. | 0neutral
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Explain why enzymes have an optimum temperature and pH for their activity. | All enzymes have an optimal temperature and ph. | 1entails
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The enzyme has optimal pH The enzyme has optimal temperature. | All enzymes have an optimal temperature and ph. | 1entails
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all pH samples should have a temperature recording associated with them. | All enzymes have an optimal temperature and ph. | 0neutral
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All matter is composed of basic elements that cannot be broken down to substances with different chemical or physical properties. | All matter in the universe is composed of one or more unique pure substances called elements. | 1entails
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All the material or substance of which the earth and its inhabitants is composed is formed of the chemical elements ; this substance taken all together is known as matter. | All matter in the universe is composed of one or more unique pure substances called elements. | 1entails
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All the matter in the universe is composed of the atoms of more than 100 different chemical elements , which are found both in pure form and combined in chemical compounds. | All matter in the universe is composed of one or more unique pure substances called elements. | 1entails
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An element is a substance that is composed of one kind of atom; | All matter in the universe is composed of one or more unique pure substances called elements. | 0neutral
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Everything that exists in the universe is either a pure chemical or a mixture, composed of one or more of the elements shown in the above Periodic Table of the Elements. | All matter in the universe is composed of one or more unique pure substances called elements. | 1entails
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In this scheme of things, the elements of air and fire predominated and together they composed a fifth element, more pure than the rest, which the ancients called "the aether. | All matter in the universe is composed of one or more unique pure substances called elements. | 0neutral
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PEF executable files are composed of one or more elements called Code Fragments. | All matter in the universe is composed of one or more unique pure substances called elements. | 0neutral
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Recall that matter is composed of different substances that are called elements . | All matter in the universe is composed of one or more unique pure substances called elements. | 1entails
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The substance of a Table Group is composed an optional Table Header element, one or more Table Body elements, and an optional Table Footer element. | All matter in the universe is composed of one or more unique pure substances called elements. | 0neutral
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To the Buddhist, the universal elements of Matter are more energies than the substances. | All matter in the universe is composed of one or more unique pure substances called elements. | 0neutral
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a pure substance composed of two or more elements whose composition is constant. | All matter in the universe is composed of one or more unique pure substances called elements. | 0neutral
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all matter is composed of elements or combinations of elements. | All matter in the universe is composed of one or more unique pure substances called elements. | 1entails
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alloy A substance having metallic properties and being composed of two or more chemical elements of which at least one is an elemental metal. | All matter in the universe is composed of one or more unique pure substances called elements. | 0neutral
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91 All of the above indicates that population structure may be more important to a community's diversity, whether parasitic or free-living, than interactions among its member species. | All members of a species living together form a(n) population. | 0neutral
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A population is all the members of one species that live in the same area. | All members of a species living together form a(n) population. | 1entails
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A population is usually defined as all of the individuals of the same species that live in a given area. | All members of a species living together form a(n) population. | 1entails
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A species of lizard lives on islands of all sizes and has the same population density on each of those islands. | All members of a species living together form a(n) population. | 0neutral
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All living populations and species are continuously changing in response to pressures from other organisms, and to variability in Earth's geology and climate. | All members of a species living together form a(n) population. | 0neutral
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All populations of all species in a habitat | All members of a species living together form a(n) population. | 0neutral
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All populations of different species. | All members of a species living together form a(n) population. | 0neutral
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All the members of one particular species in a give area are called a population. | All members of a species living together form a(n) population. | 1entails
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Community All the populations of different species that live in the same place at the same time. | All members of a species living together form a(n) population. | 0neutral
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Extinction- Many species and populations live in the tropical rainforest. | All members of a species living together form a(n) population. | 0neutral
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For example, a disease may be deadly to most members of a population, but if a few individuals are genetically different enough to survive it, the species will live on. | All members of a species living together form a(n) population. | 0neutral
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Homo sapiens is a worldwide species with some 6 billion highly varying members, all descending from a small ancestral population that lived in Africa some 200,000 years ago. | All members of a species living together form a(n) population. | 0neutral
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