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This behavior is similar to that of the main-group elements, but is in stark contrast to that of the neighboring group 11 elements (copper, silver, and gold), which also have filled d-subshells in their ground-state electron configuration but behave chemically as transition metals.
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The chemical behavior of elements can largely be explained by electron configurations.
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Using electron spectroscopy for chemical analysis (ESCA) , models explaining corrosion behavior of metal surfaces are being developed.
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The chemical behavior of elements can largely be explained by electron configurations.
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Determine the number of protons, neutrons, and electrons in an atom or ion.
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The chemistry of each element is determined by its number of protons and electrons.
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The number of protons in a given nucleus is the atomic number of that nucleus and determines which chemical element the nucleus will constitute when surrounded by electrons.
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The chemistry of each element is determined by its number of protons and electrons.
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entails
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There are methods to determine the number of protons on each of the carbons.
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The chemistry of each element is determined by its number of protons and electrons.
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Inner Ear the labyrinth, comprising the vestibule, cochlea and semicircular canals.
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The cochlea and vestibul make up the inner ear.
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The inner ear is made of the spiral-shaped cochlea, and also the semicircular canals and the vestibule, which are the organs of balance.
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The cochlea and vestibul make up the inner ear.
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The vestibule is a small part of the inner ear adjoining the cochlea, which is the hearing part of the inner ear.
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The cochlea and vestibul make up the inner ear.
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The vestibule is the region of the inner ear where the semicircular canals converge, close to the cochlea (the hearing organ).
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The cochlea and vestibul make up the inner ear.
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As the frozen carbon dioxide sublimes, the carbon dioxide gas is so much colder than the water vapor in the air that the vapor condenses.
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The combustion of propane gas produces carbon dioxide and water vapor.
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Because at standard temperature and pressure carbon dioxide is a gas, the carbon dioxide sublimates and instantly produces a gas, condensing water vapor and creating a thick white fog.
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The combustion of propane gas produces carbon dioxide and water vapor.
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Carbon Dioxide as a Greenhouse Gas After water vapor, carbon dioxide is the most important greenhouse gas.
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The combustion of propane gas produces carbon dioxide and water vapor.
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neutral
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Gas exchange in plants is dominated by the roles of carbon dioxide and water vapor.
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The combustion of propane gas produces carbon dioxide and water vapor.
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neutral
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In the first case, completely combusted gas would be emitted from the chimney (particularly nitrogen, carbon dioxide, water vapor, and a minimum amount of sulfur dioxide);
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The combustion of propane gas produces carbon dioxide and water vapor.
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neutral
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Methane is a greenhouse gas that burns to form carbon dioxide (CO2) and water vapor.
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The combustion of propane gas produces carbon dioxide and water vapor.
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neutral
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Perfect combustion of propane yields water, carbon dioxide & heat.
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The combustion of propane gas produces carbon dioxide and water vapor.
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The chief hothouse gas is water vapor-not carbon dioxide or methane.
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The combustion of propane gas produces carbon dioxide and water vapor.
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Then instruments will analyze the gas released by the heat, looking for water vapor and carbon dioxide.
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The combustion of propane gas produces carbon dioxide and water vapor.
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natural gas delivered through the pipelines also contains hydrocarbons such as ethane and propane, and other gases such as nitrogen, helium, carbon dioxide, hydrogen sulfide and water vapor.
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The combustion of propane gas produces carbon dioxide and water vapor.
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neutral
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Antibiotics are prescription drugs that are prescribed to fight against disease causing bacteria, which are different from viruses as in colds and the flu.
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The common cold and flu are examples of human diseases caused by viruses.
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neutral
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Common human diseases caused by viruses include the common cold, the flu, chickenpox and cold sores.
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The common cold and flu are examples of human diseases caused by viruses.
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Examples of common infections caused by viruses are the common cold, influenza and chickenpox.
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The common cold and flu are examples of human diseases caused by viruses.
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Viruses cause colds and flu.
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The common cold and flu are examples of human diseases caused by viruses.
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Viruses cause most cases of colds and respiratory flu.
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The common cold and flu are examples of human diseases caused by viruses.
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Viruses, a type of germ, cause both colds and flu.
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The common cold and flu are examples of human diseases caused by viruses.
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You'll be able to see images of E coli, Pneumonia, TB, the common cold, Flu virus, and Lyme Disease.
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The common cold and flu are examples of human diseases caused by viruses.
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neutral
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A systemic inflammation is characterized by high blood plasma levels of interleukin 6 (IL-6) and C-reactive protein (CRP).
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The complement system is a series of proteins constitutively found in the blood plasma.
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Albumin is the major protein in blood plasma.
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The complement system is a series of proteins constitutively found in the blood plasma.
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Allergy and Immunology complement-ecn List for discussion of all aspects of the complement system of plasma proteins, which are a major part of the humoral immune defence system.
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The complement system is a series of proteins constitutively found in the blood plasma.
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neutral
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Basically, this system encompasses several types of white blood cells and a blood protein called complement.
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The complement system is a series of proteins constitutively found in the blood plasma.
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neutral
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Complement is a collection of protein substances in the blood plasma involved in the removal of foreign substances.
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The complement system is a series of proteins constitutively found in the blood plasma.
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Fibrinogen is one of the plasma proteins in the blood.
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The complement system is a series of proteins constitutively found in the blood plasma.
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neutral
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Humoral immunity depends upon B-lymphocytes, plasma cells, immunoglobulins, the complement system, and other plasma proteins like lysozyme, transferrin, C-reactive protein, and properdin to synergistically combat bacteria and some viruses.
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The complement system is a series of proteins constitutively found in the blood plasma.
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neutral
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Plasma proteins in the blood of fishes from the Gulf of Mexico.
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The complement system is a series of proteins constitutively found in the blood plasma.
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neutral
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Proteins The three kinds of proteins in the immune system, found dissolved in the serum (the liquid portion of the blood), are immunoglobulins, cytokines, and complement proteins.
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The complement system is a series of proteins constitutively found in the blood plasma.
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neutral
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Studying genes for complement, a series of proteins in the blood that play an important part in the immune system, is another active area of lupus research.
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The complement system is a series of proteins constitutively found in the blood plasma.
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neutral
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That triggers the complement cascade, a series of 20 proteins in the blood serum that clog arteries and kill any graft cells the blood can reach.
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The complement system is a series of proteins constitutively found in the blood plasma.
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neutral
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The Complement System a set of 20 normally inactive proteins in blood plasma and on plasma membranes when activated they complement certain immune, allergic and inflammatory reactions V.
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The complement system is a series of proteins constitutively found in the blood plasma.
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The protein buffer system is an abundant and powerful means of regulating pH inside cells, and has a limited role in buffering the blood plasma.
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The complement system is a series of proteins constitutively found in the blood plasma.
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neutral
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There is no plasma protein and no blood cell in the solution.
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The complement system is a series of proteins constitutively found in the blood plasma.
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neutral
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This GPI-anchored plasma membrane protein normally serves to protect blood and vascular cells from injury by the C5b-9 membrane attack complex of complement.
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The complement system is a series of proteins constitutively found in the blood plasma.
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This converts a blood protein fibrinogen to fibrin which then create a series of tiny threads which lead the plasma in the blood to become sticky.
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The complement system is a series of proteins constitutively found in the blood plasma.
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a decrease in the concentration of plasma proteins in the blood,
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The complement system is a series of proteins constitutively found in the blood plasma.
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blood cells and most plasma proteins
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The complement system is a series of proteins constitutively found in the blood plasma.
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return plasma proteins to the blood.
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The complement system is a series of proteins constitutively found in the blood plasma.
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neutral
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A lower pH means a higher acidity, and thus a higher concentration of positive hydrogen ions in the solution.
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The concentration of hydrogen ions in a solution is called acidity.
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A measure of acidity and alkalinity of a solution, taken by measuring the relative concentration of hydrogen ions in the solution.
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The concentration of hydrogen ions in a solution is called acidity.
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Chemists use a pH test that measures the concentration of hydrogen ions in a chemical solution to determine the solution's relative acidity or alkalinity.
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The concentration of hydrogen ions in a solution is called acidity.
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If the hydrogen ion concentration of a solution increases, as happens with increasing acidity, the pH will decrease, and vice versa.
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The concentration of hydrogen ions in a solution is called acidity.
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The hydrogen ion concentration of a water to denote Acidity or Alkalinity.
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The concentration of hydrogen ions in a solution is called acidity.
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The pH is a scale that measures the hydrogen ion concentration, or the acidity, of a solution.
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The concentration of hydrogen ions in a solution is called acidity.
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The pH scale, from 1 to 14, is a measure of the acidity or alkalinity of soil, determined by the concentration of hydrogen ions in a water or salt solution.
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The concentration of hydrogen ions in a solution is called acidity.
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acidity is caused by high concentrations of hydrogen ions.
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The concentration of hydrogen ions in a solution is called acidity.
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entails
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pH A logarithmic measure of the acidity or alkalinity of a solution using the hydrogen ion concentration.
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The concentration of hydrogen ions in a solution is called acidity.
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pH Expresses the hydrogen ion concentration of the solution, the intensity of acidity or alkalinity.
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The concentration of hydrogen ions in a solution is called acidity.
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pH In chemistry, pH is a measure of the concentration of hydrogen ions in a solution, which is a measure of acidity or alkalinity.
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The concentration of hydrogen ions in a solution is called acidity.
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pH In chemistry, pH is a measure of the concentration of hydrogen ions in solution, which is a measure of acidity or alkalinity .
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The concentration of hydrogen ions in a solution is called acidity.
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entails
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A neutron star forms when a massive star's iron core collapses and triggers a supernova explosion.
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The core of a star collapses during a supernova, forming a neutron star.
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A neutron star is the imploded core of a massive star produced by a supernova explosion.
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The core of a star collapses during a supernova, forming a neutron star.
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After the supernova event, the core may remain as a neutron star.
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The core of a star collapses during a supernova, forming a neutron star.
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Another event that generates a large amount of gravitational radiation is the collapse of a massive star in a supernova explosion to form a neutron star.
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The core of a star collapses during a supernova, forming a neutron star.
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Neutron Star Neutron stars are formed when the collapsed core left by a supernova causes its protons and electrons to combine into only neutrons.
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The core of a star collapses during a supernova, forming a neutron star.
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Neutron Stars Astronomers now agree that pulsars are rapidly rotating neutron stars, one form for the stellar core that remains after a supernova outburst.
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The core of a star collapses during a supernova, forming a neutron star.
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Supernovae and neutron stars.
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The core of a star collapses during a supernova, forming a neutron star.
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neutral
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b) (6 pts) Near the end of the massive star s life, its core will attempt to fuse iron and collapse in the process, forming a neutron star during a supernova explosion.
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The core of a star collapses during a supernova, forming a neutron star.
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entails
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As continents drift apart from one another, ocean crust is created in their wake.
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The creation and destruction of oceanic crust is the reason continents move.
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entails
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Because the top of the continental crust is above that of the oceanic, water runs off the continents and collects above the oceanic crust.
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The creation and destruction of oceanic crust is the reason continents move.
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neutral
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Conclusive proof was produced during the 1960's however, to substantiate the fact that the continents move continually over the earth's surface, the sea-bed constantly expands and is consumed beneath some of the continents and the oceanic crust is only a fifth of the age of the continents.
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The creation and destruction of oceanic crust is the reason continents move.
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neutral
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Crust of the ocean is younger than that of the continent due to seafloor spreading.
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The creation and destruction of oceanic crust is the reason continents move.
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neutral
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Current researches: magma genesis in island arc and continent, elemental cycle between crust and mantle, origin and evolution of volcano, origin, evolution, and destruction of meteorite parent bodies, evolution of ocean recorded in fossil.
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The creation and destruction of oceanic crust is the reason continents move.
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neutral
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Geophysical evidence suggested lateral motion of continents and that oceanic crust is younger than continental crust.
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The creation and destruction of oceanic crust is the reason continents move.
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neutral
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Geophysicists and geologists studied the nature of the crust and upper mantle in and under the continents and oceans.
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The creation and destruction of oceanic crust is the reason continents move.
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neutral
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Oceanic crust adjacent to the continents can be deeply buried by several kilometres of sediment.
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The creation and destruction of oceanic crust is the reason continents move.
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neutral
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Partial melting of subducted oceanic crust can produce andesitic volcanism at ocean-ocean and ocean-continent plate margins.
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The creation and destruction of oceanic crust is the reason continents move.
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neutral
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The Crust under the continents is quite a bit thicker than under the oceans.
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The creation and destruction of oceanic crust is the reason continents move.
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neutral
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The crust is thicker and lighter at the continents and thinner and denser at the ocean floor.
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The creation and destruction of oceanic crust is the reason continents move.
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neutral
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The oceanic crust that formed in between the two continents became the Piemont-Liguria Ocean.
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The creation and destruction of oceanic crust is the reason continents move.
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neutral
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e. Ocean to continent Oceanic crust subducts.
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The creation and destruction of oceanic crust is the reason continents move.
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neutral
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the structure and evolution of the crust, continents, oceans and the atmosphere.
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The creation and destruction of oceanic crust is the reason continents move.
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neutral
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Crisscrossing the cytoplasm is a structure called the cytoskeleton , which consists of thread-like filaments and tubules.
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The cytoskeleton is a cellular "scaffolding" or "skeleton" that crisscrosses the cytoplasm
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entails
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List functions of the cytoplasm and cytoskeleton.
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The cytoskeleton is a cellular "scaffolding" or "skeleton" that crisscrosses the cytoplasm
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neutral
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The cytoplasm and the cytoskeleton A.
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The cytoskeleton is a cellular "scaffolding" or "skeleton" that crisscrosses the cytoplasm
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neutral
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They are the cell membrane , the cytoplasm , and the cytoskeleton .
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The cytoskeleton is a cellular "scaffolding" or "skeleton" that crisscrosses the cytoplasm
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neutral
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providing a site for many of the biochemical reactions of the cell Cytoskeleton Crisscrossing the cytoplasm is a structure called the cytoskeleton, which consists of thread-like filaments and tubules.
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The cytoskeleton is a cellular "scaffolding" or "skeleton" that crisscrosses the cytoplasm
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entails
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Decay curve of a radioactive element with a half-life equal to one time unit.
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The decay rate is measured in a unit called the half-life.
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neutral
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Each radioactive component has a different rate of decay called its half-life -- the time it takes the material to lose half of its radioactivity.
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The decay rate is measured in a unit called the half-life.
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entails
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It decays by beta decay with a half-life of 14.29 days.
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The decay rate is measured in a unit called the half-life.
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neutral
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It decays by beta-decay with a half-life of 87.51 days.
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The decay rate is measured in a unit called the half-life.
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neutral
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Sometimes, the rate of dissipation (or any other decay process that behaves like this) is described in terms of its half-life , the time it takes for half of the amount to decay.
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The decay rate is measured in a unit called the half-life.
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entails
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The decay rate of a radioactive isotope is measured in half-lives .
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The decay rate is measured in a unit called the half-life.
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entails
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The decay rate of each radioactive isotope is stated in terms of its half-life , which is the time in years that it takes for one-half of the original parent to decay into the daughter .
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The decay rate is measured in a unit called the half-life.
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entails
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The half-life for the decay of
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The decay rate is measured in a unit called the half-life.
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neutral
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The rate of an isotope's decay is defined by its half-life, or the time it takes for one half of a given amount of the element to decay.
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The decay rate is measured in a unit called the half-life.
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entails
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The rate of this decay is measured in half-lives, or the time it takes half of the radioactive atoms to decay.
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The decay rate is measured in a unit called the half-life.
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entails
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This rate of decay is measured by half-life (how long it takes for one-half of the parent radioactive material to decay to a daughter product).
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The decay rate is measured in a unit called the half-life.
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entails
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a) Convert the half-life into a decay constant in units of s -1 .
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The decay rate is measured in a unit called the half-life.
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neutral
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half life a unit of relative time measuring the rate at which a radioactive substance decays, or (more generally) the rate of decrease for any process that decreases exponentially.
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The decay rate is measured in a unit called the half-life.
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entails
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rate of decay is usually expressed in terms of half life.
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The decay rate is measured in a unit called the half-life.
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entails
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Different catalysts require unequal overpotential for this reduction reaction to take place.
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The difference between the theoretical half-reaction reduction potential and the actual voltage required is called overpotential.
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neutral
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Examination of the plots show that for a reduction reaction and a >0.5 a negative overpotential results in a greater current density than an equivalent positive overpotential.
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The difference between the theoretical half-reaction reduction potential and the actual voltage required is called overpotential.
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neutral
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