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The Earth's crust is roughly 5 to 10 kilometers thick beneath the oceans;
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The earth's continental crust, on average, is 35 kilometers thick.
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The Moon's crust averages 68 kilometers thick;
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The earth's continental crust, on average, is 35 kilometers thick.
| 0neutral
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The crust is thinnest beneath the oceans, averaging only 5 kilometers thick, and thickest beneath large mountain ranges.
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The earth's continental crust, on average, is 35 kilometers thick.
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The earth's crust is made up of giant Plates which are thick slabs of rock that make up the outermost 100 kilometers or so of the earth.
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The earth's continental crust, on average, is 35 kilometers thick.
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The lunar crust is rich in the mineral plagioclase and has an average crustal thickness of 60-70 kilometers, which is about 3 times the average crustal thickness on Earth.
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The earth's continental crust, on average, is 35 kilometers thick.
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The plate boundary between the Indian and Asian continental masses provides a well-studied example, as the Tibetan Plateau just north of the boundary has crust about 80 kilometers thick, roughly twice the thickness of normal continental crust.
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The earth's continental crust, on average, is 35 kilometers thick.
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The two types of crust also differ in thickness, with continental crust being considerably thicker than oceanic (35 km vs. 6 km).
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The earth's continental crust, on average, is 35 kilometers thick.
| 1entails
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The two types of crust also differ in thickness, with continental crust being considerably thicker than oceanic (35 km vs. 6 km).
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The earth's continental crust, on average, is 35 kilometers thick.
| 1entails
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And the pace shows no sign of slowing down.
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Human evolution shows that evolutionary changes typically occur at a slow pace.
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By 2003-2004, the pace of XML evolution will slow as critical mass is reached and the weight of legacy constraints changes.
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Human evolution shows that evolutionary changes typically occur at a slow pace.
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Change will come in a slow and evolutionary way, and the arrival of the messiah will only culminate a long period of human activity.
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Human evolution shows that evolutionary changes typically occur at a slow pace.
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Consider that human evolution progresses at a very, very slow pace.
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Human evolution shows that evolutionary changes typically occur at a slow pace.
| 1entails
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It starts slow, but the pace quickly changes.
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Human evolution shows that evolutionary changes typically occur at a slow pace.
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Sloths might be notorious for their leisurely pace of life, but research published last year shows they are no slow coaches when it comes to evolution.
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Human evolution shows that evolutionary changes typically occur at a slow pace.
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Slow evolution, very typical Sancerre ...
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Human evolution shows that evolutionary changes typically occur at a slow pace.
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Slowed the rhythm and pace of the show.
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Human evolution shows that evolutionary changes typically occur at a slow pace.
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The other path available to humankind at this fork in the evolution road is the truly conservative one of among other things, deliberately slowing the pace of human-driven change.
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Human evolution shows that evolutionary changes typically occur at a slow pace.
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The pace of change will not slow down.
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Human evolution shows that evolutionary changes typically occur at a slow pace.
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The slow pace of change can be discouraging.
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Human evolution shows that evolutionary changes typically occur at a slow pace.
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There is no slowing in the pace of technological change.
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Human evolution shows that evolutionary changes typically occur at a slow pace.
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These changes slowed the pace of implementation of the program.
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Human evolution shows that evolutionary changes typically occur at a slow pace.
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What's more, this intensity of evolutionary change shows no signs of slowing down.
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Human evolution shows that evolutionary changes typically occur at a slow pace.
| 0neutral
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model of the timing of evolution in which evolutionary change occurs at a slow and steady pace
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Human evolution shows that evolutionary changes typically occur at a slow pace.
| 1entails
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1.15.2 Illustrate the interactions within and among populations, including carrying capacities, limiting factors, and growth curves.
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Humans are unique in their ability to alter their environment with the conscious purpose of increasing carrying capacity, which acts as a limiting factor on populations in general.
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2.3 Changes (8h) 23.1-- 1,3 Explain the concepts of limiting factors and carrying capacity in the context of population growth.
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Humans are unique in their ability to alter their environment with the conscious purpose of increasing carrying capacity, which acts as a limiting factor on populations in general.
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As populations increase above the carrying capacity of the environment, certain density dependent mechanisms kick in to reduce population size.
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Humans are unique in their ability to alter their environment with the conscious purpose of increasing carrying capacity, which acts as a limiting factor on populations in general.
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Environment The purpose of the environment project is to increase the capacity of Mongolians working with environmental organizations to carry out their organization's missions;
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Humans are unique in their ability to alter their environment with the conscious purpose of increasing carrying capacity, which acts as a limiting factor on populations in general.
| 0neutral
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For another, it is not practical, nor even ethical, to experiment with human populations in an attempt to determine limits and carrying capacities for humans in specific environments.
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Humans are unique in their ability to alter their environment with the conscious purpose of increasing carrying capacity, which acts as a limiting factor on populations in general.
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Fortunately there is the ability to alter the carrying capacity of the land by landlords.
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Humans are unique in their ability to alter their environment with the conscious purpose of increasing carrying capacity, which acts as a limiting factor on populations in general.
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However, such exponential growth cannot continue indefinitely because limiting factors determine the carrying capacity of the natural environment for any given population.
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Humans are unique in their ability to alter their environment with the conscious purpose of increasing carrying capacity, which acts as a limiting factor on populations in general.
| 0neutral
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Populations of organisms are kept to a habitat's carrying capacity by factors that limit their growth.
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Humans are unique in their ability to alter their environment with the conscious purpose of increasing carrying capacity, which acts as a limiting factor on populations in general.
| 0neutral
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The carrying capacity of the environment will increase.
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Humans are unique in their ability to alter their environment with the conscious purpose of increasing carrying capacity, which acts as a limiting factor on populations in general.
| 0neutral
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The greater the density becomes, the more vigorously the limiting factors slows down population growth and then gradually the density approaches the carrying capacity of the environment.
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Humans are unique in their ability to alter their environment with the conscious purpose of increasing carrying capacity, which acts as a limiting factor on populations in general.
| 0neutral
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The limiting factor in supporting expanded applications in a network setting is the ability to increase the number of service dimensions that will uniquely shape the raw capacity found in the optical core to satisfy the requirements of the application itself.
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Humans are unique in their ability to alter their environment with the conscious purpose of increasing carrying capacity, which acts as a limiting factor on populations in general.
| 0neutral
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The purpose of cognitive energy is to develop the limited being's capacity and ability to receive God consciousness.
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Humans are unique in their ability to alter their environment with the conscious purpose of increasing carrying capacity, which acts as a limiting factor on populations in general.
| 0neutral
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They point to a rapid increase in population and human needs through the year 2000 while at the same time a decline in the earth's capacity to meet those needs, unless nations of the world act decisively to alter current trends.
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Humans are unique in their ability to alter their environment with the conscious purpose of increasing carrying capacity, which acts as a limiting factor on populations in general.
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it is the self-conscious, ongoing development of human and organizational capacity to act in effective and sustained ways on purpose and values.
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Humans are unique in their ability to alter their environment with the conscious purpose of increasing carrying capacity, which acts as a limiting factor on populations in general.
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the answer is elusive, because humans have a unique ability to manipulate their environment and expand its supporting capacity through technology and trade.
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Humans are unique in their ability to alter their environment with the conscious purpose of increasing carrying capacity, which acts as a limiting factor on populations in general.
| 1entails
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Artificial Selection Selective breeding as practiced by humans on domesticated plants and animals.
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Humans create different breeds of organisms using artificial selection.
| 1entails
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Commercial breeding programs use artificial selection (an accelerated, guided form of natural selection) to breed plants and animals with desired characteristics.
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Humans create different breeds of organisms using artificial selection.
| 1entails
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Darwin discussed many examples of artificial selection, in which humans have modified species through selection and breeding.
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Humans create different breeds of organisms using artificial selection.
| 1entails
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Differences between Bioengineering and Breeding The breeding of animals and plants speeds up the natural processes of gene selection and mutation that occur in nature to select new species that have specific use to humans.
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Humans create different breeds of organisms using artificial selection.
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Discuss advantages and disadvantages of artificial selection and breeding.
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Humans create different breeds of organisms using artificial selection.
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Do NOT use artificial selection.
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Humans create different breeds of organisms using artificial selection.
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Genetic engineering is the alteration of genetic code by artificial means, and is therefore different from traditional selective breeding.
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Humans create different breeds of organisms using artificial selection.
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The fact of artificial selection in breeding alone falsifies this contention.
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Humans create different breeds of organisms using artificial selection.
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This is followed by artificial selection in which we select the traits we desire to produce breeds or cultivars that suit our uses.
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Humans create different breeds of organisms using artificial selection.
| 1entails
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When humans breed animals for a specific trait we call this artificial selection.
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Humans create different breeds of organisms using artificial selection.
| 1entails
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Among the Eumatazoa, the phylum Cnidaria (hydras, jellies, coral polyps, and sea anemones) includes all of the radially symmetric animals those that can be split into two identical halves by any cut made from top to bottom.
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Hydras and sea anemones are examples of apolyp.
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Corals, hydra, & sea anemones exist in the polyp form as adults
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Hydras and sea anemones are examples of apolyp.
| 1entails
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Covered in Lab 8 Seed Plant Reproduction polyp The asexual reproducing, normally sedentary form of coelenterates such as the sea anemone.
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Hydras and sea anemones are examples of apolyp.
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In addition to the polyp-dinoflagellate symbiosis, another famous example is the clown fish-sea anemone.
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Hydras and sea anemones are examples of apolyp.
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It feeds on coral polyps and sea anemones.
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Hydras and sea anemones are examples of apolyp.
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Sea anemones, sea whips, corals and hydroids are polyps growing attached to rocks or other hard surfaces of the sea.
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Hydras and sea anemones are examples of apolyp.
| 1entails
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Stony corals are similar to sea anemones, but coral polyps are smaller (approx.
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Hydras and sea anemones are examples of apolyp.
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The polyp is a sessile, or nonmotile, organism; well-known solitary polyps are the sea anemone and the freshwater hydra .
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Hydras and sea anemones are examples of apolyp.
| 1entails
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This species grazes on coral polyps and sea anemone tentacles.
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Hydras and sea anemones are examples of apolyp.
| 0neutral
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Gut flora produce compounds such as indole, skatole, and thiols (sulfur-containing compounds), as well as the inorganic gas hydrogen sulfide.
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Hydrogen sulfide is a noxious and toxic gas produced from decaying organic matter that contains sulfur.
| 0neutral
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Hydrogen Sulfide, H 2 S, is produced by the decay of organic matter, and then rises to the atmosphere where it oxidizes and forms sulfur dioxide.
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Hydrogen sulfide is a noxious and toxic gas produced from decaying organic matter that contains sulfur.
| 1entails
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Hydrogen sulfide gas can be formed and released whenever waste containing sulfur is broken down by bacteria.
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Hydrogen sulfide is a noxious and toxic gas produced from decaying organic matter that contains sulfur.
| 1entails
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In petroleum, sulfur is found in a variety of complex organic compounds and in natural gas as hydrogen sulfide.
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Hydrogen sulfide is a noxious and toxic gas produced from decaying organic matter that contains sulfur.
| 1entails
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It is not the formation of hydrogen sulfide that is toxic to the cell but the process of reducing the sulfur that results in toxicity.
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Hydrogen sulfide is a noxious and toxic gas produced from decaying organic matter that contains sulfur.
| 0neutral
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Keep film out of an atmosphere containing chemical fumes, such as hydrogen sulfide, hydrogen peroxide, sulfur dioxide, ammonia, coal gas, and automobile engine exhaust.
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Hydrogen sulfide is a noxious and toxic gas produced from decaying organic matter that contains sulfur.
| 0neutral
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The oxidation of hydrogen sulfide to sulfate, a different sulfur compound, provides bacteria living around the vents with the energy necessary to produce organic matter, pretty much in the same way as the sun provides plants with the energy to perform photosynthesis and grow.
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Hydrogen sulfide is a noxious and toxic gas produced from decaying organic matter that contains sulfur.
| 0neutral
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The reaction gave off hydrogen sulfide gas, while the sulfur auretum precipitated to the bottom of the container.
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Hydrogen sulfide is a noxious and toxic gas produced from decaying organic matter that contains sulfur.
| 0neutral
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Ice masses, aquifers, and the deep ocean are water reservoirs.
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Ice masses, acquifers, and the deep ocean are examples of water reservoirs.
| 1entails
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In the big water reservoir the puddles are deep.
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Ice masses, acquifers, and the deep ocean are examples of water reservoirs.
| 0neutral
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deep reservoir of water (G.);
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Ice masses, acquifers, and the deep ocean are examples of water reservoirs.
| 0neutral
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[31] Carbon Sequestration The long-term storage of carbon CO 2 in the forests, soils, ocean or underground in depleted oil and gas reservoirs, coal seams and saline acquifers.
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Ice masses, acquifers, and the deep ocean are examples of water reservoirs.
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nutrient reservoirs in the deep ocean;
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Ice masses, acquifers, and the deep ocean are examples of water reservoirs.
| 0neutral
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Accordingly, an increase in pressure will cause an increase in density of the gas and a decrease in its volume .
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If a gas in a closed area experiences increases in pressure and decreases in temperatures, the volume of the gas will be affected.
| 1entails
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Continental shields are composed of a. horizontal layers of rock b. basalt c. ancient rocks of the oceanic ridges d. intensely deformed igneous and metamorphic rock e. folded volcanic and sedimentary rock ____ 8.
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If a sedimentary rock layer is not horizontal, it is deformed.
| 0neutral
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Original Horizontality This principle says that sedimentary rock layers are laid down flat originally and that if you find sedimentary layers which are not flat, they have been deformed since deposition.
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If a sedimentary rock layer is not horizontal, it is deformed.
| 1entails
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3) The solubility of gases typically decreases with increasing temperature.
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If a solute is a gas, increasing the temperature will decrease its solubility.
| 1entails
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An increase in temperature results in a decrease in gas solubility in water, while a decrease in temperature results in an increase in gas solubility.
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If a solute is a gas, increasing the temperature will decrease its solubility.
| 1entails
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At this coldest temperature, the LiBr solution is close to the crystallization point as the solubility of LiBr in solution decreases with decreasing temperature.
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If a solute is a gas, increasing the temperature will decrease its solubility.
| 0neutral
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Consequently, the solubility of all gases in water decrease with increasing temperature.
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If a solute is a gas, increasing the temperature will decrease its solubility.
| 1entails
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Gas solubility in water decreases when the temperature goes up.
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If a solute is a gas, increasing the temperature will decrease its solubility.
| 1entails
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Gas solubility is exothermic, so solubility of gases decreases with increasing temperature.
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If a solute is a gas, increasing the temperature will decrease its solubility.
| 1entails
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Gases, however, decrease in solubility with an increase in temperature.
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If a solute is a gas, increasing the temperature will decrease its solubility.
| 1entails
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Hence an increase in temperature corresponds to a decrease in the solubility of gases in liquids .
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If a solute is a gas, increasing the temperature will decrease its solubility.
| 1entails
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If the solution process absorbs energy then the solubility will be INCREASED as the temperature is increased.
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If a solute is a gas, increasing the temperature will decrease its solubility.
| 0neutral
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In general, the solubility of gases decreases with increasing temperature.
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If a solute is a gas, increasing the temperature will decrease its solubility.
| 1entails
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It shows that solubility of oxygen in water increases with decreased temperatures.
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If a solute is a gas, increasing the temperature will decrease its solubility.
| 0neutral
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The decrease in solubility of gases with increasing temperature is an example of the operation of Le Chatelier's principle .
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If a solute is a gas, increasing the temperature will decrease its solubility.
| 1entails
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The fertilizer solutions stored during the summer form precipitates when the temperatures decrease in the autumn, due to the diminution of the solubility with low temperatures.
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If a solute is a gas, increasing the temperature will decrease its solubility.
| 0neutral
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The solubility of gases in liquids decreases with an increase in temperature.
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If a solute is a gas, increasing the temperature will decrease its solubility.
| 1entails
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When the temperature further increased to 350 C, the benzene solubility decreased to 89.1%.
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If a solute is a gas, increasing the temperature will decrease its solubility.
| 0neutral
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A hot saturated solution containing two or more dissolved solids is allowed to cool slowly; the least-soluble material crystallizes out first, and can be separated by filtration.
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If a solution contains so much solute that its solubility limit is reached, the solution is said to be saturated.
| 0neutral
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A saturated solution contains the maximum amount of solute that can be dissolved at a given temperature.
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If a solution contains so much solute that its solubility limit is reached, the solution is said to be saturated.
| 1entails
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A saturated solution is one that already contains all of the solute that can be possibly dissolved in.
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If a solution contains so much solute that its solubility limit is reached, the solution is said to be saturated.
| 1entails
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A solution which contains the maximum concentration of solute which it can contain under the current conditions, which is the molar solubility, is called a saturated solution .
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If a solution contains so much solute that its solubility limit is reached, the solution is said to be saturated.
| 1entails
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Contains a saturated solution of Ac.
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If a solution contains so much solute that its solubility limit is reached, the solution is said to be saturated.
| 0neutral
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Cool the warm saturated solution to cause a drop in solubility of the dissolved substance.
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If a solution contains so much solute that its solubility limit is reached, the solution is said to be saturated.
| 0neutral
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Impurities which are soluble in the solvent remain in solution as the solution is not saturated with respect to them.
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If a solution contains so much solute that its solubility limit is reached, the solution is said to be saturated.
| 0neutral
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Saturated Solution -
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If a solution contains so much solute that its solubility limit is reached, the solution is said to be saturated.
| 0neutral
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Saturated solutions are those that are at the solubility limits.
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If a solution contains so much solute that its solubility limit is reached, the solution is said to be saturated.
| 1entails
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Simply prepare a saturated solution of the copper nitrate in water, It is very soluble, so use the water sparingly.
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If a solution contains so much solute that its solubility limit is reached, the solution is said to be saturated.
| 0neutral
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This solution so obtained is a saturated one.
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If a solution contains so much solute that its solubility limit is reached, the solution is said to be saturated.
| 0neutral
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We say the solution is saturated .
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If a solution contains so much solute that its solubility limit is reached, the solution is said to be saturated.
| 0neutral
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