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Since work is force times distance, the bigger the force, the more work is done.
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Force times distance is the equation for work.
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Since, work equals force times distance.
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Force times distance is the equation for work.
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The Working Group discussed establishing specific time periods or distances traveled that might equate to a satisfactory and concise definition of these terms.
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Force times distance is the equation for work.
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The amount of work is force times the distance the force is exerted.
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Force times distance is the equation for work.
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The definition of work is the force times the distance.
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Force times distance is the equation for work.
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The left side of this equation is the work of the applied force as it acts on the particle along the trajectory from time t1 to time t2.
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Force times distance is the equation for work.
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The original, provocative force of the work dissipates with time and cultural distance.
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Force times distance is the equation for work.
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The work is the force times the distance.
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Force times distance is the equation for work.
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This equation says that the work (or W) (in joules) done by a force (or F) is equal to the product of that force and the distance (d) over which it acts.
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Force times distance is the equation for work.
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This in turn is due to the fact that the work done is force-times-distance, and distance increases as cube-root of mass.
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Force times distance is the equation for work.
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This leads to the definition of work as force times distance.
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Force times distance is the equation for work.
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Torque is work (distance times force) which causes rotation.
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Force times distance is the equation for work.
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Work (or energy) is equal to force times distance.
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Force times distance is the equation for work.
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Work -- Force times distance.
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Force times distance is the equation for work.
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Work can be quantified a force times a distance.
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Force times distance is the equation for work.
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Work equals the force times distance.
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Force times distance is the equation for work.
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Work is defined simply as a force times the distance over which that force acts.
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Force times distance is the equation for work.
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Work is force times distance.
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Force times distance is the equation for work.
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Work is the force times the distance.
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Force times distance is the equation for work.
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Work, a form of energy, is force times distance.
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Force times distance is the equation for work.
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Work, we define as a force times a distance.
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Force times distance is the equation for work.
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You might recall that work is actually defined as the product of a force times a distance.
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Force times distance is the equation for work.
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As the centripetal force acts upon an object moving in a circle at constant speed, the force always acts inward as the velocity of the object is directed tangent to the circle.
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Centripetal forces cause objects to turn around continuously in a circle.
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CENTRIPETAL FORCE The force required to keep an object moving in a curved or circular path.
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Centripetal forces cause objects to turn around continuously in a circle.
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Centripetal Force
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Centripetal forces cause objects to turn around continuously in a circle.
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Centripetal force allows an object to maintain circular motion.
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Centripetal forces cause objects to turn around continuously in a circle.
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With uniform circular motion, the only force acting upon an object traveling in a circle is the centripetal force.
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Centripetal forces cause objects to turn around continuously in a circle.
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You will measure the centripetal force on an object and compare it with the theoretical centripetal force.
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Centripetal forces cause objects to turn around continuously in a circle.
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(Formic acid is the poison found in the > sting of fire ants.)
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Formic acid is found in the secretions of stinging ants.
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Acid From Ants Formic acid (HCOOH).
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Formic acid is found in the secretions of stinging ants.
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Ants defend themselves from predators by biting and stinging by injecting or spraying chemical substances like formic acid.
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Formic acid is found in the secretions of stinging ants.
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Ants may be attracted with only the slightest encouragement, and they do have the ability to bite (strong mandibles) and sting (modified ovipositor that injects formic acid).
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Formic acid is found in the secretions of stinging ants.
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Ants secrete the formic acid for attack and defense purposes.
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Formic acid is found in the secretions of stinging ants.
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Aspartame also contains methanol (wood alcohol) which converts to formaldehyde and then formic acid (ant sting poison).
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Formic acid is found in the secretions of stinging ants.
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But when touched, they release formic acid, the same chemical that lends authority to ant bites and bee stings.
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Formic acid is found in the secretions of stinging ants.
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F, the wood alcohol (used to excrete the chemicals) converts to formaldehyde and then to formic acid, which in turn causes metabolic acidosis (formic acid is the poison found in the sting of fire ants).
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Formic acid is found in the secretions of stinging ants.
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Formic Acid (ant venom) 3.
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Formic acid is found in the secretions of stinging ants.
| 0neutral
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Formic acid is the same poison found in the sting of fire ants.
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Formic acid is found in the secretions of stinging ants.
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Formic acid (HCOOH, the substance causing ant bites to sting) is a weak acid with Ka of 1.8 x 10e-4.
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Formic acid is found in the secretions of stinging ants.
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Formic acid is another bi-product of methanol which is the poison found in the sting of fire ants.
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Formic acid is found in the secretions of stinging ants.
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Once ingested the methanol, wood alcohol that has killed or blinded thousands of skid row drunks, converts into formaldehyde and formic acid (ant sting poison).
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Formic acid is found in the secretions of stinging ants.
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Once ingested the methanol, wood alcohol, converts into formaldehyde and formic acid (ant sting poison).
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Formic acid is found in the secretions of stinging ants.
| 1entails
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Once ingested the methanol, wood alcohol, converts to formaldehyde, and then formic acid (ant sting poison) causing metabolic acidosis.
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Formic acid is found in the secretions of stinging ants.
| 1entails
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Once ingested, methanol, which is wood alcohol that killed or blinded thousands of skid row drunks, converts to formaldehyde, and then formic acid which is ant sting poison.
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Formic acid is found in the secretions of stinging ants.
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Some think it is because of the formic acid some ants secrete, since the ants the birds use are the type which secrete the acid.
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Formic acid is found in the secretions of stinging ants.
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That poison contains the formic acid also present in the stings of bees and ants.
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Formic acid is found in the secretions of stinging ants.
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The formaldehyde converts to formic acid (same as ant sting poison).
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Formic acid is found in the secretions of stinging ants.
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The formaldehyde converts to formic acid, (ant sting poison).
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Formic acid is found in the secretions of stinging ants.
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The wood alcohol, a severe metabolic poison, breaks down first into formaldehyde and then formic acid, ant sting poison.
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Formic acid is found in the secretions of stinging ants.
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There is no sting, but the ant can bite and then curve its abdomen forwards and secrete formic acid onto the wound.
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Formic acid is found in the secretions of stinging ants.
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These chemicals can cause metabolic acidosis (formic acid is the same poison found in the stinging chemical of fire ants ).
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Formic acid is found in the secretions of stinging ants.
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You've got as a component, methyl ester which becomes methanol and then converts to formaldehyde and formic acid (ant sting poison).
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Formic acid is found in the secretions of stinging ants.
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formic acid, a venom in ant stings;
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Formic acid is found in the secretions of stinging ants.
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Amphibians Frog and ToadTheme Page Amphibians are vertebrates that spend part of their lives under water (breathing with gills) and the remainder on land (breathing with lungs).
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Frogs are amphibians that live part of the time in fresh water and live rest of the time on land.
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Amphibians have dual habitats, dividing their time between land and water.
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Frogs are amphibians that live part of the time in fresh water and live rest of the time on land.
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Amphibians include frogs and salamanders and they spend their lives living both on land and in the water.
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Frogs are amphibians that live part of the time in fresh water and live rest of the time on land.
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Amphibians to Paint Online Amphibians are vertebrates that spend part of their lives under water (breathing with gills) and the remainder on land (breathing with lungs).
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Frogs are amphibians that live part of the time in fresh water and live rest of the time on land.
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An amphibian, such as a frog or salamander, is able to live and breathe both on land and in the water.
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Frogs are amphibians that live part of the time in fresh water and live rest of the time on land.
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Because amphibians live part of their lives in water and part on land, they are exposed to water, soil, and air pollutants.
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Frogs are amphibians that live part of the time in fresh water and live rest of the time on land.
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Frogs and other amphibians, such as toads and newts, live on land and in water, and often occur in wetlands.
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Frogs are amphibians that live part of the time in fresh water and live rest of the time on land.
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Frogs and toads are amphibians, animals who begin their lives in the water (breathing with gills) and then, during maturity, live on land (breathing with lungs).
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Frogs are amphibians that live part of the time in fresh water and live rest of the time on land.
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Frogs are amphibians and this means they can live on land and in the water.
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Frogs are amphibians that live part of the time in fresh water and live rest of the time on land.
| 1entails
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Frogs are amphibians, animals that spend part of their lives in water and the remainder on land.
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Frogs are amphibians that live part of the time in fresh water and live rest of the time on land.
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Frogs are amphibians, which comes from the Greek words amphi and bios meaning double life as they live both on land and in water.
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Frogs are amphibians that live part of the time in fresh water and live rest of the time on land.
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Frogs are amphibians, which means that they typically live on land but breed underwater.
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Frogs are amphibians that live part of the time in fresh water and live rest of the time on land.
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Frogs are cold blooded amphibians who live part of their lives in the water, and the other part on land.
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Frogs are amphibians that live part of the time in fresh water and live rest of the time on land.
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Most amphibians, such as frogs, live part of their lives on land and return to water to breed.
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Frogs are amphibians that live part of the time in fresh water and live rest of the time on land.
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Toads and frogs are tailless amphibians that live in land or water.
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Frogs are amphibians that live part of the time in fresh water and live rest of the time on land.
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home search messages help assistant log out AMPHIBIANS Amphibians are creatures such as frogs, toads, newts and salamanders that live both on land and in the water.
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Frogs are amphibians that live part of the time in fresh water and live rest of the time on land.
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As the pressure of a gas increases at constant volume, the temperature will increase.
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From observations as simple as blowing up a balloon, it is clear that increasing the amount of gas increases the volume.
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As the temperature of a gas is increased, the volume of a gas increases and conversely, as the temperature of a gas is decreased, the volume of that gas decreases.
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From observations as simple as blowing up a balloon, it is clear that increasing the amount of gas increases the volume.
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As transaction volume and market valuations have increased, the amount of fees collected under Section 31 has ballooned.
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From observations as simple as blowing up a balloon, it is clear that increasing the amount of gas increases the volume.
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As you blow up the balloon, its radius increases in time, and the volume of space represented by its stretching surface represents how the 3-dimensional space of our universe is stretching to 'create' more space as the universe expands in time.
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From observations as simple as blowing up a balloon, it is clear that increasing the amount of gas increases the volume.
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Conversely, reducing the volume of the gas increases the pressure.
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From observations as simple as blowing up a balloon, it is clear that increasing the amount of gas increases the volume.
| 0neutral
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He noted that the volume of a gas increased with the temperature.
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From observations as simple as blowing up a balloon, it is clear that increasing the amount of gas increases the volume.
| 0neutral
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If the amount of gas in a container is increased, the volume increases.
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From observations as simple as blowing up a balloon, it is clear that increasing the amount of gas increases the volume.
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If the sounds are not clear, increase in volume will not be that beneficial.
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From observations as simple as blowing up a balloon, it is clear that increasing the amount of gas increases the volume.
| 0neutral
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Increase volume by fifth of maximum amount.
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From observations as simple as blowing up a balloon, it is clear that increasing the amount of gas increases the volume.
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Increasing the % Inspiratory Time will also increase the volume of gas moved or tidal volume.
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From observations as simple as blowing up a balloon, it is clear that increasing the amount of gas increases the volume.
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T As the temperature of an amount of gas increases, so does its volume (maintaining a constant pressure).
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From observations as simple as blowing up a balloon, it is clear that increasing the amount of gas increases the volume.
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The balloon will expand to full volume with increasing altitude.
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From observations as simple as blowing up a balloon, it is clear that increasing the amount of gas increases the volume.
| 0neutral
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The lower lifting efficiency of helium gas meant that a larger balloon would be needed, so Goodyear-Zeppelin increased the volume to 3,700,000 flip .
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From observations as simple as blowing up a balloon, it is clear that increasing the amount of gas increases the volume.
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The method involved observing the increase in the gas pressure due to the helium generated in an apparatus of known volume, and applying Boyle's law.
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From observations as simple as blowing up a balloon, it is clear that increasing the amount of gas increases the volume.
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The pressure increase is related to the volume decrease of the gas in the syringe.
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From observations as simple as blowing up a balloon, it is clear that increasing the amount of gas increases the volume.
| 0neutral
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The volume of a gas will increase if the pressure is lowered.
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From observations as simple as blowing up a balloon, it is clear that increasing the amount of gas increases the volume.
| 0neutral
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The volume of a given amount of gas increases as the pressure surrounding it decreases.
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From observations as simple as blowing up a balloon, it is clear that increasing the amount of gas increases the volume.
| 0neutral
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This gas increases the joint volume by 15 to 20 percent;
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From observations as simple as blowing up a balloon, it is clear that increasing the amount of gas increases the volume.
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This is mainly explained by the growth in the volume of road traffic and an increase in the amount of natural gas used in oil and gas production in the North Sea.
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From observations as simple as blowing up a balloon, it is clear that increasing the amount of gas increases the volume.
| 0neutral
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When the temperature of a gas at constant volume is increased, the pressure of the gas increases.
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From observations as simple as blowing up a balloon, it is clear that increasing the amount of gas increases the volume.
| 0neutral
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Anyway, according to the energy conservation laws we can
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According to the law of conservation of energy, energy can never actually be “consumed”; it can only be changed from one form to another.
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CONCEPT According to the Law of Conservation of Energy, we cannot create or destroy energy, but we can change its form.
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According to the law of conservation of energy, energy can never actually be “consumed”; it can only be changed from one form to another.
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CONSERVATION OF ENERGY Conservation of energy is a basic principle of physics stating that energy can never be created or destroyed, it just changes form.
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According to the law of conservation of energy, energy can never actually be “consumed”; it can only be changed from one form to another.
| 1entails
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Law of Conservation of Energy This law states that energy can be transferred from one system to another in many forms, however, it can not be created nor destroyed .
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According to the law of conservation of energy, energy can never actually be “consumed”; it can only be changed from one form to another.
| 1entails
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The Law of Conservation of Energy states that energy can neither be created nor destroyed, only converted from one form to another.
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According to the law of conservation of energy, energy can never actually be “consumed”; it can only be changed from one form to another.
| 1entails
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The law of conservation of energy states that energy cannot be created or destroyed, it can only be changed from one form to another.
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According to the law of conservation of energy, energy can never actually be “consumed”; it can only be changed from one form to another.
| 1entails
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The law of the conservation of energy means that energy can neither be created or destroyed, only transformed from one form to another.
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According to the law of conservation of energy, energy can never actually be “consumed”; it can only be changed from one form to another.
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conservation of energy (Newton's law) The principle that energy cannot be created or destroyed, although it can be changed from one form to another.
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According to the law of conservation of energy, energy can never actually be “consumed”; it can only be changed from one form to another.
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As this energy radiates back toward space as heat, a portion is absorbed by a delicate balance of heat-trapping gases in the atmosphere among them carbon dioxide and methane -- which creates an insulating layer.
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Gases such as co2 and methane can trap thermal energy in earth's atmosphere before radiating it into space.
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Because CO2 absorbs energy emitted from the Earth and prevents it from going back out into space, it is called a greenhouse gas.
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Gases such as co2 and methane can trap thermal energy in earth's atmosphere before radiating it into space.
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Earth radiates energy back into space.
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Gases such as co2 and methane can trap thermal energy in earth's atmosphere before radiating it into space.
| 0neutral
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