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organelles Membrane-bounded structures found in eukaryotic cells which contain enzymes and other components required for specialized cell functions.
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Eukaryotic cells contain organelles that possess special functions.
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A trait is an adaptation if it was shaped by natural selection.
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Evolution occurs by natural selection, a process whereby better-adapted members pass along their traits, according to darwin.
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According to Darwin's theory of evolution by natural selection (57
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Evolution occurs by natural selection, a process whereby better-adapted members pass along their traits, according to darwin.
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According to Darwin's theory of evolution, natural selection means only the organisms best adapted to their environment tend to survive and transmit their genetic characters in increasing numbers to succeeding generations while those less adapted tend to be eliminated.
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Evolution occurs by natural selection, a process whereby better-adapted members pass along their traits, according to darwin.
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Evolution occurs as the more successful adaptations become dominant, and former traits are bred out by the natural selection process.
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Evolution occurs by natural selection, a process whereby better-adapted members pass along their traits, according to darwin.
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Natural Selection is the engine for Darwin Evolution.
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Evolution occurs by natural selection, a process whereby better-adapted members pass along their traits, according to darwin.
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Selection Differential and Response to Selection Returning to the process of adaptation, evolution reflects a genetically-based change in phenotypic traits over time.
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Evolution occurs by natural selection, a process whereby better-adapted members pass along their traits, according to darwin.
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The species with the stronger characteristics mate and pass the traits on in the process called natural selection .
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Evolution occurs by natural selection, a process whereby better-adapted members pass along their traits, according to darwin.
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Evolution, microevolution, and macroevolution are defined by biologists.
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Evolution that occurs over a short period of time is known as microevolution.
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Losos and his colleagues write that their lizard experiment suggests that macroevolution is simply microevolution observed over a much larger time period.
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Evolution that occurs over a short period of time is known as microevolution.
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Macroevolution is NOT simply microevolution extrapolated over longer periods of time.
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Evolution that occurs over a short period of time is known as microevolution.
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Microevolution is concerned with understanding the mechanisms responsible for imparting evolutionary change within populations over relatively short time periods.
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Evolution that occurs over a short period of time is known as microevolution.
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Microevolution occurs over a relatively short period of time within a population or species.
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Evolution that occurs over a short period of time is known as microevolution.
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Microevolution occurs over a short period of time in a population or species.
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Evolution that occurs over a short period of time is known as microevolution.
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Most creationists accept microevolution, but most people think that when a person rejects evolution they are rejecting microevolution as well as macroevolution and evolutionism .
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Evolution that occurs over a short period of time is known as microevolution.
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The concern is that microevolution is labeled evolution, then based on the evidence for microevolution the claim is made that evolution has occurred.
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Evolution that occurs over a short period of time is known as microevolution.
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These changes which we know so well are examples of microevolution or evolution at or below the species level.
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Evolution that occurs over a short period of time is known as microevolution.
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This definition is very similar to microevolution and evolution itself...
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Evolution that occurs over a short period of time is known as microevolution.
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This scenario is inconsistent with neo-Darwinian gradualism, according to which macroevolution is simply cumulative microevolution over long periods of time.
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Evolution that occurs over a short period of time is known as microevolution.
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Unfortunately, "evolution" is used at various times to mean microevolution, macroevolution, evolutionary theory, neo-Darwinism and evolutionism, all of which I define below.
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Evolution that occurs over a short period of time is known as microevolution.
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We are currently learning about evolution...you know, microevolution and macroevolution and the like.
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Evolution that occurs over a short period of time is known as microevolution.
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and mechanisms of evolution such as population and quantitative genetics, microevolution and speciation.
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Evolution that occurs over a short period of time is known as microevolution.
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A study of the anatomy of the human body that includes the structures of the skeletal, muscular, nervous, sensory, circulatory, respiratory, digestive, excretory, endocrine, and reproductive systems.
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Examples of organ systems in a human include the skeletal, nervous, and reproductive systems.
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Includes structure and function of the cell, skeletal, muscular, nervous, digestive, and reproductive systems.
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Examples of organ systems in a human include the skeletal, nervous, and reproductive systems.
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Includes the skeletal, muscular, circulatory, respiratory, digestive, excretory, nervous, and reproductive systems.
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Examples of organ systems in a human include the skeletal, nervous, and reproductive systems.
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It affects many organ systems, including the skin, gastrointestinal tract, central nervous system, and immune, skeletal, and reproductive systems.
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Examples of organ systems in a human include the skeletal, nervous, and reproductive systems.
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It gives an introductory treatment of the structure and function of the human body including cell, skeletal, muscular, nervous, endocrine, respiratory, cardiovascular, digestive, urinary and reproductive systems.
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Examples of organ systems in a human include the skeletal, nervous, and reproductive systems.
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It involves investigation of cells, tissues, organs and systems (including the skeletal, muscular, nervous, endocrine, circulatory, respiratory, digestive, renal and reproductive systems).
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Examples of organ systems in a human include the skeletal, nervous, and reproductive systems.
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Other examples of organ systems include the skeletal, digestive, urinary, and reproductive systems.
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Examples of organ systems in a human include the skeletal, nervous, and reproductive systems.
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Physiological processes in humans relating to functions and structures in muscular, skeletal, circulatory, respiratory, digestive, nervous, excretory, reproductive, and endocrine systems.
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Examples of organ systems in a human include the skeletal, nervous, and reproductive systems.
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Structure and function of the skeletal, muscular, and nervous systems, including sense organs.
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Examples of organ systems in a human include the skeletal, nervous, and reproductive systems.
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Study of the structure and function of human organ systems, including biological chemistry, cytology, histology, and skeletal, muscular and nervous systems.
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Examples of organ systems in a human include the skeletal, nervous, and reproductive systems.
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Surveys the morphology of the musculo-skeletal system, the dentition, the viscera, the nervous system, including the brain and sensory organs, and the reproductive system.
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Examples of organ systems in a human include the skeletal, nervous, and reproductive systems.
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Systems studies include the skeletal, muscular and nervous systems.
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Examples of organ systems in a human include the skeletal, nervous, and reproductive systems.
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The integumentary, skeletal, muscular, cardiovascular, digestive, nervous, urinary, and reproductive organ systems will be studied.
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Examples of organ systems in a human include the skeletal, nervous, and reproductive systems.
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The major human organ systems are explored including integumentary, skeletal, muscular, circulatory, lymphatic, respiratory, digestive, renal and reproductive.
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Examples of organ systems in a human include the skeletal, nervous, and reproductive systems.
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The organ systems in animals include the integument, skeletal, muscular, nervous and sensory, circulatory, lymphatic, immune, respiratory, digestive, excretory, endocrine, and reproductive systems.
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Examples of organ systems in a human include the skeletal, nervous, and reproductive systems.
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There are nine primary organ systems of the human body, consitisting of the digestive, respiratory, circulatory, excretory, skeletal, muscular, reproductive, nervous, and endocrine systems.
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Examples of organ systems in a human include the skeletal, nervous, and reproductive systems.
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Topics include general organization and cellular function, skeletal-muscular system, nervous system, and circulatory system.
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Examples of organ systems in a human include the skeletal, nervous, and reproductive systems.
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Climate of the area is classified as humid continental with short, cool summers and long, cold winters.
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Exemplified by canada and alaska, a subarctic climate has cool, short summers and long, cold winters, little precipitation, and abundant conifers.
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In this climate zone, summers are cool, and winters are cool, but not cold, and there is little frozen precipitation at lower elevations.
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Exemplified by canada and alaska, a subarctic climate has cool, short summers and long, cold winters, little precipitation, and abundant conifers.
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It has an extreme continental climate with long, cold winters and short summers, during which most precipitation falls.
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Exemplified by canada and alaska, a subarctic climate has cool, short summers and long, cold winters, little precipitation, and abundant conifers.
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The city has a humid subtropical climate with long hot rainy summers and short cool to cold,dry winters.
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Exemplified by canada and alaska, a subarctic climate has cool, short summers and long, cold winters, little precipitation, and abundant conifers.
| 0neutral
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The climate is considered to be humid continental with long cold winters and short summers which tend to be cool to warm.
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Exemplified by canada and alaska, a subarctic climate has cool, short summers and long, cold winters, little precipitation, and abundant conifers.
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The climate is continental with short warm summers and long and very cold winters.
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Exemplified by canada and alaska, a subarctic climate has cool, short summers and long, cold winters, little precipitation, and abundant conifers.
| 0neutral
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The climate is continental with short, cool summers and cold winters.
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Exemplified by canada and alaska, a subarctic climate has cool, short summers and long, cold winters, little precipitation, and abundant conifers.
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The climate is cool with long cold winters, moist springs, and warm dry summers.
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Exemplified by canada and alaska, a subarctic climate has cool, short summers and long, cold winters, little precipitation, and abundant conifers.
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The climate is rather severe, the winters are long and very cold, with temperatures going down to -30C, Summer is short and cool.
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Exemplified by canada and alaska, a subarctic climate has cool, short summers and long, cold winters, little precipitation, and abundant conifers.
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The climate is severe, with short, cool growing seasons and long, cold winters.
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Exemplified by canada and alaska, a subarctic climate has cool, short summers and long, cold winters, little precipitation, and abundant conifers.
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The climate is typified by long, cold winters and short, warm summers.
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Exemplified by canada and alaska, a subarctic climate has cool, short summers and long, cold winters, little precipitation, and abundant conifers.
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The climate of Emporium is characterized by comparatively short cool summers and long cold winters with 42 inches of precipitation well distributed throughout the year.
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Exemplified by canada and alaska, a subarctic climate has cool, short summers and long, cold winters, little precipitation, and abundant conifers.
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The climate of the boreal forest is characterised by long, extremely cold, dry winters and short, cool, moist summers.
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Exemplified by canada and alaska, a subarctic climate has cool, short summers and long, cold winters, little precipitation, and abundant conifers.
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The polar marine climate means long, cold winters and short, cool summers.
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Exemplified by canada and alaska, a subarctic climate has cool, short summers and long, cold winters, little precipitation, and abundant conifers.
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The resulting climate ranges from cool, wet winters and warm, dry summers to long, cold winters and short, cool, growing seasons.
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Exemplified by canada and alaska, a subarctic climate has cool, short summers and long, cold winters, little precipitation, and abundant conifers.
| 0neutral
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The subarctic climate (also called subpolar climate or boreal climate) is a climate characterized by long, usually very cold winters, and short, cool to mild summers.
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Exemplified by canada and alaska, a subarctic climate has cool, short summers and long, cold winters, little precipitation, and abundant conifers.
| 1entails
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The town has a cold maritime climate characterized by cool short summers and long cold winters with heavy snow.
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Exemplified by canada and alaska, a subarctic climate has cool, short summers and long, cold winters, little precipitation, and abundant conifers.
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The town has a cold maritime climate characterized by cool short summers and long cold winters with strong winds.
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Exemplified by canada and alaska, a subarctic climate has cool, short summers and long, cold winters, little precipitation, and abundant conifers.
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The tundra climate has a very short, cool summer and a long, severe winter (see Appendix 2, climate diagram for Barrow, Alaska).
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Exemplified by canada and alaska, a subarctic climate has cool, short summers and long, cold winters, little precipitation, and abundant conifers.
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Weather & Climate Halfway between the equator and the pole, the site has short cool summers and long cold winters.
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Exemplified by canada and alaska, a subarctic climate has cool, short summers and long, cold winters, little precipitation, and abundant conifers.
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With elevations above 3600 2 , the prefecture has a harsh climate, with long, cold winters, and short, rainy, and cool to warm summers.
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Exemplified by canada and alaska, a subarctic climate has cool, short summers and long, cold winters, little precipitation, and abundant conifers.
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and continental climate of long, cold winters and mild to cool summers.
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Exemplified by canada and alaska, a subarctic climate has cool, short summers and long, cold winters, little precipitation, and abundant conifers.
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Newton's Second Law Newton's second law states that the acceleration of an object is inversely proportional to its mass and directly proportional to the net external force acting upon it.
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Experiments have shown that acceleration is exactly inversely proportional to mass, just as it is exactly linearly proportional to the net external force.
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The acceleration of an object is directly proportional to the net external force acting on the object and inversely proportional to the mass of the object.
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Experiments have shown that acceleration is exactly inversely proportional to mass, just as it is exactly linearly proportional to the net external force.
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The experiments showed that the force of traction was nearly in an exact proportion to the hardness of the road.
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Experiments have shown that acceleration is exactly inversely proportional to mass, just as it is exactly linearly proportional to the net external force.
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This combination of forces is linearly proportional to the absolute temperature and inversely proportional to the volume (2).
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Experiments have shown that acceleration is exactly inversely proportional to mass, just as it is exactly linearly proportional to the net external force.
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A connection between the risk of skin-cancer and the exposure to ultraviolet radiation is scientifically ascertained.
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Exposure to ultraviolet radiation can increase the amount of pigment in the skin and make it appear darker.
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A more serious concern is that chronic exposure to ultraviolet radiation increases the risk of skin cancer.
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Exposure to ultraviolet radiation can increase the amount of pigment in the skin and make it appear darker.
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Almost all cases of skin cancer can be traced to excessive exposure to ultraviolet (UV) radiation from the sun.
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Exposure to ultraviolet radiation can increase the amount of pigment in the skin and make it appear darker.
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Beware of Sunburn Exposure to ultraviolet radiation increases your risk of skin cancer.
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Exposure to ultraviolet radiation can increase the amount of pigment in the skin and make it appear darker.
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Doctors have long known that exposure to ultraviolet radiation from the sun increases the risk for skin cancer.
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Exposure to ultraviolet radiation can increase the amount of pigment in the skin and make it appear darker.
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Estimating increases in skin cancer morbidity due to increases in ultraviolet radiation exposure.
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Exposure to ultraviolet radiation can increase the amount of pigment in the skin and make it appear darker.
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Evolutionary pigmentation of the skin was caused by ultraviolet (UV) radiation of the sun.
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Exposure to ultraviolet radiation can increase the amount of pigment in the skin and make it appear darker.
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Experts believe that much of this increase is due to people's greater exposure to the sun's ultraviolet radiation, which can cause misspellings in DNA and, as a result, damage skin cells.
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Exposure to ultraviolet radiation can increase the amount of pigment in the skin and make it appear darker.
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Exposure to sunlight and excessive ultraviolet radiation increases the risk for skin cancer.
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Exposure to ultraviolet radiation can increase the amount of pigment in the skin and make it appear darker.
| 0neutral
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Exposure to the sun s ultraviolet radiation significantly increases the risk of skin cancer.
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Exposure to ultraviolet radiation can increase the amount of pigment in the skin and make it appear darker.
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Exposure to ultraviolet (UV) radiation, usually from strong sunshine, appears to increase the risk for skin cancers.
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Exposure to ultraviolet radiation can increase the amount of pigment in the skin and make it appear darker.
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For humans, most skin cancers are associated with exposure to ultraviolet radiation.
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Exposure to ultraviolet radiation can increase the amount of pigment in the skin and make it appear darker.
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However, exposure to ultraviolet radiation can increase the amount of pigment in the skin and make it appear darker.
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Exposure to ultraviolet radiation can increase the amount of pigment in the skin and make it appear darker.
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Increased exposure to ultraviolet radiation could potentially cause an increase in skin cancer, increased cataract cases, suppression of the human immune response system and environmental damage.
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Exposure to ultraviolet radiation can increase the amount of pigment in the skin and make it appear darker.
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Moreover, exposure to the ultraviolet radiation of the sun can cause tissue destruction and trigger mutations that can lead to skin cancer .
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Exposure to ultraviolet radiation can increase the amount of pigment in the skin and make it appear darker.
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Repeated exposure to ultraviolet radiation increases the risk of skin cancer, especially if you have fair skin or freckle easily.
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Exposure to ultraviolet radiation can increase the amount of pigment in the skin and make it appear darker.
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Since excess exposure to ultraviolet radiation is the primary cause of skin cancer, reducing sun exposure can help prevent skin cancer.
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Exposure to ultraviolet radiation can increase the amount of pigment in the skin and make it appear darker.
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Tanning occurs when ultraviolet radiation is absorbed by the skin, causing an increase in the activity and number of melanocytes, the cells that produce the pigment melanin.
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Exposure to ultraviolet radiation can increase the amount of pigment in the skin and make it appear darker.
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That exposure to solar ultraviolet-B (UVB) radiation increases the incidence of basal- and squamous-cell skin cancers is widely recognized.
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Exposure to ultraviolet radiation can increase the amount of pigment in the skin and make it appear darker.
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The main public concern from reduced ozone is the increased amount of ultraviolet radiation at the earth's surface, which can harm many forms of life, including skin cancers and eye damage.
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Exposure to ultraviolet radiation can increase the amount of pigment in the skin and make it appear darker.
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This can increase the amount of ultraviolet radiation reaching the earth, where it damages crops and plants and can lead to skin cancer and cataracts .
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Exposure to ultraviolet radiation can increase the amount of pigment in the skin and make it appear darker.
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Ultraviolet radiation can cause skin cancer and cataracts.
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Exposure to ultraviolet radiation can increase the amount of pigment in the skin and make it appear darker.
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Ultraviolet radiation from sun exposure is the primary cause of skin cancer.
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Exposure to ultraviolet radiation can increase the amount of pigment in the skin and make it appear darker.
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Unprotected exposure to sunlight (ultraviolet radiation) is associated with skin cancer.
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Exposure to ultraviolet radiation can increase the amount of pigment in the skin and make it appear darker.
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increased exposure to ultraviolet radiation due to ozone thinning;
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Exposure to ultraviolet radiation can increase the amount of pigment in the skin and make it appear darker.
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the depletion of this layer is increasing the amount of ultraviolet radiation that can pass through it.
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Exposure to ultraviolet radiation can increase the amount of pigment in the skin and make it appear darker.
| 0neutral
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B, Hyderabad, India) Fermat principle This java applet let you visualize "the path of a ray of light between two points is the path that minimizes the travel time" (known as Fermat principle).
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Fermat’s principle states that light will always take the path of the least amount of time.
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Based on 'Fermat's least-time principle,' a light beam will take the path requiring the least amount of time between two points.
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Fermat’s principle states that light will always take the path of the least amount of time.
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Enunciated his principle of 'least time', according to which, a ray of light follows the path which takes it to its destination in the shortest time.
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Fermat’s principle states that light will always take the path of the least amount of time.
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Fermat also stated that Light follows a path that minimizes total travel time .
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Fermat’s principle states that light will always take the path of the least amount of time.
| 1entails
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Fermat's Principle of Least Time again;
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Fermat’s principle states that light will always take the path of the least amount of time.
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From the Symmetric Principle, gravity can be viewed as a warpage by mass of the time field, with objects moving along the least time path (similar to Fermat's least time optics or Feynman's least action mechanics).
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Fermat’s principle states that light will always take the path of the least amount of time.
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In the field of optics, Fermat s Principle states that light travels between two points in the quickest time possible.
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Fermat’s principle states that light will always take the path of the least amount of time.
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It takes the least amount of time and coordination.
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Fermat’s principle states that light will always take the path of the least amount of time.
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Recall that Fermat's Principle states that light follows a path that minimizes total travel time---regardless of the speed of the light ray.
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Fermat’s principle states that light will always take the path of the least amount of time.
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