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Thermoregulation is also the process of...
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Thermoregulation is the process when animals maintain an internal temperature.
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Thermoregulation to Maintain Homeostasis
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Thermoregulation is the process when animals maintain an internal temperature.
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These birds have featherless neck which the naturalists believe that it plays a pivotal role in thermoregulation (maintaining adequate body temperature).
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Thermoregulation is the process when animals maintain an internal temperature.
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Under these circumstances, thermoregulation is the ability of the human body to maintain a regular body temperature, even when the surrounding temperature is immeasurably different.
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Thermoregulation is the process when animals maintain an internal temperature.
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Yellow-faced bumblebees, like most bumblebees, use thermoregulation to maintain stable body temperatures several degrees above the ambient temperature.
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Thermoregulation is the process when animals maintain an internal temperature.
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thermoregulation implies an animal is able to maintain a stable body temperature while exposed to a more or less broad range of ambient temperatures.
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Thermoregulation is the process when animals maintain an internal temperature.
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A force times time is most appropriately called (a) a torque (b) an impulse (c) an angular momentum (d) a change in momentum 3.
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Impulse is the quantity of force multiplied by the time it is applied.
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An impulse of k times the long range force is applied to the system every k timesteps (i.e., the r-RESPA integrator is used).
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Impulse is the quantity of force multiplied by the time it is applied.
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An other way of looking at this is to say that a force applied to an object for an interval of time will change its velocity in such a way that the applied Impulse is equal to the change in Linear Momentum.
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Impulse is the quantity of force multiplied by the time it is applied.
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neutral
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Hint An impulse is a force applied for a time interval.
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Impulse is the quantity of force multiplied by the time it is applied.
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Impulse and Momentum We can define a quantity, which we will call an Impulse , as a Force x a unit of time.
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Impulse is the quantity of force multiplied by the time it is applied.
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Impulse is force multiplied by time.
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Impulse is the quantity of force multiplied by the time it is applied.
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Impulse is measured by the force multiplied by the change in time.
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Impulse is the quantity of force multiplied by the time it is applied.
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Impulse is the product of the applied force and the time over which that force is applied.
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Impulse is the quantity of force multiplied by the time it is applied.
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In time Eros became associated with creative forces on a lesser scale, as the impulse that had brought cosmos into being was seen to apply to particular life forms as well.
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Impulse is the quantity of force multiplied by the time it is applied.
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Integral of moment of a force with respect to time is angular impulse .
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Impulse is the quantity of force multiplied by the time it is applied.
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LINEAR MOMENTUM (Chapter 5) Impulse and Momentum We can define a quantity, which we will call an Impulse , as a Force x a unit of time.
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Impulse is the quantity of force multiplied by the time it is applied.
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The impulse of the force is calculated by multiplying that force by the length of time it acts.
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Impulse is the quantity of force multiplied by the time it is applied.
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The impulse of the force is just the value of the force times the time of application.
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Impulse is the quantity of force multiplied by the time it is applied.
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The quantity Ft is called the impulse , and it equals the change in momentum of the object struck.
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Impulse is the quantity of force multiplied by the time it is applied.
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Then the impulse is being applied for a longer period of time.
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Impulse is the quantity of force multiplied by the time it is applied.
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neutral
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This period of time, multiplied by the speed of light, was described as the impulse width, a quantity which, if the nature of the X-rays were the same as that of the light rays, would coincide with the wavelength.
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Impulse is the quantity of force multiplied by the time it is applied.
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neutral
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pressure, impulse, or force, or force applied;
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Impulse is the quantity of force multiplied by the time it is applied.
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neutral
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Allele -
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Allele frequecy is the rate at which a specific allele appears within a population.
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Allele --
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Allele frequecy is the rate at which a specific allele appears within a population.
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Allele Frequency The Allele Frequency details the frequency with which the various Alleles occur within a specific population.
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Allele frequecy is the rate at which a specific allele appears within a population.
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Alleles -
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Allele frequecy is the rate at which a specific allele appears within a population.
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Alleles ;
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Allele frequecy is the rate at which a specific allele appears within a population.
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No population specific alleles were observed.
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Allele frequecy is the rate at which a specific allele appears within a population.
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The name of the allele will appear in the Allele field.
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Allele frequecy is the rate at which a specific allele appears within a population.
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allele .
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Allele frequecy is the rate at which a specific allele appears within a population.
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neutral
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Osmolality is a measure of the ratio of osmotically active solute content to water content.
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Osmolality is the ratio of solutes in a solution to a volume of solvent in a solution.
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entails
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Osmolality is a measure of the total number of solute particles relative to a given mass of solvent (usually water).
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Osmolality is the ratio of solutes in a solution to a volume of solvent in a solution.
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entails
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The osmolality of a pure solvent is zero, but if one mole of osmotically active nonelectrolyte particles is added to one kilogram of solvent, the end product is a one osmolal solution.
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Osmolality is the ratio of solutes in a solution to a volume of solvent in a solution.
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The solution with the higher osmolality has the higher osmotic pressure.
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Osmolality is the ratio of solutes in a solution to a volume of solvent in a solution.
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neutral
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You need to know what osmolality you want in the fixative solution.
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Osmolality is the ratio of solutes in a solution to a volume of solvent in a solution.
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An orbital is the region of space where an electron is likely to be found.
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The orbital is the region called where an electron is most likely to be found.
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Atomic Orbitals Atomic Orbitals are the specific regions in space around the nucleus of an atom in which the electrons are most likely to be found.
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The orbital is the region called where an electron is most likely to be found.
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Atomic orbitals are the places surrounding the nucleus of an atom where the electrons are most likely to be at any given time.
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The orbital is the region called where an electron is most likely to be found.
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Electrons surround the atom in pathways called orbitals .
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The orbital is the region called where an electron is most likely to be found.
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Find tips for learning and remembering concepts like electron orbitals and bonding.
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The orbital is the region called where an electron is most likely to be found.
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Like an activated electron at a higher orbital shell.
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The orbital is the region called where an electron is most likely to be found.
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Orbitals are areas of probability of finding an electron.
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The orbital is the region called where an electron is most likely to be found.
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Orbitals are regions around the nucleus where a high probability exists of finding electrons.
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The orbital is the region called where an electron is most likely to be found.
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So scientists describe their positions in terms of orbitals--essentially regions in which electrons are most likely to be found as they whiz around atomic nuclei.
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The orbital is the region called where an electron is most likely to be found.
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Specifically, an orbital describes a region in space where there is a 90% change of finding an electron.
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The orbital is the region called where an electron is most likely to be found.
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Such a volume is called an electronic orbital or simply an orbital.
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The orbital is the region called where an electron is most likely to be found.
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neutral
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The Schr dinger model assumes that the electron is a wave and tries to describe the regions in space, or orbitals , where electrons are most likely to be found.
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The orbital is the region called where an electron is most likely to be found.
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The orbitals used by chemists describe the shape of the region where there is a high probability of finding a particular electron.
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The orbital is the region called where an electron is most likely to be found.
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The probability of finding an electron at an orbital node is zero.
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The orbital is the region called where an electron is most likely to be found.
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The removal of orbital electrons from an atom is called ionization.
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The orbital is the region called where an electron is most likely to be found.
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The various rounded shapes in an orbital diagram indicate where electrons would most likely be found in an atom.
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The orbital is the region called where an electron is most likely to be found.
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Thus, the atomic orbitals are diffuse regions in space around the nucleus of an atom in which the electrons are most likely to be found.
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The orbital is the region called where an electron is most likely to be found.
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When Schrödinger studied the atom, he abandoned the idea of precise orbits, and replaced them with a description of the regions of space, which he called orbitals, where the electrons were most likely to be found.
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The orbital is the region called where an electron is most likely to be found.
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entails
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RADIOACTIVITY--Release of energy and energetic particles by changes occurring within atomic or nuclear structures.
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Radioactivity is the release of particles and/or energy from the nucleus of an atom.
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Radioactivity is the property of certain atoms (which are not stable) to spontaneously disintegrate by emitting either energetic particles or rays of pure energy (or both) from the nucleus or centre of the atom.
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Radioactivity is the release of particles and/or energy from the nucleus of an atom.
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Radioactivity is the spontaneous disintegration of an unstable atomic nucleus and the emission of particles or electromagnetic radiation.
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Radioactivity is the release of particles and/or energy from the nucleus of an atom.
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Structure of atomic nucleus, mass and binding energy, radioactivity and its applications, Laws of radioactive decay.
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Radioactivity is the release of particles and/or energy from the nucleus of an atom.
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neutral
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The Atomic Nucleus and Radioactivity Activity 8.
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Radioactivity is the release of particles and/or energy from the nucleus of an atom.
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the structure of the atom and the nucleus, radioactivity, nuclear energy and nuclear reactors.
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Radioactivity is the release of particles and/or energy from the nucleus of an atom.
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neutral
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Background Information Heredity involves the transmission of traits from parent to offspring.
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Heredity is the science of how traits are passed from parents to offspring.
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Genes are the building blocks of heredity and are passed from parents to offspring in a predictable manner.
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Heredity is the science of how traits are passed from parents to offspring.
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Genetics The study of heredity, or the passing on of traits from an organism to its offspring.
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Heredity is the science of how traits are passed from parents to offspring.
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Heredity The genetic transmission or passing of a particular quality or trait from parent to offspring.
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Heredity is the science of how traits are passed from parents to offspring.
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entails
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Heredity is defined as the passing of traits from parents to offspring.
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Heredity is the science of how traits are passed from parents to offspring.
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Heredity is the passing of phenotypic traits from parents to their offspring, either through asexual reproduction or sexual reproduction.
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Heredity is the science of how traits are passed from parents to offspring.
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entails
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Heredity is the passing of traits (characteristics) from parents to offspring.
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Heredity is the science of how traits are passed from parents to offspring.
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Heredity, which includes gene transfer, assures that the offspring possesses the same adaptive trait as its parent.
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Heredity is the science of how traits are passed from parents to offspring.
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In heredity the genes of the parents are passed on to their offspring unchanged.
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Heredity is the science of how traits are passed from parents to offspring.
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The laws of heredity explain why different traits herited by offspring of the same parents.
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Heredity is the science of how traits are passed from parents to offspring.
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entails
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The science of heredity (genetics) is the study of the transmission of characteristics from parent to offspring.
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Heredity is the science of how traits are passed from parents to offspring.
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The science that studies the principles of heredity, specifically with respect to how traits and diseases are passed from parents to children.
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Heredity is the science of how traits are passed from parents to offspring.
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entails
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The term heredity could be introduced now to refer to all of the traits that are passed on to offspring from parent plants and animals.
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Heredity is the science of how traits are passed from parents to offspring.
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entails
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heredity Genetic transmission of traits from parent to offspring.
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Heredity is the science of how traits are passed from parents to offspring.
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entails
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heredity The familial phenomenon where biological traits are passed from parent to offspring.
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Heredity is the science of how traits are passed from parents to offspring.
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entails
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heredity The handing down of certain traits from parents to their offspring.
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Heredity is the science of how traits are passed from parents to offspring.
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entails
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heredity the transmission, via genes, of certain traits from parent to offspring.
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Heredity is the science of how traits are passed from parents to offspring.
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entails
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heredity- The familial phenomenon where biological traits are passed from parent to offspring.
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Heredity is the science of how traits are passed from parents to offspring.
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entails
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But the ancestral phylogenies are not extinct.
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Phylogeny is the science that describes the ancestral and descendant connections between organisms.
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neutral
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Describe the current state of phylogeny in protists.
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Phylogeny is the science that describes the ancestral and descendant connections between organisms.
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neutral
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In phylogeny reconstruction, the contemporary or hypothetical ancestral strain, species or whatever, is known as a taxon.
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Phylogeny is the science that describes the ancestral and descendant connections between organisms.
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neutral
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Molecular phylogenies of organisms 4.
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Phylogeny is the science that describes the ancestral and descendant connections between organisms.
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neutral
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Phylogenies can depict whatever level in the Linnean hierarchy see Pony Express , Vol. 1, No. 1, page 6) the investigator would like to present, but usually are of ancestral-descendant species, or genera, or families.
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Phylogeny is the science that describes the ancestral and descendant connections between organisms.
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neutral
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Phylogeny is the science that describes the relative connections between organisms, in terms of ancestral and descendant species.
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Phylogeny is the science that describes the ancestral and descendant connections between organisms.
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entails
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Phylogeny of living organisms -
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Phylogeny is the science that describes the ancestral and descendant connections between organisms.
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neutral
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RASP (reconstruct ancestral state in phylogenies) 2.0 beta.
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Phylogeny is the science that describes the ancestral and descendant connections between organisms.
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neutral
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So, warm blood is not a shared, exclusive phylogeny, despite birds and humans sharing a deeper phylogeny of the ancestral reptile.
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Phylogeny is the science that describes the ancestral and descendant connections between organisms.
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neutral
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Teaching about phylogenies Phylogenetic Investigator a teaching program that allows students to connect together organisms from a data set provided to them, to make phylogenies and examine them.
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Phylogeny is the science that describes the ancestral and descendant connections between organisms.
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This describes the topology of the phylogeny in test.
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Phylogeny is the science that describes the ancestral and descendant connections between organisms.
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neutral
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Together with phylogeny the science of palæ
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Phylogeny is the science that describes the ancestral and descendant connections between organisms.
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neutral
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phylogeny A Dictionary of Earth Sciences 5.
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Phylogeny is the science that describes the ancestral and descendant connections between organisms.
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neutral
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Additional information of interest Mount Everest is 29,028 feet tall, and K2 is the second tallest mountain in the world.
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K2 is the second highest mountain in the world, at over 28,000 feet.
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entails
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And Mortenson, 43, who went off in 1992 to climb 28,250-foot K2, the world's second-highest peak, came back committed to bettering lives of the Balti people who served as porters on his climb.
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K2 is the second highest mountain in the world, at over 28,000 feet.
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entails
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At 8,611m K2, the second highest mountain in the world, is difficult by any route.
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K2 is the second highest mountain in the world, at over 28,000 feet.
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Find out more about K2, the second-highest mountain in the world and scene of the mountain-climbing movie.
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K2 is the second highest mountain in the world, at over 28,000 feet.
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He climbed 8611 m K2, the second highest and according to many, the most difficult and dangerous mountain of the world.
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K2 is the second highest mountain in the world, at over 28,000 feet.
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entails
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In '93 he climbed K2 (8,680 meters), the second-highest mountain in the world, and what people think is the most dangerous summit.
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K2 is the second highest mountain in the world, at over 28,000 feet.
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entails
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K2 Mountain of Mountains.
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K2 is the second highest mountain in the world, at over 28,000 feet.
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neutral
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Mountains rise up to 7000 and even 8000 meters (K2 and Nanga Parbat, respectively the second and ninth mountain of the world).
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K2 is the second highest mountain in the world, at over 28,000 feet.
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Of the fourteen highest peaks on earth, Pakistan has five, two of which are the sublime pyramid of K2 (8611 m.) the second highest mountain on earth and the most dangerous mountain in the world, Nanga Parbat (8125 m.).
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K2 is the second highest mountain in the world, at over 28,000 feet.
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entails
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