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L_0664 | respiratory system organs | T_3356 | FIGURE 1.2 | image | textbook_images/respiratory_system_organs_22116.png |
L_0665 | rna | T_3357 | FIGURE 1.1 | image | textbook_images/rna_22117.png |
L_0667 | roundworms | T_3362 | FIGURE 1.1 | image | textbook_images/roundworms_22120.png |
L_0675 | segmented worms | T_3389 | FIGURE 1.1 Leeches are parasitic worms. Notice the presence of segments. | image | textbook_images/segmented_worms_22135.png |
L_0676 | sex linked inheritance | T_3391 | FIGURE 1.1 A person with red-green colorblindness would not be able to see the number. | image | textbook_images/sex_linked_inheritance_22136.png |
L_0677 | sexually transmitted infections | T_3393 | FIGURE 1.1 This graph shows data on the number of cases of chlamydia in U.S. males and females in 2009. Which two age groups had the highest rates of chlamydia? Why do you think rates were highest in these age groups? | image | textbook_images/sexually_transmitted_infections_22137.png |
L_0677 | sexually transmitted infections | T_3394 | FIGURE 1.2 This lip blister, or cold sore, is caused by a herpes virus. The virus is closely related to the virus that causes genital herpes. The genital herpes virus causes similar blisters on the genitals. If youve ever had a cold sore, you know how painful they can be. Genital herpes blisters are also painful. | image | textbook_images/sexually_transmitted_infections_22138.png |
L_0678 | skeletal system joints | T_3395 | FIGURE 1.1 | image | textbook_images/skeletal_system_joints_22139.png |
L_0678 | skeletal system joints | T_3395 | FIGURE 1.2 The joints between your vertebrae are partially movable. | image | textbook_images/skeletal_system_joints_22140.png |
L_0678 | skeletal system joints | T_3396 | FIGURE 1.3 Your hip joint is a ball-and-socket joint. The ball end of one bone fits into the socket of another bone. These joints can move in many different directions. | image | textbook_images/skeletal_system_joints_22141.png |
L_0678 | skeletal system joints | T_3396 | FIGURE 1.4 Hinge Joint. The knee joint is a hinge joint. Like a door hinge, a hinge joint allows backward and forward movement. | image | textbook_images/skeletal_system_joints_22142.png |
L_0678 | skeletal system joints | T_3396 | FIGURE 1.5 Pivot Joint. The joint at which the radius and ulna meet is a pivot joint. Movement at this joint allows you to flip your palm over without moving your elbow joint. | image | textbook_images/skeletal_system_joints_22143.png |
L_0679 | skin | T_3397 | FIGURE 1.1 | image | textbook_images/skin_22144.png |
L_0679 | skin | T_3400 | FIGURE 1.2 | image | textbook_images/skin_22145.png |
L_0679 | skin | T_3402 | FIGURE 1.3 | image | textbook_images/skin_22146.png |
L_0680 | smooth skeletal and cardiac muscles | T_3403 | FIGURE 1.1 | image | textbook_images/smooth_skeletal_and_cardiac_muscles_22147.png |
L_0682 | sources of water pollution | T_3407 | FIGURE 1.1 | image | textbook_images/sources_of_water_pollution_22152.png |
L_0691 | the carbon cycle | T_3428 | FIGURE 1.1 | image | textbook_images/the_carbon_cycle_22166.png |
L_0694 | timeline of evolution | T_3437 | FIGURE 1.1 The geologic time scale is used to de- scribe events that occurred millions and billions of years ago. The geologic time scale of Earths past is organized ac- cording to events that took place during different periods on the time scale. Ge- ologic time is the same as the age of the Earth: between 4.404 and 4.57 billion years. Look closely for such events as the extinction of dinosaurs and many marine animals. | image | textbook_images/timeline_of_evolution_22170.png |
L_0695 | touch | T_3439 | FIGURE 1.1 The spines on this cactus are like needles; they help keep away animals that might want to eat the cactus. | image | textbook_images/touch_22171.png |
L_0697 | transcription of dna to rna | T_3444 | FIGURE 1.1 | image | textbook_images/transcription_of_dna_to_rna_22174.png |
L_0697 | transcription of dna to rna | T_3444 | FIGURE 1.2 | image | textbook_images/transcription_of_dna_to_rna_22175.png |
L_0698 | translation of rna to protein | T_3445 | FIGURE 1.1 | image | textbook_images/translation_of_rna_to_protein_22176.png |
L_0698 | translation of rna to protein | T_3445 | FIGURE 1.2 | image | textbook_images/translation_of_rna_to_protein_22177.png |
L_0698 | translation of rna to protein | T_3445 | FIGURE 1.3 This chart shows the genetic code used by all organisms. For example, an RNA codon reading GUU would encode for a valine (Val) according to this chart. Start at the center for the first base of the three base codon, and work your way out. Notice that more than one codon may encode for a single amino acid. For example, glycine (Gly) is encoded by a GGG, GGA, GGC, and GGU. Notice there are 64 codons. Of the 64 codons, three are stop codons. | image | textbook_images/translation_of_rna_to_protein_22178.png |
L_0702 | types of echinoderms | T_3459 | FIGURE 1.1 The giant red brittle star, an ophiuroid echinoderm. | image | textbook_images/types_of_echinoderms_22187.png |
L_0704 | types of nutrients | T_3469 | FIGURE 1.1 | image | textbook_images/types_of_nutrients_22189.png |
L_0704 | types of nutrients | T_3471 | FIGURE 1.2 | image | textbook_images/types_of_nutrients_22190.png |
L_0704 | types of nutrients | T_3472 | FIGURE 1.3 can lead to heart disease. 2. Unsaturated fats are found mainly in plant foods, such as vegetable oil, olive oil, and nuts. Unsaturated lipids are also found in fish, such as salmon. Unsaturated lipids are needed in small amounts for good health. Most lipids in your diet should be unsaturated. | image | textbook_images/types_of_nutrients_22191.png |
L_0705 | urinary system | T_3474 | FIGURE 1.1 | image | textbook_images/urinary_system_22192.png |
L_0709 | vision correction | T_3489 | FIGURE 1.1 | image | textbook_images/vision_correction_22201.png |
L_0709 | vision correction | T_3489 | FIGURE 1.2 | image | textbook_images/vision_correction_22202.png |
L_0716 | acids and bases | T_3519 | FIGURE 10.6 Blue litmus paper turns red when placed in an acidic solution. | image | textbook_images/acids_and_bases_22216.png |
L_0716 | acids and bases | T_3520 | FIGURE 10.7 Acids are used widely for many purposes. | image | textbook_images/acids_and_bases_22217.png |
L_0716 | acids and bases | T_3523 | FIGURE 10.8 Red litmus paper turns blue when placed in a basic solution. | image | textbook_images/acids_and_bases_22218.png |
L_0716 | acids and bases | T_3524 | FIGURE 10.9 Bases are used in many products. | image | textbook_images/acids_and_bases_22219.png |
L_0716 | acids and bases | T_3529 | FIGURE 10.10 This pH scale shows the acidity of several common acids and bases. Which substance on this scale is the weakest acid? Which substance is the strongest base? | image | textbook_images/acids_and_bases_22220.png |
L_0716 | acids and bases | T_3529 | FIGURE 10.11 Acid fog and acid rain killed the trees in this forest. | image | textbook_images/acids_and_bases_22221.png |
L_0716 | acids and bases | T_3529 | FIGURE 10.12 What neutral products are produced when antacid tablets react with hydrochloric acid in the stomach? | image | textbook_images/acids_and_bases_22222.png |
L_0717 | radioactivity | T_3531 | FIGURE 11.1 X-rays are a form of energy that can pass through skin and muscle but not bone. Thats why bones show up clearly in an X-ray, while the rest of the body is barely visible. | image | textbook_images/radioactivity_22223.png |
L_0717 | radioactivity | T_3533 | FIGURE 11.2 This periodic table highlights elements that have only radioactive isotopes. | image | textbook_images/radioactivity_22224.png |
L_0717 | radioactivity | T_3534 | FIGURE 11.3 This sign is used to warn people of dan- gerous radiation. | image | textbook_images/radioactivity_22225.png |
L_0717 | radioactivity | T_3535 | FIGURE 11.4 A Geiger counter detects radiation. | image | textbook_images/radioactivity_22226.png |
L_0717 | radioactivity | T_3536 | FIGURE 11.5 This machine scans a patients body and detects radiation. | image | textbook_images/radioactivity_22227.png |
L_0718 | radioactive decay | T_3538 | FIGURE 11.6 Alpha decay results in the loss of two protons and two neutrons from a nucleus. | image | textbook_images/radioactive_decay_22228.png |
L_0718 | radioactive decay | T_3539 | FIGURE 11.7 In beta decay, an electron and a proton form from a neutron (another unusual particle, called an antineutrino, is also produced). Only the electron is emitted from the nucleus. How does this change the atomic number and atomic mass of the atom? | image | textbook_images/radioactive_decay_22229.png |
L_0718 | radioactive decay | T_3541 | FIGURE 11.8 Its easy to stop alpha particles and even beta particles. However, its very difficult to stop gamma rays. | image | textbook_images/radioactive_decay_22230.png |
L_0718 | radioactive decay | T_3542 | FIGURE 11.9 This diagram models the rate of decay of phosphorus-32 to sulfur-32. | image | textbook_images/radioactive_decay_22231.png |
L_0718 | radioactive decay | T_3544 | FIGURE 11.10 After organisms die, the carbon-14 they contain is lost at a constant rate. | image | textbook_images/radioactive_decay_22232.png |
L_0719 | nuclear energy | T_3547 | FIGURE 11.11 This pellet of uranium-235 can release a huge amount of energy if it undergoes nuclear fission. | image | textbook_images/nuclear_energy_22233.png |
L_0719 | nuclear energy | T_3547 | FIGURE 11.12 The fissioning of a nucleus of uranium-235 begins when it captures a neutron. MEDIA Click image to the left or use the URL below. URL: https://www.ck12.org/flx/render/embeddedobject/5018 | image | textbook_images/nuclear_energy_22234.png |
L_0719 | nuclear energy | T_3547 | FIGURE 11.13 In a nuclear chain reaction, each nuclear reaction leads to more nuclear reactions. | image | textbook_images/nuclear_energy_22235.png |
L_0719 | nuclear energy | T_3548 | FIGURE 11.14 This diagram shows the main parts of a nuclear power plant. | image | textbook_images/nuclear_energy_22236.png |
L_0719 | nuclear energy | T_3550 | FIGURE 11.15 In this nuclear fusion reaction, nuclei of two hydrogen isotopes (tritium and deu- terium) fuse together. They form a helium nucleus, a neutron, and energy. | image | textbook_images/nuclear_energy_22237.png |
L_0719 | nuclear energy | T_3552 | FIGURE 11.16 The extremely hot core of the sun radiates energy from nuclear fusion. | image | textbook_images/nuclear_energy_22238.png |
L_0719 | nuclear energy | T_3552 | FIGURE 11.17 In the thermonuclear reactor modeled here, radiation from fusion is used to heat water and form steam. The steam can then be used to turn a turbine and gen- erate electricity. | image | textbook_images/nuclear_energy_22239.png |
L_0719 | nuclear energy | T_3553 | FIGURE 11.18 Albert Einstein is considered by many to be the greatest physicist of all time. | image | textbook_images/nuclear_energy_22240.png |
L_0720 | distance and direction | T_3556 | FIGURE 12.1 These are just a few examples of people or things in motion. If you look around, youre likely to see many more. | image | textbook_images/distance_and_direction_22241.png |
L_0720 | distance and direction | T_3556 | FIGURE 12.2 To a person outside the bus, the buss motion is obvious. To children riding the bus, its motion may not be as obvious. | image | textbook_images/distance_and_direction_22242.png |
L_0720 | distance and direction | T_3557 | FIGURE 12.3 These students are running a 100-meter sprint. | image | textbook_images/distance_and_direction_22243.png |
L_0720 | distance and direction | T_3560 | FIGURE 12.4 This map shows the routes from Mias house to the school, post office, and park. | image | textbook_images/distance_and_direction_22244.png |
L_0721 | speed and velocity | T_3561 | FIGURE 12.6 Speed limit signs like this one warn drivers to reduce their speed on dangerous roads. | image | textbook_images/speed_and_velocity_22246.png |
L_0721 | speed and velocity | T_3562 | FIGURE 12.7 Cars race by in a blur of motion on an open highway but crawl at a snails pace when they hit city traffic. | image | textbook_images/speed_and_velocity_22247.png |
L_0721 | speed and velocity | T_3564 | FIGURE 12.8 This graph shows how far a bike rider is from her starting point at 7:30 AM until she returned at 12:30 PM. | image | textbook_images/speed_and_velocity_22248.png |
L_0721 | speed and velocity | T_3566 | FIGURE 12.9 These vectors show both the speed and direction of motion. | image | textbook_images/speed_and_velocity_22249.png |
L_0722 | acceleration | T_3567 | FIGURE 12.11 How is velocity changing in each of these pictures? sudden. You feel yourself thrust forward. If the car turns right, you feel as though you are being pushed to the left. With a left turn, you feel a push to the right. The next time you ride in a car, notice how it feels as the car accelerates in each of these ways. For an interactive simulation about acceleration, go to this URL: http://phet.colorado.edu/en/ | image | textbook_images/acceleration_22251.png |
L_0722 | acceleration | T_3568 | FIGURE 12.12 Gravity helps this cyclist increase his downhill velocity. | image | textbook_images/acceleration_22252.png |
L_0722 | acceleration | T_3569 | FIGURE 12.13 This graph shows how the velocity of a runner changes during a 10-second sprint. | image | textbook_images/acceleration_22253.png |
L_0723 | what is force | T_3571 | FIGURE 13.1 When this girl pushes the swing away from her, it causes the swing to move in that direction. | image | textbook_images/what_is_force_22254.png |
L_0723 | what is force | T_3571 | FIGURE 13.2 Forces can vary in both strength and direction. | image | textbook_images/what_is_force_22255.png |
L_0723 | what is force | T_3573 | FIGURE 13.3 A book resting on a table is acted on by two opposing forces. | image | textbook_images/what_is_force_22256.png |
L_0723 | what is force | T_3575 | FIGURE 13.4 When unbalanced forces are applied to an object in opposite directions, the smaller force is subtracted from the larger force to yield the net force. | image | textbook_images/what_is_force_22257.png |
L_0723 | what is force | T_3575 | FIGURE 13.5 When two forces are applied to an object in the same direction, the two forces are added to yield the net force. If you need more practice calculating net force, go to this URL: http://www.physicsclassroom.com/class/newtlaws/U | image | textbook_images/what_is_force_22258.png |
L_0724 | friction | T_3576 | FIGURE 13.7 Sometimes friction is useful. Sometimes its not. | image | textbook_images/friction_22260.png |
L_0724 | friction | T_3577 | FIGURE 13.8 The surface of metal looks very smooth unless you look at it under a high-powered microscope. | image | textbook_images/friction_22261.png |
L_0724 | friction | T_3578 | FIGURE 13.9 The knife-like blades of speed skates min- imize friction with the ice. | image | textbook_images/friction_22262.png |
L_0724 | friction | T_3579 | FIGURE 13.10 When you rub the surface of a match head across the rough striking surface on the matchbox, the friction produces enough heat to ignite the match. | image | textbook_images/friction_22263.png |
L_0724 | friction | T_3580 | FIGURE 13.11 A dolly with wheels lets you easily roll boxes across the floor. | image | textbook_images/friction_22264.png |
L_0724 | friction | T_3581 | FIGURE 13.12 Static friction between shoes and the sidewalk makes it possible to walk without slipping. | image | textbook_images/friction_22265.png |
L_0724 | friction | T_3584 | FIGURE 13.13 The ball bearings in this wheel reduce fric- tion between the inner and outer cylinders when they turn. | image | textbook_images/friction_22266.png |
L_0725 | gravity | T_3587 | FIGURE 13.16 A scale measures the pull of gravity on an object. | image | textbook_images/gravity_22269.png |
L_0725 | gravity | T_3588 | FIGURE 13.17 Sir Isaac Newton discovered that gravity is universal. | image | textbook_images/gravity_22270.png |
L_0725 | gravity | T_3591 | FIGURE 13.18 The moon keeps moving around Earth rather than the sun because it is much closer to Earth. | image | textbook_images/gravity_22271.png |
L_0725 | gravity | T_3591 | FIGURE 13.19 Einstein thought that gravity is the effect of curves in space and time around mas- sive objects such as Earth. He proposed that the curves in space and time cause nearby objects to follow a curved path. How does this differ from Newtons idea of gravity? | image | textbook_images/gravity_22272.png |
L_0725 | gravity | T_3593 | FIGURE 13.20 A boy drops an object at time t = 0 s. At time t = 1 s, the object is falling at a velocity of 9.8 m/s. What is its velocity by time t = 5 ? | image | textbook_images/gravity_22273.png |
L_0725 | gravity | T_3594 | FIGURE 13.21 The cannon ball moves in a curved path because of the combined horizontal and downward forces. | image | textbook_images/gravity_22274.png |
L_0725 | gravity | T_3595 | FIGURE 13.22 Aiming at the center of a target is likely to result in a hit below the bulls eye. | image | textbook_images/gravity_22275.png |
L_0725 | gravity | T_3595 | FIGURE 13.23 In this diagram, "v" represents the forward velocity of the moon, and "a" represents the acceleration due to gravity. The line encircling Earth shows the moons actual orbit, which results from the combination of "v" and "a." | image | textbook_images/gravity_22276.png |
L_0727 | newtons first law | T_3598 | FIGURE 14.2 Pool balls remain at rest until an unbal- anced force is applied to them. After they are in motion, they stay in motion until another force opposes their motion. | image | textbook_images/newtons_first_law_22281.png |
L_0727 | newtons first law | T_3600 | FIGURE 14.3 The tendency of an object to resist a change in its motion depends on its mass. Which box has greater inertia? | image | textbook_images/newtons_first_law_22282.png |
L_0727 | newtons first law | T_3601 | FIGURE 14.4 Force must be applied to overcome the inertia of a soccer ball at rest. Once objects start moving, inertia keeps them moving without any additional force being applied. In fact, they wont stop moving unless another unbalanced force opposes their motion. What if the rolling soccer ball is not kicked by another player or stopped by a fence or other object? Will it just keep rolling forever? It would if another unbalanced force did not oppose its motion. Friction in this case rolling friction with the ground will oppose the motion of the rolling soccer ball. As a result, the ball will eventually come to rest. Friction opposes the motion of all moving objects, so, like the soccer ball, all moving objects eventually come to a stop even if no other forces oppose their motion. | image | textbook_images/newtons_first_law_22283.png |
L_0728 | newtons second law | T_3603 | FIGURE 14.6 Hitting a baseball with greater force gives it greater acceleration. Hitting a softball with the same amount of force results in less acceleration. Can you explain why? | image | textbook_images/newtons_second_law_22285.png |
L_0728 | newtons second law | T_3604 | FIGURE 14.7 This empty trunk has a mass of 10 kilo- grams. The weights also have a mass of 10 kilograms. If the weights are placed in the trunk, what will be its mass? How will this affect its acceleration? | image | textbook_images/newtons_second_law_22286.png |
L_0729 | newtons third law | T_3606 | FIGURE 14.9 Each example shown here includes an action and reaction. | image | textbook_images/newtons_third_law_22288.png |
L_0729 | newtons third law | T_3607 | FIGURE 14.10 A bowling ball and a softball differ in mass. How does this affect their momen- tum? | image | textbook_images/newtons_third_law_22289.png |
L_0729 | newtons third law | T_3609 | FIGURE 14.11 How can you tell momentum has been conserved in this collision? | image | textbook_images/newtons_third_law_22290.png |
L_0731 | buoyancy of fluids | T_3624 | FIGURE 15.12 Fluid pressure exerts force on all sides of this object, but the force is greater at the bottom of the object where the fluid is deeper. | image | textbook_images/buoyancy_of_fluids_22302.png |
L_0731 | buoyancy of fluids | T_3626 | FIGURE 15.13 Whether an object sinks or floats depends on its weight and the strength of the buoyant force acting on it. | image | textbook_images/buoyancy_of_fluids_22303.png |
L_0731 | buoyancy of fluids | T_3627 | FIGURE 15.14 The substances pictured here float in a fluid because they are less dense than the fluid. | image | textbook_images/buoyancy_of_fluids_22304.png |
L_0732 | work | T_3628 | FIGURE 16.2 Carrying a box while walking does not result in work being done. Work is done only when the box is first lifted up from the ground. Can you explain why? | image | textbook_images/work_22307.png |
Subsets and Splits