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DQ_003675 | What is directly underneath the cuticle? | question_images/parts_leaf_3134.png | a. lower epidermis, b. spongy mesophyll, c. palisade mesophyll, d. upper epidermis | d | DQ_003675 | image | question_images/parts_leaf_3134.png | parts_leaf_3134.png | 1 |
DQ_003675 | What is directly underneath the cuticle? | question_images/parts_leaf_3134.png | a. lower epidermis, b. spongy mesophyll, c. palisade mesophyll, d. upper epidermis | d | DQ_003359 | image | abc_question_images/parts_leaf_13134.png | parts_leaf_13134.png | 0.845626 |
DQ_003675 | What is directly underneath the cuticle? | question_images/parts_leaf_3134.png | a. lower epidermis, b. spongy mesophyll, c. palisade mesophyll, d. upper epidermis | d | DQ_003762 | image | question_images/parts_leaf_556.png | parts_leaf_556.png | 0.77658 |
DQ_003675 | What is directly underneath the cuticle? | question_images/parts_leaf_3134.png | a. lower epidermis, b. spongy mesophyll, c. palisade mesophyll, d. upper epidermis | d | DQ_003733 | image | question_images/parts_leaf_3852.png | parts_leaf_3852.png | 0.767382 |
DQ_003675 | What is directly underneath the cuticle? | question_images/parts_leaf_3134.png | a. lower epidermis, b. spongy mesophyll, c. palisade mesophyll, d. upper epidermis | d | DQ_003698 | image | question_images/parts_leaf_3139.png | parts_leaf_3139.png | 0.764923 |
DQ_003675 | What is directly underneath the cuticle? | question_images/parts_leaf_3134.png | a. lower epidermis, b. spongy mesophyll, c. palisade mesophyll, d. upper epidermis | d | DQ_003601 | image | question_images/parts_leaf_1117.png | parts_leaf_1117.png | 0.764809 |
DQ_003675 | What is directly underneath the cuticle? | question_images/parts_leaf_3134.png | a. lower epidermis, b. spongy mesophyll, c. palisade mesophyll, d. upper epidermis | d | DD_0184 | image | teaching_images/photosynthesis_4103.png | This diagram shows the process of photosynthesis, the process of how plants convert sunlight into energy. The plant uses sunlight and water to make glucose and creates oxygen as a waste product. Chemical energy is stored in the bonds of glucose molecules. | 0.762313 |
DQ_003675 | What is directly underneath the cuticle? | question_images/parts_leaf_3134.png | a. lower epidermis, b. spongy mesophyll, c. palisade mesophyll, d. upper epidermis | d | DD_0183 | image | teaching_images/photosynthesis_1262.png | This diagram depicts photosynthesis. Photosynthesis is the process in which plants synthesize glucose. The process uses carbon dioxide and water and also produces oxygen. The plant gets energy from sunlight using a green pigment called chlorophyll. Photosynthesis changes light energy to chemical energy. The chemical energy is stored in the bonds of glucose molecules. Glucose is used for energy by the cells of almost all living things. Plants make their own glucose. | 0.749443 |
DQ_003675 | What is directly underneath the cuticle? | question_images/parts_leaf_3134.png | a. lower epidermis, b. spongy mesophyll, c. palisade mesophyll, d. upper epidermis | d | DQ_010040 | image | question_images/photosynthesis_1266.png | photosynthesis_1266.png | 0.741384 |
DQ_003675 | What is directly underneath the cuticle? | question_images/parts_leaf_3134.png | a. lower epidermis, b. spongy mesophyll, c. palisade mesophyll, d. upper epidermis | d | DQ_010018 | image | question_images/photosynthesis_1261.png | photosynthesis_1261.png | 0.739174 |
DQ_003675 | What is directly underneath the cuticle? | question_images/parts_leaf_3134.png | a. lower epidermis, b. spongy mesophyll, c. palisade mesophyll, d. upper epidermis | d | T_2134 | text | null | Fingernails and toenails are made of specialized cells that grow out of the epidermis. They too are filled with keratin. The keratin makes them tough and hard. Their job is to protect the ends of the fingers and toes. They also make it easier to feel things with the sensitive fingertips by acting as a counterforce when things are handled. | 0.631274 |
DQ_003675 | What is directly underneath the cuticle? | question_images/parts_leaf_3134.png | a. lower epidermis, b. spongy mesophyll, c. palisade mesophyll, d. upper epidermis | d | T_3201 | text | null | Along with the skin, the integumentary system includes the nails and hair. Both the nails and hair contain the tough protein, keratin. The keratin forms fibers, which makes your nails and hair tough and strong. Keratin is similar in toughness to chitin, the carbohydrate found in the exoskeleton of arthropods. | 0.614619 |
DQ_003675 | What is directly underneath the cuticle? | question_images/parts_leaf_3134.png | a. lower epidermis, b. spongy mesophyll, c. palisade mesophyll, d. upper epidermis | d | T_2132 | text | null | You may spend a lot of time and money on your hair and nails. You may think of them as accessories, like clothes or jewelry. However, like the skin, the hair and nails also play important roles in helping the body maintain homeostasis. | 0.541249 |
DQ_003675 | What is directly underneath the cuticle? | question_images/parts_leaf_3134.png | a. lower epidermis, b. spongy mesophyll, c. palisade mesophyll, d. upper epidermis | d | T_2315 | text | null | Did you ever get a splinter in your skin, like the one in Figure 21.11? It doesnt look like a serious injury, but even a tiny break in the skin may let pathogens enter the body. If bacteria enter through the break, for example, they could cause an infection. These bacteria would then face the bodys second line of defense. | 0.53595 |
DQ_003675 | What is directly underneath the cuticle? | question_images/parts_leaf_3134.png | a. lower epidermis, b. spongy mesophyll, c. palisade mesophyll, d. upper epidermis | d | T_0726 | text | null | Nuclear energy is produced by splitting the nucleus of an atom. This releases a huge amount of energy. | 0.530993 |
DQ_003675 | What is directly underneath the cuticle? | question_images/parts_leaf_3134.png | a. lower epidermis, b. spongy mesophyll, c. palisade mesophyll, d. upper epidermis | d | T_3033 | text | null | Sperm ( Figure 1.1), the male reproductive cells, are tiny. In fact, they are the smallest cells in the human body. What do you think a sperm cell looks like? Some people think that it looks like a tadpole. Do you agree? | 0.528473 |
DQ_003675 | What is directly underneath the cuticle? | question_images/parts_leaf_3134.png | a. lower epidermis, b. spongy mesophyll, c. palisade mesophyll, d. upper epidermis | d | T_1468 | text | null | Minerals are made by natural processes, those that occur in or on Earth. A diamond created deep in Earths crust is a mineral, but a diamond made in a laboratory by humans is not. Be careful about buying a laboratory-made diamond for jewelry. It may look pretty, but its not a diamond and is not technically a mineral. | 0.522328 |
DQ_003675 | What is directly underneath the cuticle? | question_images/parts_leaf_3134.png | a. lower epidermis, b. spongy mesophyll, c. palisade mesophyll, d. upper epidermis | d | T_1106 | text | null | Despite these problems, there is a rich fossil record. How does an organism become fossilized? | 0.521973 |
DQ_003675 | What is directly underneath the cuticle? | question_images/parts_leaf_3134.png | a. lower epidermis, b. spongy mesophyll, c. palisade mesophyll, d. upper epidermis | d | T_4844 | text | null | An electric circuit consists of at least one closed loop through which electric current can flow. Every circuit has a voltage source such as a battery and a conductor such as metal wire. A circuit may have other parts as well, such as lights and switches. In addition, a circuit may consist of one loop or two loops. | 0.521348 |
DQ_003675 | What is directly underneath the cuticle? | question_images/parts_leaf_3134.png | a. lower epidermis, b. spongy mesophyll, c. palisade mesophyll, d. upper epidermis | d | T_3860 | text | null | Electric current cannot travel through empty space. It needs a material through which to travel. However, when current travels through a material, the flowing electrons collide with particles of the material, and this creates resistance. | 0.520986 |
DQ_003676 | Oxygen enters and carbon dioxide exits through which part of the plant? | question_images/parts_leaf_3134.png | a. cuticle, b. guard cells, c. epidermis, d. mesophyll | b | DQ_003675 | image | question_images/parts_leaf_3134.png | parts_leaf_3134.png | 1 |
DQ_003676 | Oxygen enters and carbon dioxide exits through which part of the plant? | question_images/parts_leaf_3134.png | a. cuticle, b. guard cells, c. epidermis, d. mesophyll | b | DQ_003359 | image | abc_question_images/parts_leaf_13134.png | parts_leaf_13134.png | 0.845626 |
DQ_003676 | Oxygen enters and carbon dioxide exits through which part of the plant? | question_images/parts_leaf_3134.png | a. cuticle, b. guard cells, c. epidermis, d. mesophyll | b | DQ_003762 | image | question_images/parts_leaf_556.png | parts_leaf_556.png | 0.77658 |
DQ_003676 | Oxygen enters and carbon dioxide exits through which part of the plant? | question_images/parts_leaf_3134.png | a. cuticle, b. guard cells, c. epidermis, d. mesophyll | b | DQ_003733 | image | question_images/parts_leaf_3852.png | parts_leaf_3852.png | 0.767382 |
DQ_003676 | Oxygen enters and carbon dioxide exits through which part of the plant? | question_images/parts_leaf_3134.png | a. cuticle, b. guard cells, c. epidermis, d. mesophyll | b | DQ_003698 | image | question_images/parts_leaf_3139.png | parts_leaf_3139.png | 0.764923 |
DQ_003676 | Oxygen enters and carbon dioxide exits through which part of the plant? | question_images/parts_leaf_3134.png | a. cuticle, b. guard cells, c. epidermis, d. mesophyll | b | DQ_003601 | image | question_images/parts_leaf_1117.png | parts_leaf_1117.png | 0.764809 |
DQ_003676 | Oxygen enters and carbon dioxide exits through which part of the plant? | question_images/parts_leaf_3134.png | a. cuticle, b. guard cells, c. epidermis, d. mesophyll | b | DD_0184 | image | teaching_images/photosynthesis_4103.png | This diagram shows the process of photosynthesis, the process of how plants convert sunlight into energy. The plant uses sunlight and water to make glucose and creates oxygen as a waste product. Chemical energy is stored in the bonds of glucose molecules. | 0.762313 |
DQ_003676 | Oxygen enters and carbon dioxide exits through which part of the plant? | question_images/parts_leaf_3134.png | a. cuticle, b. guard cells, c. epidermis, d. mesophyll | b | DD_0183 | image | teaching_images/photosynthesis_1262.png | This diagram depicts photosynthesis. Photosynthesis is the process in which plants synthesize glucose. The process uses carbon dioxide and water and also produces oxygen. The plant gets energy from sunlight using a green pigment called chlorophyll. Photosynthesis changes light energy to chemical energy. The chemical energy is stored in the bonds of glucose molecules. Glucose is used for energy by the cells of almost all living things. Plants make their own glucose. | 0.749443 |
DQ_003676 | Oxygen enters and carbon dioxide exits through which part of the plant? | question_images/parts_leaf_3134.png | a. cuticle, b. guard cells, c. epidermis, d. mesophyll | b | DQ_010040 | image | question_images/photosynthesis_1266.png | photosynthesis_1266.png | 0.741384 |
DQ_003676 | Oxygen enters and carbon dioxide exits through which part of the plant? | question_images/parts_leaf_3134.png | a. cuticle, b. guard cells, c. epidermis, d. mesophyll | b | DQ_010018 | image | question_images/photosynthesis_1261.png | photosynthesis_1261.png | 0.739174 |
DQ_003676 | Oxygen enters and carbon dioxide exits through which part of the plant? | question_images/parts_leaf_3134.png | a. cuticle, b. guard cells, c. epidermis, d. mesophyll | b | T_1312 | text | null | In photosynthesis, plants use CO2 and create O2 . Photosynthesis is responsible for nearly all of the oxygen currently found in the atmosphere. The chemical reaction for photosynthesis is: 6CO2 + 6H2 O + solar energy C6 H12 O6 (sugar) + 6O2 | 0.748193 |
DQ_003676 | Oxygen enters and carbon dioxide exits through which part of the plant? | question_images/parts_leaf_3134.png | a. cuticle, b. guard cells, c. epidermis, d. mesophyll | b | T_0960 | text | null | Through photosynthesis, the inorganic carbon in carbon dioxide plus water and energy from sunlight is transformed into organic carbon (food) with oxygen given off as a waste product. The chemical equation for photosynthesis is: | 0.712103 |
DQ_003676 | Oxygen enters and carbon dioxide exits through which part of the plant? | question_images/parts_leaf_3134.png | a. cuticle, b. guard cells, c. epidermis, d. mesophyll | b | T_0959 | text | null | The short term cycling of carbon begins with carbon dioxide (CO2 ) in the atmosphere. | 0.712014 |
DQ_003676 | Oxygen enters and carbon dioxide exits through which part of the plant? | question_images/parts_leaf_3134.png | a. cuticle, b. guard cells, c. epidermis, d. mesophyll | b | T_3385 | text | null | Plants seem to grow wherever they can. How? Plants cant move on their own. So how does a plant start growing in a new area? | 0.697635 |
DQ_003676 | Oxygen enters and carbon dioxide exits through which part of the plant? | question_images/parts_leaf_3134.png | a. cuticle, b. guard cells, c. epidermis, d. mesophyll | b | T_0966 | text | null | Why is such a small amount of carbon dioxide in the atmosphere even important? Carbon dioxide is a greenhouse gas. Greenhouse gases trap heat energy that would otherwise radiate out into space, which warms Earth. These gases were discussed in the chapter Atmospheric Processes. | 0.695486 |
DQ_003676 | Oxygen enters and carbon dioxide exits through which part of the plant? | question_images/parts_leaf_3134.png | a. cuticle, b. guard cells, c. epidermis, d. mesophyll | b | T_3299 | text | null | What goes into the cell? Oxygen and glucose are both reactants of cellular respiration. Oxygen enters the body when an organism breathes. Glucose enters the body when an organism eats. | 0.693357 |
DQ_003676 | Oxygen enters and carbon dioxide exits through which part of the plant? | question_images/parts_leaf_3134.png | a. cuticle, b. guard cells, c. epidermis, d. mesophyll | b | T_1598 | text | null | Plants and animals depend on water to live. They also play a role in the water cycle. Plants take up water from the soil and release large amounts of water vapor into the air through their leaves (Figure 1.3), a process known as transpiration. | 0.691803 |
DQ_003676 | Oxygen enters and carbon dioxide exits through which part of the plant? | question_images/parts_leaf_3134.png | a. cuticle, b. guard cells, c. epidermis, d. mesophyll | b | T_3434 | text | null | Water also moves through the living organisms in an ecosystem. Plants soak up large amounts of water through their roots. The water then moves up the plant and evaporates from the leaves in a process called transpiration. The process of transpiration, like evaporation, returns water back into the atmosphere. | 0.689393 |
DQ_003676 | Oxygen enters and carbon dioxide exits through which part of the plant? | question_images/parts_leaf_3134.png | a. cuticle, b. guard cells, c. epidermis, d. mesophyll | b | T_0987 | text | null | Now that you know what chemical weathering is, can you think of some other ways chemical weathering might occur? Chemical weathering can also be contributed to by plants and animals. As plant roots take in soluble ions as nutrients, certain elements are exchanged. Plant roots and bacterial decay use carbon dioxide in the process of respiration. | 0.684268 |
DQ_003676 | Oxygen enters and carbon dioxide exits through which part of the plant? | question_images/parts_leaf_3134.png | a. cuticle, b. guard cells, c. epidermis, d. mesophyll | b | T_1797 | text | null | The two types of air pollutants are primary pollutants, which enter the atmosphere directly, and secondary pollutants, which form from a chemical reaction. | 0.68082 |
DQ_003677 | What are the tiny openings on the underside of leaves called? | question_images/parts_leaf_3134.png | a. Upper Epidermis, b. Stoma, c. Lower Epidermis, d. Cuticle | b | DQ_003675 | image | question_images/parts_leaf_3134.png | parts_leaf_3134.png | 1 |
DQ_003677 | What are the tiny openings on the underside of leaves called? | question_images/parts_leaf_3134.png | a. Upper Epidermis, b. Stoma, c. Lower Epidermis, d. Cuticle | b | DQ_003359 | image | abc_question_images/parts_leaf_13134.png | parts_leaf_13134.png | 0.845626 |
DQ_003677 | What are the tiny openings on the underside of leaves called? | question_images/parts_leaf_3134.png | a. Upper Epidermis, b. Stoma, c. Lower Epidermis, d. Cuticle | b | DQ_003762 | image | question_images/parts_leaf_556.png | parts_leaf_556.png | 0.77658 |
DQ_003677 | What are the tiny openings on the underside of leaves called? | question_images/parts_leaf_3134.png | a. Upper Epidermis, b. Stoma, c. Lower Epidermis, d. Cuticle | b | DQ_003733 | image | question_images/parts_leaf_3852.png | parts_leaf_3852.png | 0.767382 |
DQ_003677 | What are the tiny openings on the underside of leaves called? | question_images/parts_leaf_3134.png | a. Upper Epidermis, b. Stoma, c. Lower Epidermis, d. Cuticle | b | DQ_003698 | image | question_images/parts_leaf_3139.png | parts_leaf_3139.png | 0.764923 |
DQ_003677 | What are the tiny openings on the underside of leaves called? | question_images/parts_leaf_3134.png | a. Upper Epidermis, b. Stoma, c. Lower Epidermis, d. Cuticle | b | DQ_003601 | image | question_images/parts_leaf_1117.png | parts_leaf_1117.png | 0.764809 |
DQ_003677 | What are the tiny openings on the underside of leaves called? | question_images/parts_leaf_3134.png | a. Upper Epidermis, b. Stoma, c. Lower Epidermis, d. Cuticle | b | DD_0184 | image | teaching_images/photosynthesis_4103.png | This diagram shows the process of photosynthesis, the process of how plants convert sunlight into energy. The plant uses sunlight and water to make glucose and creates oxygen as a waste product. Chemical energy is stored in the bonds of glucose molecules. | 0.762313 |
DQ_003677 | What are the tiny openings on the underside of leaves called? | question_images/parts_leaf_3134.png | a. Upper Epidermis, b. Stoma, c. Lower Epidermis, d. Cuticle | b | DD_0183 | image | teaching_images/photosynthesis_1262.png | This diagram depicts photosynthesis. Photosynthesis is the process in which plants synthesize glucose. The process uses carbon dioxide and water and also produces oxygen. The plant gets energy from sunlight using a green pigment called chlorophyll. Photosynthesis changes light energy to chemical energy. The chemical energy is stored in the bonds of glucose molecules. Glucose is used for energy by the cells of almost all living things. Plants make their own glucose. | 0.749443 |
DQ_003677 | What are the tiny openings on the underside of leaves called? | question_images/parts_leaf_3134.png | a. Upper Epidermis, b. Stoma, c. Lower Epidermis, d. Cuticle | b | DQ_010040 | image | question_images/photosynthesis_1266.png | photosynthesis_1266.png | 0.741384 |
DQ_003677 | What are the tiny openings on the underside of leaves called? | question_images/parts_leaf_3134.png | a. Upper Epidermis, b. Stoma, c. Lower Epidermis, d. Cuticle | b | DQ_010018 | image | question_images/photosynthesis_1261.png | photosynthesis_1261.png | 0.739174 |
DQ_003677 | What are the tiny openings on the underside of leaves called? | question_images/parts_leaf_3134.png | a. Upper Epidermis, b. Stoma, c. Lower Epidermis, d. Cuticle | b | T_1598 | text | null | Plants and animals depend on water to live. They also play a role in the water cycle. Plants take up water from the soil and release large amounts of water vapor into the air through their leaves (Figure 1.3), a process known as transpiration. | 0.623197 |
DQ_003677 | What are the tiny openings on the underside of leaves called? | question_images/parts_leaf_3134.png | a. Upper Epidermis, b. Stoma, c. Lower Epidermis, d. Cuticle | b | T_3434 | text | null | Water also moves through the living organisms in an ecosystem. Plants soak up large amounts of water through their roots. The water then moves up the plant and evaporates from the leaves in a process called transpiration. The process of transpiration, like evaporation, returns water back into the atmosphere. | 0.609433 |
DQ_003677 | What are the tiny openings on the underside of leaves called? | question_images/parts_leaf_3134.png | a. Upper Epidermis, b. Stoma, c. Lower Epidermis, d. Cuticle | b | T_3385 | text | null | Plants seem to grow wherever they can. How? Plants cant move on their own. So how does a plant start growing in a new area? | 0.599743 |
DQ_003677 | What are the tiny openings on the underside of leaves called? | question_images/parts_leaf_3134.png | a. Upper Epidermis, b. Stoma, c. Lower Epidermis, d. Cuticle | b | T_1698 | text | null | How well soil forms and what type of soil forms depends on several different factors, which are described below. | 0.588745 |
DQ_003677 | What are the tiny openings on the underside of leaves called? | question_images/parts_leaf_3134.png | a. Upper Epidermis, b. Stoma, c. Lower Epidermis, d. Cuticle | b | T_1950 | text | null | The most basic division of modern plants is between nonvascular and vascular plants. Vascular plants are further divided into those that reproduce without seeds and those that reproduce with seeds. Seed plants, in turn, are divided into those that produce naked seeds in cones and those that produce seeds in the ovaries of flowers. | 0.586079 |
DQ_003677 | What are the tiny openings on the underside of leaves called? | question_images/parts_leaf_3134.png | a. Upper Epidermis, b. Stoma, c. Lower Epidermis, d. Cuticle | b | T_1106 | text | null | Despite these problems, there is a rich fossil record. How does an organism become fossilized? | 0.580987 |
DQ_003677 | What are the tiny openings on the underside of leaves called? | question_images/parts_leaf_3134.png | a. Upper Epidermis, b. Stoma, c. Lower Epidermis, d. Cuticle | b | T_1312 | text | null | In photosynthesis, plants use CO2 and create O2 . Photosynthesis is responsible for nearly all of the oxygen currently found in the atmosphere. The chemical reaction for photosynthesis is: 6CO2 + 6H2 O + solar energy C6 H12 O6 (sugar) + 6O2 | 0.580494 |
DQ_003677 | What are the tiny openings on the underside of leaves called? | question_images/parts_leaf_3134.png | a. Upper Epidermis, b. Stoma, c. Lower Epidermis, d. Cuticle | b | T_2956 | text | null | Scientists used to think that fungi were members of the plant kingdom. They thought this because fungi had several similarities to plants. For example: Fungi and plants have similar structures. Plants and fungi live in the same kinds of habitats, such as growing in soil. Plants and fungi cells both have a cell wall, which animals do not have. | 0.57872 |
DQ_003677 | What are the tiny openings on the underside of leaves called? | question_images/parts_leaf_3134.png | a. Upper Epidermis, b. Stoma, c. Lower Epidermis, d. Cuticle | b | T_1947 | text | null | Some seed plants evolved another major adaptation. This was the formation of seeds in flowers. Flowers are plant structures that contain male and/or female reproductive organs. | 0.561974 |
DQ_003677 | What are the tiny openings on the underside of leaves called? | question_images/parts_leaf_3134.png | a. Upper Epidermis, b. Stoma, c. Lower Epidermis, d. Cuticle | b | T_3065 | text | null | Many insects are considered to be pests by humans. However, insects are also very important for numerous reasons. | 0.561504 |
DQ_003678 | What connects the cuticle and the palisade mesophyll? | question_images/parts_leaf_3134.png | a. upper epidermis, b. lower epidermis, c. lower epidermis, d. guard cells | a | DQ_003675 | image | question_images/parts_leaf_3134.png | parts_leaf_3134.png | 1 |
DQ_003678 | What connects the cuticle and the palisade mesophyll? | question_images/parts_leaf_3134.png | a. upper epidermis, b. lower epidermis, c. lower epidermis, d. guard cells | a | DQ_003359 | image | abc_question_images/parts_leaf_13134.png | parts_leaf_13134.png | 0.845626 |
DQ_003678 | What connects the cuticle and the palisade mesophyll? | question_images/parts_leaf_3134.png | a. upper epidermis, b. lower epidermis, c. lower epidermis, d. guard cells | a | DQ_003762 | image | question_images/parts_leaf_556.png | parts_leaf_556.png | 0.77658 |
DQ_003678 | What connects the cuticle and the palisade mesophyll? | question_images/parts_leaf_3134.png | a. upper epidermis, b. lower epidermis, c. lower epidermis, d. guard cells | a | DQ_003733 | image | question_images/parts_leaf_3852.png | parts_leaf_3852.png | 0.767382 |
DQ_003678 | What connects the cuticle and the palisade mesophyll? | question_images/parts_leaf_3134.png | a. upper epidermis, b. lower epidermis, c. lower epidermis, d. guard cells | a | DQ_003698 | image | question_images/parts_leaf_3139.png | parts_leaf_3139.png | 0.764923 |
DQ_003678 | What connects the cuticle and the palisade mesophyll? | question_images/parts_leaf_3134.png | a. upper epidermis, b. lower epidermis, c. lower epidermis, d. guard cells | a | DQ_003601 | image | question_images/parts_leaf_1117.png | parts_leaf_1117.png | 0.764809 |
DQ_003678 | What connects the cuticle and the palisade mesophyll? | question_images/parts_leaf_3134.png | a. upper epidermis, b. lower epidermis, c. lower epidermis, d. guard cells | a | DD_0184 | image | teaching_images/photosynthesis_4103.png | This diagram shows the process of photosynthesis, the process of how plants convert sunlight into energy. The plant uses sunlight and water to make glucose and creates oxygen as a waste product. Chemical energy is stored in the bonds of glucose molecules. | 0.762313 |
DQ_003678 | What connects the cuticle and the palisade mesophyll? | question_images/parts_leaf_3134.png | a. upper epidermis, b. lower epidermis, c. lower epidermis, d. guard cells | a | DD_0183 | image | teaching_images/photosynthesis_1262.png | This diagram depicts photosynthesis. Photosynthesis is the process in which plants synthesize glucose. The process uses carbon dioxide and water and also produces oxygen. The plant gets energy from sunlight using a green pigment called chlorophyll. Photosynthesis changes light energy to chemical energy. The chemical energy is stored in the bonds of glucose molecules. Glucose is used for energy by the cells of almost all living things. Plants make their own glucose. | 0.749443 |
DQ_003678 | What connects the cuticle and the palisade mesophyll? | question_images/parts_leaf_3134.png | a. upper epidermis, b. lower epidermis, c. lower epidermis, d. guard cells | a | DQ_010040 | image | question_images/photosynthesis_1266.png | photosynthesis_1266.png | 0.741384 |
DQ_003678 | What connects the cuticle and the palisade mesophyll? | question_images/parts_leaf_3134.png | a. upper epidermis, b. lower epidermis, c. lower epidermis, d. guard cells | a | DQ_010018 | image | question_images/photosynthesis_1261.png | photosynthesis_1261.png | 0.739174 |
DQ_003678 | What connects the cuticle and the palisade mesophyll? | question_images/parts_leaf_3134.png | a. upper epidermis, b. lower epidermis, c. lower epidermis, d. guard cells | a | T_2023 | text | null | Chordates have three embryonic cell layers: endoderm, mesoderm, and ectoderm. They also have a segmented body with a complete coelom and bilateral symmetry. In addition, chordates have a complete digestive system, central nervous system, and circulatory system. | 0.516629 |
DQ_003678 | What connects the cuticle and the palisade mesophyll? | question_images/parts_leaf_3134.png | a. upper epidermis, b. lower epidermis, c. lower epidermis, d. guard cells | a | T_2469 | text | null | Why does a cell have cytoplasm? Cytoplasm has several important functions. These include: suspending cell organelles. pushing against the cell membrane to help the cell keep its shape. providing a site for many of the biochemical reactions of the cell. | 0.515333 |
DQ_003678 | What connects the cuticle and the palisade mesophyll? | question_images/parts_leaf_3134.png | a. upper epidermis, b. lower epidermis, c. lower epidermis, d. guard cells | a | T_3201 | text | null | Along with the skin, the integumentary system includes the nails and hair. Both the nails and hair contain the tough protein, keratin. The keratin forms fibers, which makes your nails and hair tough and strong. Keratin is similar in toughness to chitin, the carbohydrate found in the exoskeleton of arthropods. | 0.50541 |
DQ_003678 | What connects the cuticle and the palisade mesophyll? | question_images/parts_leaf_3134.png | a. upper epidermis, b. lower epidermis, c. lower epidermis, d. guard cells | a | T_3299 | text | null | What goes into the cell? Oxygen and glucose are both reactants of cellular respiration. Oxygen enters the body when an organism breathes. Glucose enters the body when an organism eats. | 0.496101 |
DQ_003678 | What connects the cuticle and the palisade mesophyll? | question_images/parts_leaf_3134.png | a. upper epidermis, b. lower epidermis, c. lower epidermis, d. guard cells | a | T_2268 | text | null | The sensory division of the peripheral nervous system carries messages from sense organs and internal organs to the central nervous system. For example, it carries messages about images from the eyes to the brain. Once the messages reach the brain, the brain interprets the information. | 0.490542 |
DQ_003678 | What connects the cuticle and the palisade mesophyll? | question_images/parts_leaf_3134.png | a. upper epidermis, b. lower epidermis, c. lower epidermis, d. guard cells | a | T_2134 | text | null | Fingernails and toenails are made of specialized cells that grow out of the epidermis. They too are filled with keratin. The keratin makes them tough and hard. Their job is to protect the ends of the fingers and toes. They also make it easier to feel things with the sensitive fingertips by acting as a counterforce when things are handled. | 0.48981 |
DQ_003678 | What connects the cuticle and the palisade mesophyll? | question_images/parts_leaf_3134.png | a. upper epidermis, b. lower epidermis, c. lower epidermis, d. guard cells | a | T_2471 | text | null | Eukaryotic cells contain a nucleus and several other types of organelles. These structures carry out many vital cell functions. | 0.489781 |
DQ_003678 | What connects the cuticle and the palisade mesophyll? | question_images/parts_leaf_3134.png | a. upper epidermis, b. lower epidermis, c. lower epidermis, d. guard cells | a | T_2956 | text | null | Scientists used to think that fungi were members of the plant kingdom. They thought this because fungi had several similarities to plants. For example: Fungi and plants have similar structures. Plants and fungi live in the same kinds of habitats, such as growing in soil. Plants and fungi cells both have a cell wall, which animals do not have. | 0.487144 |
DQ_003678 | What connects the cuticle and the palisade mesophyll? | question_images/parts_leaf_3134.png | a. upper epidermis, b. lower epidermis, c. lower epidermis, d. guard cells | a | T_1950 | text | null | The most basic division of modern plants is between nonvascular and vascular plants. Vascular plants are further divided into those that reproduce without seeds and those that reproduce with seeds. Seed plants, in turn, are divided into those that produce naked seeds in cones and those that produce seeds in the ovaries of flowers. | 0.485953 |
DQ_003678 | What connects the cuticle and the palisade mesophyll? | question_images/parts_leaf_3134.png | a. upper epidermis, b. lower epidermis, c. lower epidermis, d. guard cells | a | T_2315 | text | null | Did you ever get a splinter in your skin, like the one in Figure 21.11? It doesnt look like a serious injury, but even a tiny break in the skin may let pathogens enter the body. If bacteria enter through the break, for example, they could cause an infection. These bacteria would then face the bodys second line of defense. | 0.48226 |
DQ_003679 | What's between the upper and lower epidermis? | question_images/parts_leaf_3134.png | a. Cuticle, b. Palisade, c. Epidermis, d. Palisade and spongy mesophyll | b | DQ_003675 | image | question_images/parts_leaf_3134.png | parts_leaf_3134.png | 1 |
DQ_003679 | What's between the upper and lower epidermis? | question_images/parts_leaf_3134.png | a. Cuticle, b. Palisade, c. Epidermis, d. Palisade and spongy mesophyll | b | DQ_003359 | image | abc_question_images/parts_leaf_13134.png | parts_leaf_13134.png | 0.845626 |
DQ_003679 | What's between the upper and lower epidermis? | question_images/parts_leaf_3134.png | a. Cuticle, b. Palisade, c. Epidermis, d. Palisade and spongy mesophyll | b | DQ_003762 | image | question_images/parts_leaf_556.png | parts_leaf_556.png | 0.77658 |
DQ_003679 | What's between the upper and lower epidermis? | question_images/parts_leaf_3134.png | a. Cuticle, b. Palisade, c. Epidermis, d. Palisade and spongy mesophyll | b | DQ_003733 | image | question_images/parts_leaf_3852.png | parts_leaf_3852.png | 0.767382 |
DQ_003679 | What's between the upper and lower epidermis? | question_images/parts_leaf_3134.png | a. Cuticle, b. Palisade, c. Epidermis, d. Palisade and spongy mesophyll | b | DQ_003698 | image | question_images/parts_leaf_3139.png | parts_leaf_3139.png | 0.764923 |
DQ_003679 | What's between the upper and lower epidermis? | question_images/parts_leaf_3134.png | a. Cuticle, b. Palisade, c. Epidermis, d. Palisade and spongy mesophyll | b | DQ_003601 | image | question_images/parts_leaf_1117.png | parts_leaf_1117.png | 0.764809 |
DQ_003679 | What's between the upper and lower epidermis? | question_images/parts_leaf_3134.png | a. Cuticle, b. Palisade, c. Epidermis, d. Palisade and spongy mesophyll | b | DD_0184 | image | teaching_images/photosynthesis_4103.png | This diagram shows the process of photosynthesis, the process of how plants convert sunlight into energy. The plant uses sunlight and water to make glucose and creates oxygen as a waste product. Chemical energy is stored in the bonds of glucose molecules. | 0.762313 |
DQ_003679 | What's between the upper and lower epidermis? | question_images/parts_leaf_3134.png | a. Cuticle, b. Palisade, c. Epidermis, d. Palisade and spongy mesophyll | b | DD_0183 | image | teaching_images/photosynthesis_1262.png | This diagram depicts photosynthesis. Photosynthesis is the process in which plants synthesize glucose. The process uses carbon dioxide and water and also produces oxygen. The plant gets energy from sunlight using a green pigment called chlorophyll. Photosynthesis changes light energy to chemical energy. The chemical energy is stored in the bonds of glucose molecules. Glucose is used for energy by the cells of almost all living things. Plants make their own glucose. | 0.749443 |
DQ_003679 | What's between the upper and lower epidermis? | question_images/parts_leaf_3134.png | a. Cuticle, b. Palisade, c. Epidermis, d. Palisade and spongy mesophyll | b | DQ_010040 | image | question_images/photosynthesis_1266.png | photosynthesis_1266.png | 0.741384 |
DQ_003679 | What's between the upper and lower epidermis? | question_images/parts_leaf_3134.png | a. Cuticle, b. Palisade, c. Epidermis, d. Palisade and spongy mesophyll | b | DQ_010018 | image | question_images/photosynthesis_1261.png | photosynthesis_1261.png | 0.739174 |
DQ_003679 | What's between the upper and lower epidermis? | question_images/parts_leaf_3134.png | a. Cuticle, b. Palisade, c. Epidermis, d. Palisade and spongy mesophyll | b | T_3120 | text | null | Your skin is your largest organ and constantly protects you from infections, so keeping your skin healthy is a good idea. | 0.632149 |
DQ_003679 | What's between the upper and lower epidermis? | question_images/parts_leaf_3134.png | a. Cuticle, b. Palisade, c. Epidermis, d. Palisade and spongy mesophyll | b | T_1106 | text | null | Despite these problems, there is a rich fossil record. How does an organism become fossilized? | 0.594814 |
DQ_003679 | What's between the upper and lower epidermis? | question_images/parts_leaf_3134.png | a. Cuticle, b. Palisade, c. Epidermis, d. Palisade and spongy mesophyll | b | T_1698 | text | null | How well soil forms and what type of soil forms depends on several different factors, which are described below. | 0.586726 |
DQ_003679 | What's between the upper and lower epidermis? | question_images/parts_leaf_3134.png | a. Cuticle, b. Palisade, c. Epidermis, d. Palisade and spongy mesophyll | b | T_2534 | text | null | Both types of reproduction have certain advantages. | 0.574157 |
DQ_003679 | What's between the upper and lower epidermis? | question_images/parts_leaf_3134.png | a. Cuticle, b. Palisade, c. Epidermis, d. Palisade and spongy mesophyll | b | T_3234 | text | null | Your heart pumps blood around your body. But how does your heart get blood to and from every cell in your body? Your heart is connected to blood vessels such as veins and arteries. Organs that work together form an organ system. Together, your heart, blood, and blood vessels form your cardiovascular system. What other organ systems can you think of? | 0.572933 |
DQ_003679 | What's between the upper and lower epidermis? | question_images/parts_leaf_3134.png | a. Cuticle, b. Palisade, c. Epidermis, d. Palisade and spongy mesophyll | b | T_3201 | text | null | Along with the skin, the integumentary system includes the nails and hair. Both the nails and hair contain the tough protein, keratin. The keratin forms fibers, which makes your nails and hair tough and strong. Keratin is similar in toughness to chitin, the carbohydrate found in the exoskeleton of arthropods. | 0.570993 |
DQ_003679 | What's between the upper and lower epidermis? | question_images/parts_leaf_3134.png | a. Cuticle, b. Palisade, c. Epidermis, d. Palisade and spongy mesophyll | b | T_2121 | text | null | The basic building blocks of the human body are cells. Human cells are organized into tissues, tissues are organized into organs, and organs are organized into organ systems. | 0.56738 |
DQ_003679 | What's between the upper and lower epidermis? | question_images/parts_leaf_3134.png | a. Cuticle, b. Palisade, c. Epidermis, d. Palisade and spongy mesophyll | b | T_2758 | text | null | You are not aware of them, but your skin is covered by millions (or more!) of bacteria. Millions more live inside your body. Most of these bacteria help defend your body from pathogens. How do they do it? They compete with harmful bacteria for food and space. This prevents the harmful bacteria from multiplying and making you sick. | 0.561986 |
DQ_003679 | What's between the upper and lower epidermis? | question_images/parts_leaf_3134.png | a. Cuticle, b. Palisade, c. Epidermis, d. Palisade and spongy mesophyll | b | T_2315 | text | null | Did you ever get a splinter in your skin, like the one in Figure 21.11? It doesnt look like a serious injury, but even a tiny break in the skin may let pathogens enter the body. If bacteria enter through the break, for example, they could cause an infection. These bacteria would then face the bodys second line of defense. | 0.560111 |
DQ_003679 | What's between the upper and lower epidermis? | question_images/parts_leaf_3134.png | a. Cuticle, b. Palisade, c. Epidermis, d. Palisade and spongy mesophyll | b | T_0078 | text | null | When rock layers are in the same place, its easy to give them relative ages. But what if rock layers are far apart? What if they are on different continents? What evidence is used to match rock layers in different places? | 0.558396 |
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