{"id":120252,"date":"2022-05-09T15:51:29","date_gmt":"2022-05-09T10:21:29","guid":{"rendered":"https:\/\/www.mapsofindia.com\/my-india\/?p=120252"},"modified":"2022-05-09T15:51:29","modified_gmt":"2022-05-09T10:21:29","slug":"chapter-11-transport-in-plants-questions-and-answers-ncert-solutions-for-class-11-biology","status":"publish","type":"post","link":"https:\/\/www.mapsofindia.com\/my-india\/education\/chapter-11-transport-in-plants-questions-and-answers-ncert-solutions-for-class-11-biology","title":{"rendered":"Chapter 11 – Transport in Plants Questions and Answers: NCERT Solutions for Class 11 Biology"},"content":{"rendered":"

1. What are the factors affecting the rate of diffusion?<\/h2>\n

Solution:
\nFactors affecting the rate of diffusion are:
\nGradient of concentration
\nThe permeability of the membrane separating them
\nTemperature
\nPressure<\/h3>\n

2. What are porins? What role do they play in diffusion?<\/h2>\n

Solution:
\nThe porins are proteins that form large pores in the outer membranes of the plastids, mitochondria and some bacteria. The large pores allow molecules up to the size of small proteins to pass through. Hence, they promote diffusion.<\/h3>\n

3. Describe the role played by protein pumps during active transport in plants.<\/h2>\n

Solution:
\nProtein pumps use energy to carry substances across the cell membrane. These protein pumps take the substance from a region of lower concentration to the region of higher concentration. They take part in transportation with the help of energy against the concentration gradient, wherein the energy is supplied by ATP. The protein pumps, upon getting activated with energy picks up solute particles from the outside to transfer it to the inside of the cytoplasm. When all the protein pumps are getting used, transport rate reaches its maximum.
\nActive transport is the transport of ions across the membrane of plants through these protein pumps involving energy.<\/h3>\n

4. Explain why pure water has the maximum water potential.<\/h2>\n

Solution:
\nPure water has the maximum water potential because they have the kinetic energy of their own and they remain in constant random motion. The water molecules in pure water possess maximum kinetic energy which decreases with addition of solutes, subsequently free energy of the water molecules gets decreased. Hence, pure water is said to have maximum water potential.<\/h3>\n

5. Differentiate between the following:
\n(a) Diffusion and Osmosis
\n(b) Transpiration and Evaporation
\n(c) Osmotic Pressure and Osmotic Potential
\n(d) Imbibition and Diffusion
\n(e) Apoplast and Symplast pathways of movement of water in plants
\n(f) Guttation and Transpiration<\/h2>\n

Solution:
\na) Diffusion and Osmosis
\nDiffusion
\nOsmosis
\nIt is passive transport in which movement of substance takes place from the region of higher concentration to lower concentration.
\nOsmosis is a special type of diffusion in which substances get separated through a semi-permeable membrane
\nOccurs in any medium
\nOccurs only in the liquid medium
\nDoes not require semi-permeable membrane
\nSemi-permeable membrane required
\nNo role of turgor pressure
\nIt faces resistance by turgor pressure of the system
\nb) Transpiration and Evaporation
\nTranspiration
\nEvaporation
\nTakes place in plants
\nOccurs in any free surface
\nIt is a physiological process
\nIt is a physical process
\nSlower phenomena
\nIt is a fast process comparatively
\nTakes place at the exposed plant surface
\nTakes place at the surface of non-living objects
\nAffected by pH , CO2 and hormones
\nEvaporation is not affected by pH , CO2and hormones
\nc) Osmotic Pressure and Osmotic Potential
\nOsmotic pressure
\nOsmotic potential
\nIt is developed by the entry of water into an osmotic system
\nOsmotic potential is lowering of free energy of water in a system due to the presence of solute particles.
\nIt is developed only in a confined system
\nIt is present in both confined and open systems.
\nIts value is positive and expressed in bars
\nIts value is negative and expressed in bars<\/h3>\n

d) Imbibition and Diffusion
\nImbibition
\nDiffusion
\nAbsorption of water by solid particles without forming solution is called imbibition
\nMovement of substance from a region of higher concentration to the part of lower concentration
\nIt is faster
\nIt is slower comparitively
\nHeat is liberated during imbibition
\nHeat is not liberated during diffusion
\nAdsorbent present
\nAdsorbent absent
\nVolume changes, as the imbibant swells up
\nNo change in the volume of the substance
\ne) Apoplast and Symplast pathways of movement of water in plants
\nApoplast
\nSymplast
\nComprises of nonliving parts of body such as cell walls and intercellular spaces
\nIt consists of living parts of a plant body.
\nFaster comparitively
\nIt is slower
\nSlight resistance offered in the movement of water
\nSome resistance occurs in the water movement through Symplast
\nThe metabolic state of the roots has no impact on the apoplast pathway
\nThe metabolic state of the roots have a direct influence on symplast pathway
\nf) Guttation and Transpiration
\nGuttation
\nTranspiration
\nLoss of liquid droplets from the plant
\nIt is the loss of water in the plant in the form of vapour.
\nTakes place through water pores
\nTakes place through, lenticels, stomata and epidermal cells.
\nDuring guttation water pore is always kept open.
\nStomata may be closed or open during transpiration
\nTakes place during humid periods.
\nTakes place during dry periods.<\/h3>\n

6. Briefly describe water potential. What are the factors affecting it?<\/h2>\n

Solution:
\nWater potential is the tendency of the water to move from one area to other due to osmosis, gravity and mechanical pressure. In other words, it is the difference in the free energy or chemical potential per unit molal volume of water in a system and that of pure water, at the same pressure and temperature. It can be estimated in units of pressure. At a standard temperature and pressure, pure water is defined as possessing a 0 water potential. When solutes are added to water, potential lowers and increase in pressure, increases potential.
\nFactors affecting water potential:
\nSolute potential
\nPressure potential
\nMatric potential
\nPressure
\nTemperature
\nGain\/loss of water<\/h3>\n

7. What happens when a pressure greater than the atmospheric pressure is applied to pure water or a solution?<\/h2>\n

Solution:
\nWhen a pressure greater than the atmospheric pressure is applied to pure water or a solution, its water potential increases.<\/h3>\n

8. (a) With the help of well-labelled diagrams, describe the process of plasmolysis in plants, giving appropriate examples.
\n(b) Explain what will happen to a plant cell if it is kept in a solution having higher water potential.<\/h2>\n

Solution:
\na) When water moves out of the cell and the cell membrane of a plant, cell shrinks away from its cell wall and plasmolysis of the cell takes place. When the cell is placed in a hypertonic solution to the protoplasm (as seen in figure A), water moves out. Water is first lost from the cytoplasm and then from the vacuole. This causes shrinkage of the cell and cell is said to be plasmolysed.
\nb) When plant cell is kept in a solution with higher water potential plant cell absorbs water by endosmosis and the cell becomes turgid or swollen (as observed in figure C). The swollen protoplast develops a wall pressure that becomes equivalent to the water potential of the system thereby resulting in the endosmosis to stop.<\/h3>\n

\"\"<\/p>\n

9. How is the mycorrhizal association helpful in absorption of water and minerals in plants?<\/h2>\n

Solution:
\nHyphae of mycorrhiza have very large surface area which helps in absorbing water and minerals. Thus the association of plants with Mycorrhiza helps in absorption of water and minerals in plants.<\/h3>\n

10. What role does root pressure play in water movement in plants?<\/h2>\n

Solution:
\nIn herbaceous plants, Root pressure helps upward movement of plants.<\/h3>\n

11. Describe transpiration pull model of water transport in plants. What are the factors influencing transpiration? How is it useful to plants?<\/h2>\n

Solution:
\nTranspiration pull helps water rise in tall trees which is created by loss of water or the process of transpiration from the pores of stomata of leaves which is known as cohesion-tension model of water transport. The water that is lost during day time through the process of transpiration results in the epidermal cells and guard cells to turn
\nflaccid. In turn, these take water from the xylem creating a negative pressure or tension in the xylem vessels from the surface of the leaves to root tips, through the stem. Subsequently, water in the xylem gets pulled as a single column from the stem. The adhesion and cohesion forces of the water molecules and cell walls of the xylem vessels restrict the splitting of the water column.
\nFactors affecting transpiration pull are
\nTemperature
\nRelative humidity
\nLight
\nWind
\nPlant factors \u2013 number and distribution of stomata, canopy structure, water status of plants, number of open stomata
\nImportance of transpiration pull
\nIt has a cooling effect on plants
\nTranspiration pull exerts ascent of sap which helps in the distribution of mineral salts.
\nIt helps in retaining shape and structure by keeping the cells turgid.
\nTranspiration helps in the removal of excess water absorbed by the plants.
\nProvides water for photosynthesis<\/h3>\n

12. Discuss the factors responsible for ascent of xylem sap in plants.<\/h2>\n

Solution:
\nFactors responsible for ascent of xylem sap in plants are as follows:
\nCohesion: Mutual attraction between water molecules.
\nAdhesion: Attraction of water molecules to the polar surface.
\nRoot pressure: is a positive pressure which pushes sap from below because of active absorption by roots.
\nSurface tension:attraction of water molecules to each other in the liquid phase more than water in gas phase
\nTransportation Pull: transpiration in aerial regions draws the xylem sap under negative pressure which withdraws water continuously.<\/h3>\n

13. What essential role does the root endodermis play during mineral absorption in plants?<\/h2>\n

Solution:
\nBecause of deposition of lignin and suberin, endodermal cells have thickening in their radial walls. This prevents apoplastic movement of water and minerals, hence allowing only symplastic movement of minerals in plants.<\/h3>\n

14. Explain why xylem transport is unidirectional and phloem transport bi-directional.<\/h2>\n

Solution:
\nWater moves only in the upward direction when absorbed by roots through the xylem. Hence water transport is unidirectional. Food is transported by the phloem tissue. Food is synthesized in leaves and required by both roots and shoot system thus phloem sap moves upwards as well as downwards making food transport bidirectional so that it can reach other plant parts.<\/h3>\n

15. Explain pressure flow hypothesis of translocation of sugars in plants.<\/h2>\n

Solution:
\nFood is continuously prepared in plants in the mesophyll cells of the leaves in the form of glucose. The food that is prepared is converted into sucrose and is then passed to the source cells located in the phloem. Water contained in the xylem vessels moves to the nearest phloem causing the hydrostatic pressure in the phloem to rise. This causes the movement of sucrose via the sieve cells of the phloem. The sucrose that is already found in the sink region converts into starch or cellulose causing a reduction in the hydrostatic pressure in the sink cells. Subsequently, the difference in pressure that is created between the source and the sink cells permits the sugars to be translocated to the latter from the former.<\/h3>\n

\"\"<\/p>\n

16. What causes the opening and closing of guard cells of stomata during transpiration?<\/h2>\n

Solution:
\nCauses for the opening and closing of the stomata is the change in the turgidity of the guard cells. When guard cells become turgid, their thin walls get extended and thick walls become slightly concave to cause the stomatal aperture to open. When water is lost, guard cell lose water, and flat elastic inner walls regain their original shape, thus guard cells become flaccid, and the stomata close.<\/h3>\n","protected":false},"excerpt":{"rendered":"

Class 11 Biology NCERT book solutions for Chapter 11 – Transport in Plants Questions and Answers.<\/p>\n","protected":false},"author":21830,"featured_media":120091,"comment_status":"closed","ping_status":"closed","sticky":false,"template":"","format":"standard","meta":{"footnotes":""},"categories":[7],"tags":[],"class_list":{"0":"post-120252","1":"post","2":"type-post","3":"status-publish","4":"format-standard","5":"has-post-thumbnail","7":"category-education"},"aioseo_notices":[],"_links":{"self":[{"href":"https:\/\/www.mapsofindia.com\/my-india\/wp-json\/wp\/v2\/posts\/120252","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/www.mapsofindia.com\/my-india\/wp-json\/wp\/v2\/posts"}],"about":[{"href":"https:\/\/www.mapsofindia.com\/my-india\/wp-json\/wp\/v2\/types\/post"}],"author":[{"embeddable":true,"href":"https:\/\/www.mapsofindia.com\/my-india\/wp-json\/wp\/v2\/users\/21830"}],"replies":[{"embeddable":true,"href":"https:\/\/www.mapsofindia.com\/my-india\/wp-json\/wp\/v2\/comments?post=120252"}],"version-history":[{"count":1,"href":"https:\/\/www.mapsofindia.com\/my-india\/wp-json\/wp\/v2\/posts\/120252\/revisions"}],"predecessor-version":[{"id":120257,"href":"https:\/\/www.mapsofindia.com\/my-india\/wp-json\/wp\/v2\/posts\/120252\/revisions\/120257"}],"wp:featuredmedia":[{"embeddable":true,"href":"https:\/\/www.mapsofindia.com\/my-india\/wp-json\/wp\/v2\/media\/120091"}],"wp:attachment":[{"href":"https:\/\/www.mapsofindia.com\/my-india\/wp-json\/wp\/v2\/media?parent=120252"}],"wp:term":[{"taxonomy":"category","embeddable":true,"href":"https:\/\/www.mapsofindia.com\/my-india\/wp-json\/wp\/v2\/categories?post=120252"},{"taxonomy":"post_tag","embeddable":true,"href":"https:\/\/www.mapsofindia.com\/my-india\/wp-json\/wp\/v2\/tags?post=120252"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}