Videos
To analyze:
The properties and role of water in the movement of nutrient in plants.
Introduction:
Water plays an important role in plant life. For proper growth and development, and for maintaining all the physiological activities of the cell, a proper balance of water is very much necessary. Water is released from the plant and again produced in the plant to keep it in a balanced state.
Explanation of Solution
In a plant’s life, the requirement of water is always maintained so that the plants are able to survive in any environmental conditions. There are some properties of water which helps the movement of nutrients in plants and other functions too. Some of the properties of water are:
The Polarity of water: Water is made up of two molecules of hydrogen and one molecule of oxygen where the two-hydrogen atom binds to one side of the oxygen creating an imbalance in the polarity. The hydrogen atom will have the least positive charge and more negative charge is developed in the oxygen atom. This always keeps the water in the liquid state. It is very easy for plants to absorb water in its liquid state from the soil and transport it to other parts. Because of its difference in polarity, the shape of water can easily be changed to droplets.
Cohesion and Adhesion: The more electronegative property of the oxygen side in the water attracts the positive hydrogen side of other water molecules forming a hydrogen bond between them. This results in clumping of water molecules together forming droplets and once they stick to the xylem, it helps in their easy movement to a larger distance.
Capillary Property: The capillary action of water brings the water molecules on the surface of the leaf through the xylem. The evaporation at the surface of the leaf and the cohesion-adhesion properties of water makes the water molecules to move in a narrow capillary tube and maintain the continuity of water columns in plants.
High specific heat: The water droplet, once they reach the surface of the leaf, will evaporate and release oxygen and hydrogen molecule in the atmosphere. The oxygen and hydrogen molecules are released in an exchange process. The atmosphere will release carbon dioxide required by the plants only when the plants release oxygen and hydrogen.
Plants absorb water through capillary action from the soil through their roots via the xylem. When the water reaches the surface of the leaf, it is evaporated and is lost in the form of oxygen and hydrogen. The properties of water make them simple and easy for the plants to absorb it.
Want to see more full solutions like this?
Chapter 9 Solutions
CONCT ACCESS CODE W/EBOOK
- examples of synamptomorphyarrow_forwardexamples of synamtomorphy.arrow_forwardE. Bar Graph Use the same technique to upload the completed image. We will use a different type of graph to derive additional information from the CO2 data (Fig A1.6.2) 1. Calculate the average rate of increase in COz concentration per year for the time intervals 1959-1969, 1969- 1979, etc. and write the results in the spaces provided. The value for 1959-1969 is provided for you as an example. 2. Plot the results as a bar graph. The 1959-1969 is plotted for you. 3. Choose the graph that looks the most like yours A) E BAR GRAPH We will use a different type of graph to derive additional information from the CU, data (rig. nive). Average Yearly Rate of Observatory, Hawall interval Rate of increase per year 1959-1969 0.9 1969-1979 1979-1989 1989-1999 1999-2009 Figure A1.6.2 1999-2009 *- mrame -11- -n4 P2 جية 1989-1999 1979-1989 1969-1979 1959-1969 This bar drawn for you as an example 1.0 CO, Average Increase/Year (ppmv) B) E BAR GRAPH We will use a different type of graph to derive…arrow_forward
- Use the relationships you just described to compute the values needed to fill in the blanks in the table in Fig A1.4.1 depth (a) 1.0 cml 0.7 cml cm| base dimensions (b, c)| 1.0 cm| 1.0 cm| 1.0 cm 1.0 cm| 1.0 cm| 1.0 cm volume (V) 1.0_cm' cm'| cm'| density (p) 1.0 g/cm'| 1.0 g/cm 1.0 g/cm' mass (m)| 0.3 g Column 1: depth at 1.0 cm volume mass Column 2: depth at 0.7 cm volume mass Column 3: unknown depth depth volumearrow_forwardSan Andreas Transform Boundary Plate Motion The geologic map below of southern California shows the position of the famous San Andreas Fault, a transform plate boundary between the North American Plate (east side) and the Pacific Plate (west side). The relative motion between the plates is indicated by the half arrows along the transform plate boundary (i.e., the Pacific Plate is moving to the northwest relative to the North American Plate). Note the two bodies of Oligocene volcanic rocks (labeled Ov) on the map in the previous page located along either side of the San Andreas Fault. These rocks are about 23.5 million years old and were once one body of rock. They have been separated by displacement along the fault. 21. Based on the offset of these volcanic rocks, what is the average annual rate of relative plate motion in cm/yr? SAF lab 2.jpg Group of answer choices 0.67 cm/yr 2 cm/yr 6.7 cm/yr 1.5 cm/yr CALIFORNIA Berkeley San Francisco K Os Q San Andreas Fault Ov…arrow_forwardThese are NOT part of any graded assignment. Are there other examples of synapomorphy. What is it called when the traits retained are similar to ancestors?arrow_forward
- Please hand draw everying. Thank you! Draw a gram positive bacterial cell below. Your cell should have the following parts, labeled: A coccus shape A capsule The gram positive cell wall should have the peptidoglycan labeled, as well as its component parts (NAM, NAG, and teichoic acid) A cell membrane Fimbriae A nucleoid Ribosomes Inclusionsarrow_forwardDraw a gram negative bacterial cell below. Your cell should have the following parts, labeled: A bacillus shape Fimbriae Amphitrichous flagella 2 membranes (outer and inner) The outer membrane should have lipopolysaccharide (LPS) with lipid A and O antigens Periplasmic space The thin peptidoglycan cell wall between the 2 membranes A nucleoid Ribosomes Inclusionsarrow_forwardBacterial species Cell wall type Example: S. mitis Gram positive S. epidermidis H. pylori M. bovis S. marcescens Shape and arrangement Coccus, streptococcus Drawing 0000000arrow_forward
- Draw a gram positive bacterial cell below. Your cell should have the following parts, labeled: A coccus shape A capsule The gram positive cell wall should have the peptidoglycan labeled, as well as its component parts (NAM, NAG, and teichoic acid) A cell membrane Fimbriae A nucleoid Ribosomes Inclusionsarrow_forwardwhat rank is above kingdom? order, class, phylum or domainarrow_forwardin the hierarchy of taconomic categories, with kingdom at the top, what taxon is below classarrow_forward
Human Anatomy & Physiology (11th Edition)BiologyISBN:9780134580999Author:Elaine N. Marieb, Katja N. HoehnPublisher:PEARSON
Biology 2eBiologyISBN:9781947172517Author:Matthew Douglas, Jung Choi, Mary Ann ClarkPublisher:OpenStax
Anatomy & PhysiologyBiologyISBN:9781259398629Author:McKinley, Michael P., O'loughlin, Valerie Dean, Bidle, Theresa StouterPublisher:Mcgraw Hill Education,
Molecular Biology of the Cell (Sixth Edition)BiologyISBN:9780815344322Author:Bruce Alberts, Alexander D. Johnson, Julian Lewis, David Morgan, Martin Raff, Keith Roberts, Peter WalterPublisher:W. W. Norton & Company
Laboratory Manual For Human Anatomy & PhysiologyBiologyISBN:9781260159363Author:Martin, Terry R., Prentice-craver, CynthiaPublisher:McGraw-Hill Publishing Co.
Inquiry Into Life (16th Edition)BiologyISBN:9781260231700Author:Sylvia S. Mader, Michael WindelspechtPublisher:McGraw Hill Education