Water Transport in the Xylem (AQA AS Biology): Revision Note

Exam code: 7401

Written by: Lára Marie McIvor

Reviewed by: Naomi Holyoak

Updated on 28 May 2025

Water transport in plants

Plants need a constant supply of water and minerals
- Water is required for photosynthesis and to maintain cell structure
- Minerals are needed for production of important biological molecules, e.g. proteins and chlorophyll

Xylem tissue

Water and dissolved minerals are transported from the soil to the rest of a plant in the xylem
- Xylem are tubes that form part of the mass transport system of plants
- Xylem cells are specialised for water transport
  - Hollow tubes with no end walls allow the continuous flow of water
  - Lignin provides waterproofing to prevent loss of water by evaporation
  - Lignin strengthens the xylem to reduce breakages
Xylem cells together form xylem tissue which, together with phloem tissue, makes up plant vascular tissue

Diagram of a xylem vessel with labels: no cell contents, original cell walls broken down, and walls thickened with lignin. — **Xylem are specialised cells that transport water and dissolved minerals from the roots to the leaves in vascular plants**

Movement of water in the xylem

The upward movement of water in the xylem is driven by the process of transpiration
- Transpiration is the loss of water from the leaves of plants by evaporation
Transpiration drives water transport as follows:
1. water diffuses out of leaves into the surrounding air via the stomata
2. the loss of water vapour lowers the water potential in the air spaces surrounding the mesophyll cells
3. water within the mesophyll cell walls evaporates into the leaf air spaces, lowering the water potential of the mesophyll cells
4. water is drawn from the xylem into the mesophyll cells by osmosis
5. water moves up the xylem vessels in a continuous column to replace this lost water; this upward movement is the transpiration stream
  - Water molecules are pulled upwards due to forces of cohesion and adhesion
The upward pulling force acting on water in the xylem can be so great that the water is under tension, exerting an inward pull on the walls of the xylem vessels; this is known as cohesion tension
- The mechanism of water movement described above is sometimes known as the cohesion-tension theory of water transport

Diagram showing the upward movement of water in a tree, with details on leaf transpiration, xylem cohesion, and root water intake, labelled with water potential values. — **Water is drawn upward due to cohesion between water molecules and adhesion between water and the sides of the xylem; this upward movement can create tension within the xylem vessels**

Examiner Tips and Tricks

Be careful not to confuse transpiration with the movement of water in the stem:

Transpiration: water loss from leaves by evaporation
Transpiration stream: upward movement of water in the xylem

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Water Transport in the Xylem (AQA AS Biology): Revision Note

Water transport in plants

Xylem tissue

Movement of water in the xylem

You've read 0 of your 5 free revision notes this week

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Biological Molecules: Carbohydrates

Biological Molecules: Key Terms

Biological Molecules: Reactions

Monosaccharides

Glucose

The Glycosidic Bond

Chromatography: Monosaccharides

Disaccharides

Starch & Glycogen

Cellulose

Biochemical Tests: Sugars & Starch

Finding the Concentration of Glucose

Biological Molecules: Lipids

Lipids

Triglyceride Function

Phospholipids

Biochemical Tests: Lipids

Lipid Diagrams & Properties

Biological Molecules: Proteins

Amino Acids & the Peptide Bond

Chromatography: Amino Acids

Protein Structure & Function

Protein Interactions

Biochemical Tests: Proteins

Globular & Fibrous Proteins

The Molecular Structure of Haemoglobin

The Molecular Structure of Collagen

Proteins: Enzymes

Many Proteins are Enzymes

Enzyme Specificity

How Enzymes Work

Required Practical: Measuring Enzyme Activity

Maths Skill: Drawing a Graph for Enzyme Rate Experiments

Maths Skill: Using a Tangent to Find Initial Rate of Reaction

Limiting Factors Affecting Enzymes: Temperature

Limiting Factors Affecting Enzymes: pH

Maths Skill: Calculating pH

Limiting Factors Affecting Enzymes: Enzyme Concentration

Limiting Factors Affecting Enzymes: Substrate Concentration

Limiting Factors Affecting Enzymes: Inhibitors

Models & Functions of Enzyme Action

Practical Skill: Controlling Variables & Calculating Uncertainty

Nucleic Acids: Structure & DNA Replication

The Function of DNA & RNA

Nucleotide Structure & the Phosphodiester Bond

The Structure of DNA

The Structure of RNA

Ribosomes

The Origins of Research on the Genetic Code

Semi-Conservative Replication

The Process of Semi-Conservative Replication

Calculating the Frequency of Nucleotide Bases

The Watson Crick Model

ATP, Water & Inorganic Ions

The Structure of ATP

Hydrolysis & Synthesis of ATP

The Properties of Water

Inorganic Ions

Cell Structure

Cell Structure

The Cell Theory

Structure of Eukaryotic Cells

Specialisation of Eukaryotic Cells

Eukaryotic Cell Organisation

Structure of Prokaryotic Cells

Prokaryotic v Eukaryotic Cells

Viruses

The Microscope in Cell Studies

Methods of studying cells

Microscopy & Drawing Scientific Diagrams

Iodine Detects Starch Grains

Resolution & Magnification