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Xylem is a specialised vascular tissue structure that, in addition to transporting water and inorganic ions, will also provide mechanical support to the plant. Together with the phloem, the xylem forms a vascular bundle.
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Jetzt kostenlos anmeldenXylem is a specialised vascular tissue structure that, in addition to transporting water and inorganic ions, will also provide mechanical support to the plant. Together with the phloem, the xylem forms a vascular bundle.
To learn about the differences between xylem and phloem, take a look at our article "Phloem".
Let's start by looking at the function of xylem cells.
Plant xylem delivers water and nutrients from the plant-soil interface to stems and leaves, and provides mechanical support and storage as well. The xylem transports water and inorganic ions in a unidirectional flow from the roots (sink) to the leaves (source) in a process known as transpiration.
A source is the plant region where food is made, such as leaves.
A sink is where food is stored or used, such as the root.
To understand this process, we first need to learn what properties of water allow this to occur.
Water has three properties that are essential for maintaining the transpiration stream up the plant. These properties are adhesion, cohesion and surface tension.
Adhesion refers to the attraction between two different substances. In this case, the water molecules are attracted to the walls of the xylem. Water molecules will cling to the xylem walls because xylem walls are charged.
The water molecules move via capillary action. This creates greater tension within the xylem walls, allowing for efficient water movement.
Capillary action describes the movement of liquids up a hollow space due to cohesion, adhesion and surface tension.
Cohesion refers to a molecule’s ability to stick together with other molecules of the same kind. The cohesive forces in water are created through hydrogen bonds. Hydrogen bonds form between water molecules because water is polar (it has an imbalanced charge distribution).
Polar molecules come about due to the unequal sharing of electrons. In water, the oxygen atom is slightly negative, and the hydrogen atom is somewhat positive.
In addition to cohesion and adhesion, the surface tension of the xylem sap (water with dissolved minerals) is also significant. A substance having surface tension means that it will tend to occupy the least space possible; cohesion allows this to happen, as it lets molecules of the same substance stay close together.
The surface tension of the xylem sap is created by the transpiration stream, which moves the water up the xylem. The water is pulled towards the stomata, where it will evaporate.
Xylem cells are adapted to their function. By losing their end walls, the xylem forms a continuous, hollow tube, strengthened by a substance called lignin.
The xylem contains four types of cells:
Tracheids and xylem vessel elements will conduct the transport of water and minerals. Xylem possesses several adaptations that allow for efficient water transport:
Mass flow describes the movement of fluid down a pressure gradient.
Lignin is the primary supportive element of the xylem tissue. The main two features are:
Pits in the xylem walls are a feature of secondary growth. They are not perforations!
There are differences in the distribution of the vascular bundles in monocotyledonous (monocot) and dicotyledonous (dicot) plants. In short, the vascular bundles containing xylem and phloem are scattered in monocots and are arranged in a ring-like structure in dicots.
First, let’s cover the main differences between monocots and dicots.
There are five main features that are different between monocots and dicots:
The isobilateral symmetry of leaves describes how opposite leaf sides are the same.
In the stems of monocots, the vascular bundles are scattered throughout the ground tissue (all tissue that is not vascular or dermal). The xylem is found on the inner surface in the bundle, and the phloem is on the outer. Cambium (an actively dividing layer of cells that promotes growth) is not present.
Cambium is a layer of unspecialised cells actively dividing for plant growth.
In the stems of dicots, the vascular bundles are arranged in a ring-like structure around a cambium. Xylem is present in the cambium ring’s inner part, and phloem is present at the exterior. Sclerenchyma tissue comprises thin and narrow non-living cells (when mature). Sclerenchyma tissue does not have any internal space, but it plays an essential role in plant support.
Monocots have a fibrous root, and dicots have a tap root.
When you look at the cross-section of the root, in general, a single ring of xylem will be present in monocots. Xylem is surrounded by phloem, which is different from their monocot stems. The monocot root has more vascular bundles than the dicot root.
In the dicot root, the xylem is in the middle (in an x-shaped manner), and the phloem is present in clusters around it. Cambium separates xylem and phloem from each other.
Water and dissolved inorganic ions.
Xylem is a specialised vascular tissue structure that, in addition to transporting water and inorganic ions, will also provide mechanical support to the plant.
To transport water and inorganic ions and provide mechanical support to the plant.
Examples of the adaptations:
A substance called lignin strengthens the walls of xylem cells, allowing the xylem to withstand water pressure changes as water moves through the plant.
Function of xylem: Plant xylem delivers water and nutrients from the plant-soil interface to stems and leaves, and provides mechanical support and storage as well. One of the major characteristics of vascular plants is their water-conducting xylem.
One of the major characteristics of vascular plants is their water-conducting xylem. An internal hydrophobic surface is provided by the water-conducting xylem cells, which facilitates the transport of water as well as providing mechanical resistance. Additionally, the xylem cells support the weight of the water transported upward within the plant as well as the weight of the plant itself.
Xylem cells are adapted to their function. By losing their end walls, the xylem forms a continuous, hollow tube, strengthened by a substance called lignin.
Xylem cells are adapted to their function.
1. Xylem cells lose their end walls, forming a continuous, hollow tube.
2. The xylem is strengthened by a substance called lignin, providing support and strength to the plant.
Plants have two transport systems. Xylem transports water and inorganic ions. What is the name of the other system and what does it transport?
Phloem. It transports amino acids and sugars.
Xylem and phloem transport substances in a bi-directional flow. True or False?
Partially true. Xylem transports water in one direction and phloem transports materials bi-directionally.
What are the two main properties of water molecules that help the mass flow of water?
Adhesion and cohesion.
How does cohesion occur between the water molecules?
The cohesive forces between water molecules occur due to hydrogen bonds. Water molecules are charged due to an unequal sharing of electrons. This allows for hydrogen bonds between water molecules.
Fill in the blanks about adhesion.
Adhesion is the _________ between the two __________ substances. In xylem, water molecules are _______ to the ________ of xylem. Water molecules are charged and xylem ________ are too. Water will move via ________ action up the plant.
Adhesion is the attraction between the two different substances. In xylem, water molecules are attracted to the walls of xylem. Water molecules are charged and xylem walls are too. Water will move via capillary action up the plant.
What will create surface tension in xylem’s sap?
Transpiration stream.
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