The purpose of the project was to determine whether Eucalyptus globulus had an effect on the germination of radish seeds. It was hypothesized that Eucalyptus globulus would have a negative effect on the germination of the seeds and their growth.
Before a seed can germinate it must first shed the seed coat, a protective outer layer that protects the seed from parasites, injury, and unfavorable temperatures. Inside the seed coat is the embryo which contains the root and first leaves of the plant, called cotyledons. After the seed coat has been shed the root emerges first so that it can absorb water and nutrients. After the roots have come out of the embryo the cotyledons will follow. Some seeds need certain conditions to germinate and go
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Allelopathic chemicals can also exist in soil, affecting the surround plants and those planted afterwards. Studies have shown that Leucaena leucocephala, a tree promoted for water conservation and revegetation, contains a toxic amino acid in its leaves and foliage that prevents the growth of other trees but not its own seedlings. Research has also shown that this species reduces the yield of wheat and increases the yield of rice. Other allelopathic plants include mango, box elder, broccoli, and Eucalyptus. A study was conducted at Gomal University that tested the allelopathic effects of Eucalyptus camaldulensis L. on the germination and seedling growth of wheat. The leaves of E. camaldulensis trees were washed and dried and then filtered to create a one hundred percent solution as well as ten percent, fifteen percent, and twenty percent. These solutions were tested on twelve varieties of wheat. The results showed that there was a significant decrease in germination counts with increasing levels of Eucalyptus aqueous extract concentration. All twelve varieties of wheat were adversely affected by the twenty percent concentration of Eucalyptus extract. It was observed that there was a direct relationship between the number of normal seedlings and the extract concentration. The results suggested that the E. camaldulensis L. leaf aqueous extract could reduce normal seedlings even in low concentrations.
Eucalyptus
This experiment is designed to test the allelopathy of two different treatments, Eucalyptus (Eucalyptus cinerea) and Lemon (Citrus limon). The two treatments will be tested on radish seeds (Raphanus sativus) to investigate the effect of the treatments on the germination of the radish seeds. Allelopathy is the beneficial or harmful effects that one plant has on another plant by the release of chemicals. Allelopathy studies the interactions among plants, fungi, algae and bacteria with the organisms living in a certain ecosystem, interactions that are mediated by the secondary metabolites produced and exuded into the environment (Francisco A Macías, José MG Molinillo, Rosa M Varela, Juan CG Galindo 2007). The plants use
Germination is the stage of plant growth through which a seed becomes a seedling plant. First, the seed begins to absorb water and the radicle root emerges from the seed coat and into the water. Then, the primary roots grow, the cotyledons move above ground, the stem begins to grow, and leaves develop. The process is complete when the first leaves open and the cotyledons fall off (The Learning Garden 2001).
When planting a seed, many factors allow the seed to grow and become a plant. To sprout from the ground, and to survive, seeds need water, air, and a certain temperature. Seeds can get water, oxygen, and sun by being placed at the proper planting depth. Planting depth is the depth at which a seed is placed in the soil. If a seed is exposed to these important needs, it goes through a process called germination. According to the Wise Geek article, “What is Germination?”, “Germination is a process in which a seed or spore awakens from dormancy and starts to sprout.” (“What is Germination?”).
The results observed do not correspond with the outcome predicted by the hypothesis. Despite the nature of the subjects of the experiments, no substantial growth was observed. Only one seed of the 36 planted germinated, and it could only survive for a period of a week. The one seed that germinated reach a height of 1.2 cm. Table 1 presents the average growth observed in each quad. Each quad had a total of 12 seeds. No seeds were removed during the course of the experiment.
Firstly, for the setup of the experiment, two styrofoam cups were filled with two inches worth of standard, fertilized garden soil, next four seeds from from the garden seed, and the bird seed were placed an inch deep in separate cups. The seeds were blindly labeled, with one being labeled group A and one being labeled group B. This was so as to efficiently conduct a double blind experiment. The seeds were watered with approximately a teaspoon of water per day, and kept in a sunny windowsill. They were left in the windowsill for two weeks, and watered daily.
This then not only prevents the germination of the seed; however, if the plant were to initially germinate, it would be unable to grow any further, as without enough water, photosynthesis, nutrient transfer, or transpiration would be unable to occur; therefore, the plant would be unable to sustain (Growing Anything,
Therefore, I was correct in my hypothesis that dark will have an effect on the germination of radish seeds. Also, I was very close in predicting that the seeds grown in the light will germinate twice as much as the seeds grown in the dark; the control seeds grew a little less than double the size of the experimental seeds. Ultimately, my experiment proved that light is a very important factor in the growth of any plant. However, I’ve learned that seeds grown in the dark will germinate, though slowly, as
also damage the plants and prove to be a detriment to its lifetime. Plus, plants
This experiment was performed to give a better idea of interspecific competition and intraspecific competition between radish seeds and wheat seeds at high and low densities. By planting two species only pots and two combined species pots our results showed that the radish seeds performed better at both interspecific and intraspecific competitions and concluded that the lower the pot density the more resources and growth. 32 radish seeds were evenly planted in pot A1 followed by 32 wheat seeds planted in pot A2 and 16 of each radish and wheat seeds combined (32 total) planted in pot AB1. We repeated this procedure again but this time planting 96 radish seeds evenly in pot A2, 96 wheat seeds in pot B2 and 48 of each radish and wheat seeds combined (96
Materials and Methods: The following procedure has been derived from the Plant Defenses Lab used by Blanar in 2018, and modified with the deviation of the tested plant defensive compounds of coffee and kava to green tea and black tea. In addition, a few of the steps were adjusted in order to fit within the parameters of the experiment. A plastic pipette was used to collect nine Daphnia magna specimens from the larger container of Daphnia magna.
The second step of the experiment was to soak the seeds in water overnight. This action was made to prepare the seeds for germination and making them more softer and less rigid. The seeds were placed in a bowl and were covered by tin foil. It was set up on the refrigerator to minimize any outside interference that may come to it. After a full night of absorbing the water, the seeds were ready to start the next stage.
In the article “Seed” William DiMichele discusses the development of seeds. A seed is a part of a plant, that is capable of creating another plant. Inside a plant's ovules, seeds are created. A seed can either be categorized by enclosed or naked, this is based on whether or not they are based on angiosperms or gymnosperms. Inside a seed, the embryo is where the plant grows, the food storage system provides nutrients, and the seed coat protects the internals of the seed. Seeds are created through sexual reproduction, through plant spores acting as reproduction cells. The movement of a seed can be influenced by many outside forces such as wind, water, animals, or people. After seeds
Germination had first appeared in the sample watered with the solution containing no sucrose. The seed coats had split and seedling had emerged.
ABSTRACT — In the present investigation, it was revealed that treatment with paclobutrazol (PBZ) @ 2.5, 5.0, 10 and 20 µg mL–1 resulted in shoot length and shoot dry weight to decrease significantly under normal condition, but increased significantly in salinity (4 dSm-1 and 8 dSm-1) with respect to control. Treatment with PBZ resulted in significant increase in root length and root dry weight as compared to control under both normal (PBZ) and saline conditions. Total chlorophyll was recorded to increase significantly at vegetative and flowering stages as compared to control. Hydrogen peroxide decreased significantly at vegetative and flowering stages. Treatment with PBZ resulted in significant increase in protein and total sugar content at
Purpose: To see the effect of an acid introduced during seed germination, on the length of the plant roots. Also shows how salt can affect the seed germination. Acid can be introduced to seeds during germination if there is acid rain. Knowing the results of acid rain on seed germination will help us understand how to grow pants better, and how to have more successful germination. Salt can be introduced into a seed during germination because salt is put on roads and the salt builds up and can contaminate the soil. Knowing the effects of salt on seed germination will allow us to know for sure if the salt is affecting the plants growth or not.