Jason Rodgers
Mr. Camp
Biology
9 December, 2016
How does Photosynthesis model the Laws of Conservation and Conservation of Energy ?
Photosynthesis model the Laws of Conservation and Conservation of Energy because seeing a car moving one day and seeing it sitting in a driveway parked these are both examples of laws of energy and motion The law of Conservation of Energy and Matter. The Law of Conservation States that “Energy can neither be created or destroyed” It only changes form If a car is moving and hits a parked it it gives the parked car energy to move on it’s on and that's how it gets kind of confusing because matter isnt created or destroyed but while hitting the car it changed because it was parked now it changed form because it moved
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Law of Energy states that energy can neither be created or destroyed and amount of energy isolated systems stays constant energy is a law of science that can only change from one object another example is “ When a car hits a non-moving car it transfer energy to the non-moving car which allows it to move on it’s on.”
Law of Matter means “ The principle that in any closed system subjected to no external forces the mass is constant irrespective of its changes in form.”(Google.com) In Accordance to the law of conservation of matter, matter is not either created or destroyed so you'll need the same amount of atoms after the change. Anything that has mass or matter can not be destroyed or created and that’s that! A cigarette that is burning turns to ash as it is being smoked because of the puffs that is being taken from it the smoke from the cigarette is floating in the air.
In conclusion of this paper you know now about the Law of Conservation, Energy and Photosynthesis of science these are what will happen during the observations and examining the causes and effects of them now you also know you can not create or destroy energy but energy and matter can be moved from one spot to another with the help of something else like YOU! You can move matter with your energy it, you have energy and there matter happening around you somewhere right
The experiment done in the lab supports the law of Conservation of Mass because we used the reactants and simply rearranged them to create the products without adding or removing anything. For the experiment we used candy and marshmallows. The green candy symbolized carbon atoms, the red ones hydrogen atoms, and the marshmallows represented oxygen atoms; we also used toothpicks which illustrated bonds keeping them all together. The chemical reaction for photosynthesis is the product of six carbon dioxide plus six water atoms is glucose (sugar) plus oxygen. We started by making the food into the reactants, the ingredients for the chemical reaction; six green candy drops and twelve marshmallows plus twelve red candy drops and six marshmallows.
Einstein's equation "E=mc^2" has two sides which is constructive and destructive. The constructive side is when energy is converted into mass and the destructive side is when a small amount of mass is converted into energy. According to Einstein’s equation, the physicists of the Manhattan project hypothesized that a minute mass ...
In this experiment, we are finding the Conservation of Energy. Energy is neither created nor destroyed. Energy is summed up into two different properties: Potential energy and Kinetic energy. The law of Energy states that:
Photosynthesis consists of the following equation: Sun light Carbon dioxide + Water = = == == ==> Glucose + Oxygen Chlorophyll Chlorophyll is a substance found in chloroplasts, found in the cells of leaves.
Energy can never be created or destroyed. Energy may be transformed from one form to another, but the total energy of an isolated system is always constant.
Experiment #1: The purpose of this experiment is to investigate the effects of baking soda and light intensity on the rate of photosynthesis of green spinach leave through the observation of floating disk.
An Analysis and Evaluation of Data from Photosynthesis Experiments Graph analysis This is my analysis for the investigation in to the affect of light intensity on the rate of photosynthesis to the Canadian pondweed, elodea. In the results the pattern is that when the light intensity is higher the readings are generally higher. On the graph the less the light intensity the lower the gradient of the curve. the equation for the photosynthesis process is; CO2 + 2H2O + Light Energy = =
= = = [IMAGE][IMAGE]6CO2 + 6h20 light energy and chlorophyll C6H1206 + 6O2 Carbon dioxide + water converted into glucose and oxygen. Theory of photosynthesis Photosynthesis is a chemical reaction, which uses the energy from sunlight to convert carbon dioxide and water to oxygen.
To make the test fair I will use the same amount of water and the leaf
Photosynthesis in simpler turns is the ability of a live plant to carry on its chemical process by the use of light energy. Photosynthesis can not take place when there is absolutely no light, instead it stores the light it captures during the day, and uses it when needed. Photosynthesis can take place in land plants and aquarian plants such as algae. There are many factors that influence the ability of a plant to go through photosynthesis, such as light, the color of light and amount of water and or light.
An Experiment to Investigate the Effect of Light Intensity on the Rate of Photosynthesis. Introduction Photosynthetics take place in the chloroplasts of green plant cells. It can produce simple sugars using carbon dioxide and water causing the release of sugar and oxygen. The chemical equation of photosynthesis is: [ IMAGE ] 6CO 2 + 6H20 C 6 H12 O 6 + 6O2 It has been proven many times that plants need light to be able to photosynthesize, so you can say that without light the plant would neither photosynthesize nor survive.
Mass-Energy Equivalence is the concept that the mass of an object or system is the measurement of its energy content. “E=mc2 is a sequence of special relativity”. Although the Algebra in the equation is very basic, it demonstrates an inherent fundamental difficulty for direct experimental verification, This formula is one of the most popular and important in the world of physics, according to (Dr. Michael Jentschel). E=mc2 basically explains that energy and mass are interchangeable, they are the same thing in different forms , This equation helps us understand the most basic natural process of the universe. Einstein's equation also perfectly describes what's happening when we produce nuclear energy. As Arlin Crotts, a professor of astronomy at Columbia University, puts it, "our entire understanding of nuclear processes would be sort of lost without it." We live in a nuclear world! This equation sprawled a whole other branch of science, literally, being “High energy particle physics”. Proper use of particle accelerators, as well as the analysing of high-speed collisions within them, this wouldn't be possible without a thorough comprehension of mass-energy equivalence, which is what Einstein discovered with his theory of specia...
Photosynthesis is a process in which plants and other organisms convert the light energy from the sun or any other source into chemical energy that can be released to fuel an organism’s activities. During this reaction, carbon dioxide and water are converted into glucose and oxygen. This process takes place in leaf cells which contain chloroplasts and the reaction requires light energy from the sun, which is absorbed by a green substance called chlorophyll. The plants absorb the water through their roots from the earth and carbon dioxide through their leaves.
Photosynthesis is a wonderful process that takes place in nature for examples in plants bacteria and algae. Where it capture the energy from the sun and convert (carbon dioxide and water) to chemical energy and storing it in the bond of sugar (fruits). The process of the photosynthesis takes place in the chloroplasts, specifically using chlorophyll (the green pigment. Human are familiar with the utilized the sun energy by using solar energy system ...
There are three laws of thermodynamics in which the changing system can be followed in order to return to equilibrium. In order for a system to gain energy, the surroundings have to supply it, and vice versa when the system loses energy, the surroundings must gain it. As the energy is transferred it can be converted from its original form to another as the transfer takes place, but the energy will never be created or destroyed. The first law of thermodynamics, also known as the law of conservation of energy, basically restates that energy can’t be destroyed or created “as follows: the total energy of the universe is a constant.” All around, the conservation of energy is applied.