with enzyme.
Cellular respiration need glucose.This glucose is produced in photosynthesis
Both aerobic respiration and photosynthesis involve the exchange of gases (oxygen and carbon dioxide). Both processes require the use of electron transport chains to generate ATP. Additionally, both processes involve the creation and utilization of a proton gradient across a membrane to generate energy.
They can be thought of as the 'reverse' of each other (though their repective biochemical pathways are in no ways similar) and are the two halves of the carbon cycle. Respiration: Glucose + Oxygen -> Carbon dioxide + Water Photosynthesis: Carbon dioxide + Water -> Glucose +Oxygen
The process of (aerobic) cellular respiration combines a carbohydrate with oxygen to release energy. This oxidation reaction is the "reverse" of photosynthesis.
Both aerobic respiration and anaerobic respiration are processes that cells use to generate energy from food molecules.
Oxygen is the atmospheric gas that is produced as a by-product of the light reaction of photosynthesis and is essential for aerobic respiration in organisms. Oxygen is used in cellular respiration to break down glucose and produce ATP, providing energy for various cellular functions.
Photosynthesis and aerobic respiration are interconnected processes in the ecosystem. In photosynthesis, plants convert sunlight, carbon dioxide, and water into glucose and oxygen, providing energy-rich compounds and oxygen as byproducts. Aerobic respiration, on the other hand, uses glucose and oxygen to produce energy, carbon dioxide, and water. The oxygen produced during photosynthesis is essential for aerobic respiration, while the carbon dioxide generated through respiration is utilized in photosynthesis, creating a cyclical relationship between the two processes.
It invoves in respiration. Specifically it is aerobic respiration
Both aerobic respiration and photosynthesis involve the exchange of gases (oxygen and carbon dioxide). Both processes require the use of electron transport chains to generate ATP. Additionally, both processes involve the creation and utilization of a proton gradient across a membrane to generate energy.
aerobic resperation
Chloroplasts are the site of photosynthesis. Mitochondria are the site of aerobic cellular respiration.
Aerobic Respiration: Respiration that requires oxygen Anaerobic Respiration: respiration that does not use oxygen aerobic respiration is continuous. anaerobic respiration has no new subsrates from photosynthesis to continue. it is usually shorter and not as efficient.
Aerobic respiration:C6H12O6 + 6O2 --> 6CO2 + 6H2Oglucose + oxygen produce carbon dioxide and waterPhotosynthesis:6CO2 + 6H2O --> C6H12O6 + 6O2carbon dioxide and water produce glucose and oxygenThe reactants of aerobic respiration are the products of photosynthesis. Organisms that undergo aerobic respiration need the products of photosynthesis to survive (this includes the plants and other photosynthesizing organisms themselves). Plants and other photosynthesizing organisms need the products of aerobic respiration in order to survive.
Aerobic respiration is the opposite of photosynthesis because in respiration, organisms break down glucose and oxygen to produce carbon dioxide, water, and energy, while in photosynthesis, plants use carbon dioxide, water, and sunlight to produce glucose and oxygen. The processes have opposite inputs and outputs, with respiration releasing energy and photosynthesis storing energy.
how are photosynthesis and celland cellular respiration similar
They can be thought of as the 'reverse' of each other (though their repective biochemical pathways are in no ways similar) and are the two halves of the carbon cycle. Respiration: Glucose + Oxygen -> Carbon dioxide + Water Photosynthesis: Carbon dioxide + Water -> Glucose +Oxygen
The process of (aerobic) cellular respiration combines a carbohydrate with oxygen to release energy. This oxidation reaction is the "reverse" of photosynthesis.
Both aerobic respiration and anaerobic respiration are processes that cells use to generate energy from food molecules.