By extrapolating the differential equation, adjacent to the the hypotenuse of the slope, when your results are plotted on the graph. Mathematically it can be worked out using the -b/2a formulae to extrapolate the vertex on the curve which can then beused to calculate the maximum value. This should in the end help to calculate the rate of photosynthesis in the hill reaction. Hope this was helpfull. By extrapolating the differential equation, adjacent to the the hypotenuse of the slope, when your results are plotted on the graph. Mathematically it can be worked out using the -b/2a formulae to extrapolate the vertex on the curve which can then beused to calculate the maximum value. This should in the end help to calculate the rate of photosynthesis in the hill reaction. Hope this was helpfull.
You will calculate the initial rate of reaction from a curve rather than measure how much gas is released because you are looking at products in there molecular nature.
It increases the rate of photosynthesis or vice versa...
Temperature being a limiting factor for biochemical reaction also regulate the rate of photosynthesis in plants. Thus lower and higher temperature, beyond the optimum limit, reduce the rate of photosynthesis and hence production of oxygen is also affected.
This means the rate in which a plant is able to absorb light through its chlorophyll while in the presence of Carbon dioxide and water in order to produce Oxygen and Glucose.
what type of scientists is interested in the rate of photosynthesis in leaves
Enzyme reaction rate increse with temperature. So photosynthetic rate increases
Intensity (W/m^2)= Watts / (4* pi* distance from bulb in meters^2) Intensity can then be compared to rate of photosynthesis at different distances.
The slowest of the elementary steps that make up a complex reaction is called the rate limiting step. Sometimes it is also called the rate determining step.
The rate of photosynthesis increases. Carbon dioxide is a reactant in photosynthesis; if the reactants are increased, the reaction goes faster.
yes but at a lower rate. Only dark reaction takes place. Light reaction takes place only at day
You will calculate the initial rate of reaction from a curve rather than measure how much gas is released because you are looking at products in there molecular nature.
to maintain the reaction so that we calculate the rate of reaction at that particular time.
No, that is not true and increasing light intensity increases the photosynthetic rate, to a point. The saturation point is reached when the reactions in the reaction center have reached top speed and any more light intensity will not increase the rate of photosynthesis.
The measure is the rate of reaction.
The formula is:r = k(T) · [A]n'· [B]m' where:- r is the rate of reaction- k is the rate constant- [A] and [B] are the concentrations of the reactants- n' and m' are the reaction orders- T is the temperature
It increases the rate of photosynthesis or vice versa...
The chemical term is reaction rate.