The change in enthalpy between products and reactants in a reaction
Delta G (written triangle G) = Delta H -T Delta S
Use the following equation: delta G = delta H - T*deltaS. A reaction is spontaneous if delta G is negative. A reaction will always be spontaneous (under any temperature) only if the change in enthalpy (delta H) is negative and the change in entropy (delta S) is positive. If this is not the case, the reaction will only be spontaneous (negative delta G) for a range of temperatures (or could be always non-spontaneous)
Well the equation is: 6CO2 + 6H2O + -s-u-n-l-i-g-h-t--> C6H12O6 + 6O2.
∆G = ∆H - T∆S and for it to be spontaneous, ∆G should be negative. If both ∆H and ∆S are positive, in order to get a negative ∆H, the temperature needs to be elevated in order to make the ∆S term greater than the ∆H term. So, I guess the answer would be "the higher the temperature, the more likely will be the spontaneity of the reaction."
The time between one noon and the next at the same place on the planet is 24 hours.
The change in enthalpy between products and reactants in a reaction
Delta G (written triangle G) = Delta H -T Delta S
Delta G (written triangle G) = Delta H -T Delta S
Delta G (written triangle G) = Delta H -T Delta S
The change in enthalpy between products and reactants in a reaction
The equation for ∆G is ∆G = ∆H - T∆S H is enthalpy and S is entropySo, ∆G is negative if T∆S is greater than ∆H
The equation for ∆G is ∆G = ∆H - T∆S H is enthalpy and S is entropySo, ∆G is negative if T∆S is greater than ∆H
h(t)= -g*t^2 + V*t +h where h(t) is the periodic time, t is the overall time, V is the initial velocity, h is the initial hieght, and g is the gravitational constant either 16 or 4.9. This equation will trace the path taken by a projected object.
Use the following equation: delta G = delta H - T*deltaS. A reaction is spontaneous if delta G is negative. A reaction will always be spontaneous (under any temperature) only if the change in enthalpy (delta H) is negative and the change in entropy (delta S) is positive. If this is not the case, the reaction will only be spontaneous (negative delta G) for a range of temperatures (or could be always non-spontaneous)
The change in entropy between products and reactants in a reaction.
The change in entropy between products and reactants in a reaction.
The change in entropy between products and reactants in a reaction.