Equations

Cards (14)

Integrated first order
A) Ln [A]
B) -kt
C) +
D) Ln[A]0
half life equation
A) ln 2
B) k
integrated second order
A) 1
B) [A]
C) kt
D) +
E) 1
F) [A]0
Maxwell-Boltzmann distribution: The probability of finding an electron in a given energy level.
A) number of molecules with energy >Ea
B) total number of molecules
C) activation energy
D) RT
Arrhenius equation
A) k
B) A
C) e
D) -Ea
E) /RT
How to work activation energy at different temperatures
A) ln
B) k1
C) k2
D) Ea
E) R
F) 1
G) T2
H) -
I) 1
J) T1
Average relative speed:
kb = R/Na (boltzmann constant)
A) 8
B) Kb
C) T
D) pi
E) reduced mass
Collision theory
A) Number of collision between A and B
B) collision area
C) x
D) average relative speed
E) x
F) Na
G) 2
H) x
I) [A][B]
Mode of vibration:
A) boltzmann constant
B) T
C) planck constant
rate constant:
derivative of Gibbs (K = e^-deltaG/RT) and (deltaG = G(trans) - G (reactants))
A) frequence of mode of vibration
B) -Change in transition enthalpy
C) RT
D) Change in transition entropy
E) R
Eyring equations
A) ln
B) k
C) T
D) -
E) delta H (trans)
F) RT
G) +
H) ln
I) Kb
J) h
K) +
L) delta S
M) R
michaelis-menten equation
A) rate of conversion from ES to P
B) [E]0
C) [S]
D) Km
E) +
F) [S]
michaelis-menten using Vmax
A) Vmax
B) 1
C) +
D) Km
E) [S]
Lineweaver -Burk plot (y=mx+c)
A) V
B) Vmax
C) +
D) Km
E) Vmax
F) 1
G) [S]0