T = (LnK-LnA)/(-Ea/R) Try this... T = (Ea/R)/(LnK - LnA) T = (Ea/R)/(LnK - LnA)
Ballhawk it is a vocabulary word on the same page that you got this question from
the terms odorless ad colorless are quantitative terms
Euler's equation of motion in spherical polar coordinates describes the dynamics of a rigid body rotating about a fixed point. It includes terms for the inertial forces, Coriolis forces, and centrifugal forces acting on the body. The equation is a vector equation that relates the angular acceleration of the body to the external torques acting on it.
The Poiseuille equation is derived from the Navier-Stokes equation for incompressible fluid flow in a cylindrical pipe, assuming laminar flow and steady state conditions. By applying assumptions of no-slip boundary conditions and conservation of mass and momentum, the equation simplifies to describe the flow rate in terms of viscosity, pressure gradient, and geometry of the pipe.
the Equation of State is a thermodynamic equation describing the state of matter under a given set of physical conditions. It is a constitutive equation which provides a mathematical relationship between two or more state functions associated with the matter, such as its temperature, pressure, volume, or internal energy. there are two common types of this equations of state. the first one is Cubic E.O.S, which has a triple root for its solution and the second one is the Viral Equation of State which depends mainly on a long series of constants that depend on Tr and Pr and other materials properties.
Arrhenius theory explains the temperature dependence of reaction rates in terms of activation energy, while Van't Hoff equation relates the equilibrium constant of a reaction to temperature changes. Both concepts involve the role of temperature in affecting the behavior of chemical reactions, with Arrhenius theory focusing on reaction rates and activation energy, while Van't Hoff equation focuses on equilibrium constants.
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If ( y = x ), then to express ( x ) in terms of ( y ), you can simply rearrange the equation. This gives you ( x = y ). Thus, ( x ) is equal to ( y ).
Svante Arrhenius
As a 'Rule of Thumb'. thehigher the temperature, the faster the reaction. Hence the Rate Constant increases. Conversely for decrease in temperature. See the Arrhenius Equation. k = Ae^(-Ea/RT). Where k = Rate constant A = pre-exponential constant 'e' = the exponential number ( 2.7818...) '-Ea- - negative activation energy R = universal gas constant T = absolute temperature (Kelvin) The last three terms are raised to a power of 'e'.
To rearrange a formula to express ( x ) as a function of ( y ), you need to isolate ( x ) on one side of the equation. Start by performing algebraic operations such as addition, subtraction, multiplication, or division to both sides of the equation as necessary. Ensure that all terms involving ( x ) are on one side and all other terms are on the opposite side. Finally, if ( x ) is multiplied by a coefficient, divide by that coefficient to solve for ( x ).
To put an equation in standard form, you typically need to rearrange the equation so that all terms involving variables are on one side and the constant is on the other. Specifically, you would move any terms to one side by adding or subtracting them, and then ensure that the coefficients of the variables are integers, with the leading coefficient (the coefficient of the variable with the highest degree) being positive.
RULE #1: you can add, subtract, multiply and divide by anything, as long as you do the same thing to both sides of the equals sign.RULE #2: to move or cancel a quantity or variable on one side of the equation, perform the "opposite" operation with it on both sides of the equation.
The question only makes sense if the equation is a linear one. You rearrange the terms of the equation so that you have y on one side of the equals sign and the rest on the other side. Divide through by the coefficient of y so you then have the equation in the form y = mx + c One point on the line is (0, c) and the slope is m.
The equation can be expressed as ( y = \frac{1}{4}x - 5 ). This means that if you take one fourth of ( x ) and then subtract 5 from it, you will get ( y ). To find ( x ) in terms of ( y ), you can rearrange the equation to ( x = 4(y + 5) ).
There are two terms: 3x, -2b. Yeah, two terms. But where is the equation?
To write an equation showing ( y ) as a function of ( x ), you typically want to express ( y ) in terms of ( x ), isolating ( y ) on one side of the equation. For example, if you have a linear equation like ( 2x + 3y = 6 ), you can rearrange it to ( y = -\frac{2}{3}x + 2 ). This format clearly indicates that ( y ) is dependent on the value of ( x ).