Initial Reactant Concentration of Reactant for No Pore Resistance in Catalyst Deactivation Solution

STEP 0: Pre-Calculation Summary
Formula Used
Initial Conc. for 1st Order Catalyzed Reactions = Reactant Concentration for No Pore Diffusion*exp(Rate Constant based on Weight of Catalyst*Space Time for 1st Order Catalyzed Reactions*exp(-Rate of Deactivation*Time Interval))
CA0 = CA,NP*exp(k'*𝛕 '*exp(-kd*t))
This formula uses 1 Functions, 6 Variables
Functions Used
exp - n an exponential function, the value of the function changes by a constant factor for every unit change in the independent variable., exp(Number)
Variables Used
Initial Conc. for 1st Order Catalyzed Reactions - (Measured in Mole per Cubic Meter) - Initial Conc. for 1st Order Catalyzed Reactions is the first measured Concentration of a Compound in a Substance.
Reactant Concentration for No Pore Diffusion - (Measured in Mole per Cubic Meter) - Reactant Concentration for No Pore Diffusion refers to the amount of reactant present at any given point of time during the process, in Catalyst Deactivation.
Rate Constant based on Weight of Catalyst - (Measured in 1 Per Second) - The Rate Constant based on Weight of Catalyst is a specific form of expressing the rate constant in a catalytic reaction with respect to the mass of the catalyst.
Space Time for 1st Order Catalyzed Reactions - (Measured in Second) - Space Time for 1st Order Catalyzed Reactions is a parameter used to quantify the time required for a given volume of reactant to pass through a catalytic reactor.
Rate of Deactivation - (Measured in 1 Per Second) - Rate of Deactivation refers to the speed or rate at which the activity of a catalyst decreases over time in a chemical reaction.
Time Interval - (Measured in Second) - A Time Interval is the amount of time required for the change from initial to the final state.
STEP 1: Convert Input(s) to Base Unit
Reactant Concentration for No Pore Diffusion: 7.06 Mole per Cubic Meter --> 7.06 Mole per Cubic Meter No Conversion Required
Rate Constant based on Weight of Catalyst: 0.988 1 Per Second --> 0.988 1 Per Second No Conversion Required
Space Time for 1st Order Catalyzed Reactions: 2.72 Second --> 2.72 Second No Conversion Required
Rate of Deactivation: 0.034 1 Per Second --> 0.034 1 Per Second No Conversion Required
Time Interval: 3 Second --> 3 Second No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
CA0 = CA,NP*exp(k'*𝛕 '*exp(-kd*t)) --> 7.06*exp(0.988*2.72*exp(-0.034*3))
Evaluating ... ...
CA0 = 79.9347396570184
STEP 3: Convert Result to Output's Unit
79.9347396570184 Mole per Cubic Meter --> No Conversion Required
FINAL ANSWER
79.9347396570184 79.93474 Mole per Cubic Meter <-- Initial Conc. for 1st Order Catalyzed Reactions
(Calculation completed in 00.005 seconds)

Credits

Creator Image
Created by Pavan Kumar
Anurag Group of Institutions (AGI), Hyderabad
Pavan Kumar has created this Calculator and 100+ more calculators!
Verifier Image
Verified by Vaibhav Mishra
DJ Sanghvi College of Engineering (DJSCE), Mumbai
Vaibhav Mishra has verified this Calculator and 200+ more calculators!

Deactivating Catalysts Calculators

Weight of Catalyst in Batch Solids and Batch Fluids
​ LaTeX ​ Go Weight of Catalyst in Deactivation of Catalyst = ((Volume of Reactor*Rate of Deactivation)/Rate Constant based on Weight of Catalyst)*exp(ln(ln(Reactant Concentration/Concentration at Infinite Time))+Rate of Deactivation*Time Interval)
Deactivation rate for Batch Solids and Mixed Changing Flow of Fluids
​ LaTeX ​ Go Rate of Deactivation for Mixed Flow = (ln(Space Time for 1st Order Catalyzed Reactions)-ln((Initial Conc. for 1st Order Catalyzed Reactions-Reactant Concentration)/(Rate Constant based on Weight of Catalyst*Reactant Concentration)))/Time Interval
Deactivation Rate in Batch Solids and Mixed Constant Flow of Fluids
​ LaTeX ​ Go Rate of Deactivation for Mixed Flow = (ln(Rate Constant based on Weight of Catalyst*Space Time for 1st Order Catalyzed Reactions)-ln((Initial Conc. for 1st Order Catalyzed Reactions/Reactant Concentration)-1))/Time Interval
Activity of Catalyst
​ LaTeX ​ Go Activity of Catalyst = -(Rate at which Pellet converts Reactant A)/-(Rate of Reaction of A with a Fresh Pellet)

Initial Reactant Concentration of Reactant for No Pore Resistance in Catalyst Deactivation Formula

​LaTeX ​Go
Initial Conc. for 1st Order Catalyzed Reactions = Reactant Concentration for No Pore Diffusion*exp(Rate Constant based on Weight of Catalyst*Space Time for 1st Order Catalyzed Reactions*exp(-Rate of Deactivation*Time Interval))
CA0 = CA,NP*exp(k'*𝛕 '*exp(-kd*t))

What is No Pore Resistance?

No Pore Diffusion refers to a situation in catalysis where mass transfer limitations associated with diffusion of reactants and products within the pores of a catalyst are negligible or not significant. Pore diffusion can be a limiting factor in catalytic reactions, especially when the reactants and products need to diffuse through the internal structure of the catalyst material.

What is Deactivation of Catalyst?

Catalyst deactivation refers to a gradual loss of catalytic activity over time, leading to a decline in the catalyst's effectiveness in promoting a chemical reaction. This phenomenon can occur due to various factors, and understanding the mechanisms of catalyst deactivation is crucial for optimizing and extending the lifespan of catalysts in industrial processes.

How to Calculate Initial Reactant Concentration of Reactant for No Pore Resistance in Catalyst Deactivation?

Initial Reactant Concentration of Reactant for No Pore Resistance in Catalyst Deactivation calculator uses Initial Conc. for 1st Order Catalyzed Reactions = Reactant Concentration for No Pore Diffusion*exp(Rate Constant based on Weight of Catalyst*Space Time for 1st Order Catalyzed Reactions*exp(-Rate of Deactivation*Time Interval)) to calculate the Initial Conc. for 1st Order Catalyzed Reactions, The Initial Reactant Concentration of Reactant for No Pore Resistance in Catalyst Deactivation formula is defined as Concentration of Reactant Calculated, when there is No Resistance to Pore Diffusion in the Catalyst, with Deactivation. Initial Conc. for 1st Order Catalyzed Reactions is denoted by CA0 symbol.

How to calculate Initial Reactant Concentration of Reactant for No Pore Resistance in Catalyst Deactivation using this online calculator? To use this online calculator for Initial Reactant Concentration of Reactant for No Pore Resistance in Catalyst Deactivation, enter Reactant Concentration for No Pore Diffusion (CA,NP), Rate Constant based on Weight of Catalyst (k'), Space Time for 1st Order Catalyzed Reactions (𝛕 '), Rate of Deactivation (kd) & Time Interval (t) and hit the calculate button. Here is how the Initial Reactant Concentration of Reactant for No Pore Resistance in Catalyst Deactivation calculation can be explained with given input values -> 272.865 = 7.06*exp(0.988*2.72*exp(-0.034*3)).

FAQ

What is Initial Reactant Concentration of Reactant for No Pore Resistance in Catalyst Deactivation?
The Initial Reactant Concentration of Reactant for No Pore Resistance in Catalyst Deactivation formula is defined as Concentration of Reactant Calculated, when there is No Resistance to Pore Diffusion in the Catalyst, with Deactivation and is represented as CA0 = CA,NP*exp(k'*𝛕 '*exp(-kd*t)) or Initial Conc. for 1st Order Catalyzed Reactions = Reactant Concentration for No Pore Diffusion*exp(Rate Constant based on Weight of Catalyst*Space Time for 1st Order Catalyzed Reactions*exp(-Rate of Deactivation*Time Interval)). Reactant Concentration for No Pore Diffusion refers to the amount of reactant present at any given point of time during the process, in Catalyst Deactivation, The Rate Constant based on Weight of Catalyst is a specific form of expressing the rate constant in a catalytic reaction with respect to the mass of the catalyst, Space Time for 1st Order Catalyzed Reactions is a parameter used to quantify the time required for a given volume of reactant to pass through a catalytic reactor, Rate of Deactivation refers to the speed or rate at which the activity of a catalyst decreases over time in a chemical reaction & A Time Interval is the amount of time required for the change from initial to the final state.
How to calculate Initial Reactant Concentration of Reactant for No Pore Resistance in Catalyst Deactivation?
The Initial Reactant Concentration of Reactant for No Pore Resistance in Catalyst Deactivation formula is defined as Concentration of Reactant Calculated, when there is No Resistance to Pore Diffusion in the Catalyst, with Deactivation is calculated using Initial Conc. for 1st Order Catalyzed Reactions = Reactant Concentration for No Pore Diffusion*exp(Rate Constant based on Weight of Catalyst*Space Time for 1st Order Catalyzed Reactions*exp(-Rate of Deactivation*Time Interval)). To calculate Initial Reactant Concentration of Reactant for No Pore Resistance in Catalyst Deactivation, you need Reactant Concentration for No Pore Diffusion (CA,NP), Rate Constant based on Weight of Catalyst (k'), Space Time for 1st Order Catalyzed Reactions (𝛕 '), Rate of Deactivation (kd) & Time Interval (t). With our tool, you need to enter the respective value for Reactant Concentration for No Pore Diffusion, Rate Constant based on Weight of Catalyst, Space Time for 1st Order Catalyzed Reactions, Rate of Deactivation & Time Interval and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.
How many ways are there to calculate Initial Conc. for 1st Order Catalyzed Reactions?
In this formula, Initial Conc. for 1st Order Catalyzed Reactions uses Reactant Concentration for No Pore Diffusion, Rate Constant based on Weight of Catalyst, Space Time for 1st Order Catalyzed Reactions, Rate of Deactivation & Time Interval. We can use 1 other way(s) to calculate the same, which is/are as follows -
  • Initial Conc. for 1st Order Catalyzed Reactions = Reactant Concentration for Strong Pore Diffusion*exp(((Rate Constant based on Weight of Catalyst*Space Time for 1st Order Catalyzed Reactions)/Thiele Modulus for Deactivation without a)*exp((-Rate of Deactivation*Time Interval)/2))
Let Others Know
Facebook
Twitter
Reddit
LinkedIn
Email
WhatsApp
Copied!