Thermodynamics

Calorimetry Problems, Thermochemistry Practice, Specific Heat Capacity, Enthalpy Fusion, Chemistry

 

Calorimetry Problems 
vs 
-MCAT

 

Bomb Calorimeter vs Coffee Cup Calorimeter Problem – Constant Pressure vs Constant Volume Calorimet

 

The Bomb Calorimeter

 

Enthalpy is the energy required to break a bond

Enthalpy is the same thing as the heat of the reaction

Mathematical Expression of Enthalpy [ edit I edit source ] 
Enthalpy(H) is a measure of the heat energy of a reaction. The Enthalpy H of a thermodynamic system whose internal energy, pressure, and volume are U, P, and V is defined as H =U+PV. Since 
U, P, and V are state functions, H is a state function. note from dw=-PdV that the product of P and V has the dimensions of work and hence of energy. Therefore it is legitimate to add U and PV. 
Naturally, H has units of energy. 
For example, a reaction that is exothermic will have a negative change in enthalpy. This is because the enthalpy of the products is less that that of the reactants. 
In mathematical terms enthalpy of a reaction can be known as the following: 
AH = (sums of bonds broken) - (sums of bonds formed) 
AH = Enl* products • EnHreactants 
When Al I is negative then the reaction is exothermic and more bonds are formed than broken 
If AH is positive then the reaction is endothermic. Chemical bonds tend to form spontaneously that the negative value of AH represents exotheunic reaction 
The enthalpy for the reverse reaction is equal in magnitude, but opposite in mathematical sign. 
Enthalpy is a state function and thus according to Hess's Law, the overall enthalpy of the reaction is equal to the sum of the enthalpies of the individual reactions or steps for which the overall 
reaction can be divided. 
Since enthalpy is a function defined for the sake of calculations, it is difficult to measure the actual enthalpy of a substance. The change in enthalpy however, is easily measured and is an 
important quantity in many calculations. 
When enthalpy changes, it signifies there is a change of state happening in the system. But enthalpies are reversible in the sense that the physical state changes are usually reversible. Therefore, 
since the enthalpy for formation of everything is always given, then at any given change, the new enthalpy can be calculated.

 

Enthalpy (video) | Thermodynamics | Khan Academy

 

 

https://www.geeksforgeeks.org/enthalpies-for-different-types-of-reactions/

 

http://ch301.cm.utexas.edu/thermo/#enthalpy/enthalpy-all.php

 

7.68 | How does the bond energy of HCl(g) differ from the standard enthalpy of formation of HCl(g)?

 

68. How does the differ from the standard.enthal 
—W)fformation 0f HCl(g)? 
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Gibb’s Free Energy

 

-∆G tells you how many joules a reaction consumes or gives off

-negative ∆G indicates that the reaction gives off joules

ATP + H2O ADP + Pi + 30.5 kJ/mol;     ∆G = -30.5 kj/mol

-positive ∆G indicates that the reaction consumes joules

Glucose + Pi Glucose-6 Phosphate;     ∆G = 13.8 kJ/mol

 

-forward and reverse reactions have ∆G’s that are equal in magnitude but with opposite signs

ATPase 
H20 ADP 
hydrolysis 
Pi 
AG = -30.5 kJ/mol

ATP Synthase 
ATP 
+ H20 AG * 
= 30.5 kJ/mol

 

-negative ∆G indicates that the reaction is spontaneous; positive ∆G indicates that the reaction is nonspontaneous

 

-∆G is determined by enthalpy and entropy modified by temperature

 

-the signs and quantities of enthalpy, entropy, and temperature determine if the reaction is spontaneous or not; many “trick” questions can be easily solved by knowing how to manipulate the ∆G equation

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Gibbs Free Energy – Entropy, Enthalpy & Equilibrium Constant K

 

Gibbs Free Energy 
AH-TU 
-ET ink 
-BORT

 

 

 

-∆G° is Gibb’s Free Energy under Standard State conditions

-standard conditions: 1 atm, 1 mole of reactants and products

-usually determined at 25 °C but doesn’t have to be

-1 atm because almost all reactions relevant to us is done under 1 atm (atmospheric pressure at sea level)

-NOT the same as standard temperature and pressure condtions (STP), which is a temperature of 273.15 °K (0 °C) and a pressure of 1 atm

-STP is used for gas reactions

-1 mole of gas takes up 22.4 L of volume

-so 1 mole = 22.4 L

-STP involves two variables (temperature and pressure), standard state involves two variables (moles and pressure)

-how to calulate ∆G° from formation ∆G°’s:

Free Energy (delta G) Calculations Pt 7 - YouTube

 

 

∆G° to Keq relationship:

Free energy and equilibrium

 

∆G of the overall reaction is NEVER related to the rate constant k. The rate constant k is only related to the ∆G of the transition state (ΔG). The ∆G of the overall reaction is never effected by changes in k, because ∆G is in joules AKA work, which is a state function and so does not depend on the path you take to get there.

-So even if you increase k and bring down ΔG, the overall reaction’s ∆G is unchanged

 

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∆G° vs ∆G

 

-∆G° tells you how many joules a reaction gives off/consumes under 1 atm and 1 mole of each reactants and products

-∆G° also tells you about Keq. A negative ∆G° indicates that more products than reactants are present at equilibrium. A positive ∆G° indicates that more reactants than products are present at equilibrium

K =

B 、 ' 0 ~ D 冖

 

-∆G (non standard state) tells you how many joules a reaction gives off when you move away from 1 mole of reactants and products

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-∆G is determined by adding the reaction quotient Q to ∆G°

Standard Gibbs Free Energy - ppt download

 

-∆G° may be positive and show that the reaction is not spontaneous under standard conditions, but after lowering the amount of products and/or raising the amount of reactants, ∆G for the same reaction may be negative and show that the reaction is spontaneous

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Standard State Gibbs Free Energy vs NonStandard State Gibbs Free Energy Thermodynamics Chemistry

 

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-energy of a reaction can be obtained/required as the reaction moves from Q to Keq

-if Q < Keq, then the reaction will want to procede foward and have a negative ∆G

-the further Q is lower than Keq, the more negative ∆G is

 

-if Q > Keq, then the reaction will want to procede backwards and have a positive ∆G

-the further Q is higher than Keq, the more positive ∆G is

 

-once Q is at Keq, no free energy will be produced

 

-trick: imagine a number line

 

How Reaction Quotient vs Keq Determines NonStandard State Gibbs Free Energy (Neat Trick Chemistry!)

 

Free

 

 

 

 

Coupling Reactions

 

-reactions can be coupled when they have similar substrates

-endergonic reactions are coupled to exergonic reactions to make an overall reaction that is favorable

 

BIOCHEM test 2 learning objectives Flashcards | Quizlet

 

 

Electrochemistry (Batteries)