Thermodynamics: Spontaneity, Entropy and Free energy
... • 1st Law: Energy in conserved (neither created nor destroyed in any process) • 2nd Law: the total entropy of the universe increases in any spontaneous process. • 3rd Law: the entropy of a pure crystalline substance at absolute zero is zero (S =0) ...
... • 1st Law: Energy in conserved (neither created nor destroyed in any process) • 2nd Law: the total entropy of the universe increases in any spontaneous process. • 3rd Law: the entropy of a pure crystalline substance at absolute zero is zero (S =0) ...
Ch17-2 Driving Forces of Reactions
... What would the activation curve look like for a rapid reaction? What would happen if amount
... What would the activation curve look like for a rapid reaction? What would happen if amount
Equilibrium
... Indicator: Discuss criteria for equilibrium Requirements for equilibrium: 1. can only occur in a closed system 2. rates of the forward reactions is the same as the rate of the reverse reaction 3. constancy or properties for the chemicals involved (ex: colour stays the same) When a reactions reaches ...
... Indicator: Discuss criteria for equilibrium Requirements for equilibrium: 1. can only occur in a closed system 2. rates of the forward reactions is the same as the rate of the reverse reaction 3. constancy or properties for the chemicals involved (ex: colour stays the same) When a reactions reaches ...
Chemistry 2nd Semester Final Exam Review Chemical Bonds Give
... 40. What happens to atoms or molecules as their temperature is increased? 41. Describe heat flow. 42. What is the difference between an exothermic reaction and an endothermic reaction? 43. Draw an energy diagram for an endothermic and exothermic reaction. 44. Are the following changes of state exoth ...
... 40. What happens to atoms or molecules as their temperature is increased? 41. Describe heat flow. 42. What is the difference between an exothermic reaction and an endothermic reaction? 43. Draw an energy diagram for an endothermic and exothermic reaction. 44. Are the following changes of state exoth ...
2nd Semester Final Review
... 40. What happens to atoms or molecules as their temperature is increased? 41. Describe heat flow. 42. What is the difference between an exothermic reaction and an endothermic reaction? 43. Draw an energy diagram for an endothermic and exothermic reaction. 44. Are the following changes of state exoth ...
... 40. What happens to atoms or molecules as their temperature is increased? 41. Describe heat flow. 42. What is the difference between an exothermic reaction and an endothermic reaction? 43. Draw an energy diagram for an endothermic and exothermic reaction. 44. Are the following changes of state exoth ...
Chemistry 30 Notes - Heat of Formation February 2nd
... If you have trouble converting mass into moles, better dig out your old Chemistry 20 notes or textbook and review. Chemistry 30 will require you to remember this basic chemistry skill! Step 2: Determine kJ for 0.390 mol We know from the question that 297 kJ of energy is released for 1 mole of SO2 — ...
... If you have trouble converting mass into moles, better dig out your old Chemistry 20 notes or textbook and review. Chemistry 30 will require you to remember this basic chemistry skill! Step 2: Determine kJ for 0.390 mol We know from the question that 297 kJ of energy is released for 1 mole of SO2 — ...
4.5b.notes
... Eg. Plants convert carbon dioxide gas and water into glucose (C6H12O6) and oxygen ...
... Eg. Plants convert carbon dioxide gas and water into glucose (C6H12O6) and oxygen ...
National 5 Chemistry Prelim Revision 1
... A compound has a relative formula mass of 30 and contains only carbon and hydrogen. Which statement about the compound is true? ...
... A compound has a relative formula mass of 30 and contains only carbon and hydrogen. Which statement about the compound is true? ...
ppt
... Use the following thermochemical equation to calculate the molar heat of combustion of hexane. 2C6H14 (l) + 19O2 (g) 12CO2 (g) + 14H2O (g) + 7086kJ ...
... Use the following thermochemical equation to calculate the molar heat of combustion of hexane. 2C6H14 (l) + 19O2 (g) 12CO2 (g) + 14H2O (g) + 7086kJ ...
Standard 4.8
... A They easily form ionic bonds with each other. B They easily form covalent bonds with each other. C They easily combine with atoms of oxygen. D They easily become highly charged ions. ...
... A They easily form ionic bonds with each other. B They easily form covalent bonds with each other. C They easily combine with atoms of oxygen. D They easily become highly charged ions. ...
Chemical Reactions
... ___________________. A chemical change may be observed during a chemical reaction when the following happens: (use figure 2.2a-e) 1. ________________________________________________ 2. ________________________________________________ 3. ________________________________________________ 4. ___________ ...
... ___________________. A chemical change may be observed during a chemical reaction when the following happens: (use figure 2.2a-e) 1. ________________________________________________ 2. ________________________________________________ 3. ________________________________________________ 4. ___________ ...
Activation energy
... • Activation energy is the energy needed to start a reaction and break chemical bonds in the reactants. – This is why a flammable material, like gasoline, does not burn without a spark or flame. – The spark supplies the activation energy to start the reaction. ...
... • Activation energy is the energy needed to start a reaction and break chemical bonds in the reactants. – This is why a flammable material, like gasoline, does not burn without a spark or flame. – The spark supplies the activation energy to start the reaction. ...
Dr. Ali Ebneshahidi
... Organic chemistry – chemistry that deals with organic substances (those that contain carbon and hydrogen). Biochemistry - chemistry of living organisms; essential for understanding physiology because body functions involve chemical changes that occur within cells. Matter – anything that has we ...
... Organic chemistry – chemistry that deals with organic substances (those that contain carbon and hydrogen). Biochemistry - chemistry of living organisms; essential for understanding physiology because body functions involve chemical changes that occur within cells. Matter – anything that has we ...
Test 4
... Randomness that comes from the number of different arrangements of a system. Molar entropy of fusion The heat energy that must be added to a solid to make it a liquid when it is at its melting temperature. ...
... Randomness that comes from the number of different arrangements of a system. Molar entropy of fusion The heat energy that must be added to a solid to make it a liquid when it is at its melting temperature. ...
Exothermic vs Endothermic
... and quickly sealed the bag. The tablet began to fizz and soon disappeared. The bag was filled with gas. If the total mass of the bag + tablet + water was 135 grams before the reaction, what was the total mass of the bag + liquid + gas after the reaction was completed? 60 grams 75 grams 135 grams 270 ...
... and quickly sealed the bag. The tablet began to fizz and soon disappeared. The bag was filled with gas. If the total mass of the bag + tablet + water was 135 grams before the reaction, what was the total mass of the bag + liquid + gas after the reaction was completed? 60 grams 75 grams 135 grams 270 ...
Transition state theory
Transition state theory (TST) explains the reaction rates of elementary chemical reactions. The theory assumes a special type of chemical equilibrium (quasi-equilibrium) between reactants and activated transition state complexes.TST is used primarily to understand qualitatively how chemical reactions take place. TST has been less successful in its original goal of calculating absolute reaction rate constants because the calculation of absolute reaction rates requires precise knowledge of potential energy surfaces, but it has been successful in calculating the standard enthalpy of activation (Δ‡Hɵ), the standard entropy of activation (Δ‡Sɵ), and the standard Gibbs energy of activation (Δ‡Gɵ) for a particular reaction if its rate constant has been experimentally determined. (The ‡ notation refers to the value of interest at the transition state.)This theory was developed simultaneously in 1935 by Henry Eyring, then at Princeton University, and by Meredith Gwynne Evans and Michael Polanyi of the University of Manchester. TST is also referred to as ""activated-complex theory,"" ""absolute-rate theory,"" and ""theory of absolute reaction rates.""Before the development of TST, the Arrhenius rate law was widely used to determine energies for the reaction barrier. The Arrhenius equation derives from empirical observations and ignores any mechanistic considerations, such as whether one or more reactive intermediates are involved in the conversion of a reactant to a product. Therefore, further development was necessary to understand the two parameters associated with this law, the pre-exponential factor (A) and the activation energy (Ea). TST, which led to the Eyring equation, successfully addresses these two issues; however, 46 years elapsed between the publication of the Arrhenius rate law, in 1889, and the Eyring equation derived from TST, in 1935. During that period, many scientists and researchers contributed significantly to the development of the theory.