PHYSICS CHEMISTRY BIOLOGY
... Elastic behavior, Stress-strain relationship. Hooke’s law, Young’s modulus, bulk modulus, shear, modulus of rigidity, poisson’s ratio; elastic energy. Viscosity, Stokes’ law, terminal velocity, Reynold’s number, streamline and turbulent flow. Critical velocity, Bernoulli’s theorem and its applicatio ...
... Elastic behavior, Stress-strain relationship. Hooke’s law, Young’s modulus, bulk modulus, shear, modulus of rigidity, poisson’s ratio; elastic energy. Viscosity, Stokes’ law, terminal velocity, Reynold’s number, streamline and turbulent flow. Critical velocity, Bernoulli’s theorem and its applicatio ...
AIPMT prelims examination last year cut off
... Equilibrium in physical and chemical processes, dynamic nature of equilibrium, law of chemical equilibrium, equilibrium constant, factors affecting equilibrium-Le Chatelier’s principle; ionic equilibrium- ionization of acids and bases, strong and weak electrolytes, degree of ionization, ionization o ...
... Equilibrium in physical and chemical processes, dynamic nature of equilibrium, law of chemical equilibrium, equilibrium constant, factors affecting equilibrium-Le Chatelier’s principle; ionic equilibrium- ionization of acids and bases, strong and weak electrolytes, degree of ionization, ionization o ...
No Slide Title - McMaster Chemistry
... RELATIVE STRENGTHS of ACIDS and BASES STRONG ACIDS - react completely with water to form H3O+ (aq) HCl (aq) + H2O H3O+ (aq) + Cl- (aq) STRONG BASES - react completely with water to form OH- (aq) Li2O + H2O 2 Li+ (aq) + OH- (aq) Weak ACIDS/ weak BASES only react partially with water - an EQUILIB ...
... RELATIVE STRENGTHS of ACIDS and BASES STRONG ACIDS - react completely with water to form H3O+ (aq) HCl (aq) + H2O H3O+ (aq) + Cl- (aq) STRONG BASES - react completely with water to form OH- (aq) Li2O + H2O 2 Li+ (aq) + OH- (aq) Weak ACIDS/ weak BASES only react partially with water - an EQUILIB ...
Homogeneous Catalysis
... To minimize the error this introduces into our measurements, it seems advisable to measure the rate of reaction over periods of time that are short compared with the time it takes for the reaction to occur. We might try, for example, to measure the infinitesimally small change in ...
... To minimize the error this introduces into our measurements, it seems advisable to measure the rate of reaction over periods of time that are short compared with the time it takes for the reaction to occur. We might try, for example, to measure the infinitesimally small change in ...
C7 Revision Notes 2015
... •Sports men and women have to provide urine samples to check they have not been taking drugs this is done in front of a testing officer to ensure it is not tampered with and labelled with a unique code so the lab does not know the identity of the ...
... •Sports men and women have to provide urine samples to check they have not been taking drugs this is done in front of a testing officer to ensure it is not tampered with and labelled with a unique code so the lab does not know the identity of the ...
Density Functional Theory Based Study of the Electron Transfer
... Chemical reaction rates are generally calculated using the transition-state theory (TST)35 and other theories based in whole or in part on the fundamental assumptions of TST or some quantum mechanical generalization of these assumptions.36−38 However, these theories are not applicable for electron t ...
... Chemical reaction rates are generally calculated using the transition-state theory (TST)35 and other theories based in whole or in part on the fundamental assumptions of TST or some quantum mechanical generalization of these assumptions.36−38 However, these theories are not applicable for electron t ...
In_Class_Practice Chapter 17 PreAP
... Calculate Keq for this equilibrium using the data [NOBr] = 0.0474 mol/L, [NO] = 0.312 mol/L, and [Br2] = 0.259 mol/L. Practice Problems 3. The following is the chemical equation for the decomposition of formamide. HCONH2(g) NH3(g) + CO(g) Calculate Keq using the equilibrium data [HCONH2] = 0.0637 ...
... Calculate Keq for this equilibrium using the data [NOBr] = 0.0474 mol/L, [NO] = 0.312 mol/L, and [Br2] = 0.259 mol/L. Practice Problems 3. The following is the chemical equation for the decomposition of formamide. HCONH2(g) NH3(g) + CO(g) Calculate Keq using the equilibrium data [HCONH2] = 0.0637 ...
The Nature of Energy - Rivermont Collegiate
... identification of the systems, the type (heat versus work), or the direction of energy flow. LO 5.5 The student is able to use the conservation of energy to relate the magnitudes of the energy changes when two nonreacting substances are mixed or brought into contact with one another. LO 5.6 The stud ...
... identification of the systems, the type (heat versus work), or the direction of energy flow. LO 5.5 The student is able to use the conservation of energy to relate the magnitudes of the energy changes when two nonreacting substances are mixed or brought into contact with one another. LO 5.6 The stud ...
Name: Chemistry Honors Date: Period: ____ Reduction/Oxidation
... 2. As (s) + ClO3-1 (aq) H3AsO3 (aq) + HClO (aq) ...
... 2. As (s) + ClO3-1 (aq) H3AsO3 (aq) + HClO (aq) ...
An enquiry into theoretical bioinorganic chemistry: How heuristic is
... DFT—because of the feasibility of such calculations rather than because of their reliability. In principle, there exists an exact energy density functional that allows us to calculate the potential energy surface Eel,0 of the electronic ground state from the electronic density alone owing to the fir ...
... DFT—because of the feasibility of such calculations rather than because of their reliability. In principle, there exists an exact energy density functional that allows us to calculate the potential energy surface Eel,0 of the electronic ground state from the electronic density alone owing to the fir ...
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.