A2 Chemistry key word list
... double bond carries the same atom or group: the cis isomer (Z isomer) has that group on each carbon on the same side; the trans isomer (E isomer) has that group on each carbon on different ...
... double bond carries the same atom or group: the cis isomer (Z isomer) has that group on each carbon on the same side; the trans isomer (E isomer) has that group on each carbon on different ...
Matter—anything that has mass and occupies space Weight—pull of
... Attractive force between electropositive hydrogen of one molecule and an electronegative atom of another molecule Not true bond Common between dipoles such as water Also act as intramolecular bonds, holding a large molecule in a threedimensional shape ...
... Attractive force between electropositive hydrogen of one molecule and an electronegative atom of another molecule Not true bond Common between dipoles such as water Also act as intramolecular bonds, holding a large molecule in a threedimensional shape ...
Review for Final Exam - Short Answer and Problems
... Limestone is composed of calcium carbonate (CaCO3) as well as other compounds. In an analysis, a chemist takes a sample of limestone which has a mass of 413 mg and treats it with oxalic acid (H2C2O4). A chemical reaction occurs between the calcium carbonate and the acid producing calcium oxalate and ...
... Limestone is composed of calcium carbonate (CaCO3) as well as other compounds. In an analysis, a chemist takes a sample of limestone which has a mass of 413 mg and treats it with oxalic acid (H2C2O4). A chemical reaction occurs between the calcium carbonate and the acid producing calcium oxalate and ...
CHM 130 Final Exam Review Chapter 1 Scientific method Theory
... Chapter 8 Writing chemical reactions from words Balancing chemical reactions Classifying chemical reactions o Combination o Decomposition o Combustion o Single replacement o Double replacement o Acid base neutralization Activity series Solubility rules Electrolytes Oxidation and reduction, the agent ...
... Chapter 8 Writing chemical reactions from words Balancing chemical reactions Classifying chemical reactions o Combination o Decomposition o Combustion o Single replacement o Double replacement o Acid base neutralization Activity series Solubility rules Electrolytes Oxidation and reduction, the agent ...
Chemical and Physical Property Unit Test
... a1. What often happens when a chemical or physical change occurs? A. changes in mass B. changes in size C. changes in energy D. changes in color a2. What must often be added to increase the speed or ability of two substances to react? A. a bigger container B. adding heat C. more substances D. adding ...
... a1. What often happens when a chemical or physical change occurs? A. changes in mass B. changes in size C. changes in energy D. changes in color a2. What must often be added to increase the speed or ability of two substances to react? A. a bigger container B. adding heat C. more substances D. adding ...
T h - Website Staff UI
... The standard enthalpy of an overall reaction is the sum of the standard enthalpies of the individual reactions into which a reaction may be divided. Standard reaction enthalpy is the change in enthalpy when the reactants in their standard states change to products in their ...
... The standard enthalpy of an overall reaction is the sum of the standard enthalpies of the individual reactions into which a reaction may be divided. Standard reaction enthalpy is the change in enthalpy when the reactants in their standard states change to products in their ...
Final Exam Practice 2016 (MC)
... d) There are too many electrons in this diagram. The lone pair on carbon should instead be a double bond with one of oxygen’s lone pairs. 23. The molecules CO2 and SO2 have very similar formulas yet make a different shape. What is different about their Lewis structures that give them a different sha ...
... d) There are too many electrons in this diagram. The lone pair on carbon should instead be a double bond with one of oxygen’s lone pairs. 23. The molecules CO2 and SO2 have very similar formulas yet make a different shape. What is different about their Lewis structures that give them a different sha ...
Chapter 8
... • A formula equation uses symbols & formulas to represent the identities & relative amounts of reactants & products. • There are also word equations which use chemical names instead of formulas. • See p. 246 Table Reactants (s) → Products (g) Original Substances ...
... • A formula equation uses symbols & formulas to represent the identities & relative amounts of reactants & products. • There are also word equations which use chemical names instead of formulas. • See p. 246 Table Reactants (s) → Products (g) Original Substances ...
CH 13
... at 25C is 5.21 x 10-4/min. The rate constant for the catalyzed reaction at 25C is 2.95 x 108/min. 1) What is the half-life of the uncatalyzed reaction at 25C? 2) What is the half-life of the catalyzed reaction? ...
... at 25C is 5.21 x 10-4/min. The rate constant for the catalyzed reaction at 25C is 2.95 x 108/min. 1) What is the half-life of the uncatalyzed reaction at 25C? 2) What is the half-life of the catalyzed reaction? ...
1 - College of Arts and Sciences
... A mass of 4.0 g indicates that the uncertainty is in the first decimal place of the measurement. Thus, the mass might be anything between 3.9 and 4.1 ...
... A mass of 4.0 g indicates that the uncertainty is in the first decimal place of the measurement. Thus, the mass might be anything between 3.9 and 4.1 ...
unit_k_reading_notes
... This is because ionic compounds tend to separate into charged particles when they are in water. The different particles formed from AgNO3, for example would be: AgNO3 = Ag+ + (NO3)1One could now ask if the reverse reaction can occur. We find our answer in a property called the activity of an element ...
... This is because ionic compounds tend to separate into charged particles when they are in water. The different particles formed from AgNO3, for example would be: AgNO3 = Ag+ + (NO3)1One could now ask if the reverse reaction can occur. We find our answer in a property called the activity of an element ...
An Overview of Organic Reactions
... The standard free energy change at 1 atm pressure and 298 K is ΔGº The relationship between free energy change and an equilibrium constant is: § ΔGº = - RT ln Keq where § R = 1.987 cal/(K x mol) § T = temperature in Kelvin § ln Keq = natural logarithm of Keq ...
... The standard free energy change at 1 atm pressure and 298 K is ΔGº The relationship between free energy change and an equilibrium constant is: § ΔGº = - RT ln Keq where § R = 1.987 cal/(K x mol) § T = temperature in Kelvin § ln Keq = natural logarithm of Keq ...
Chemical Reactions and The Mole Review
... • http://www.youtube.com/watch?v=QjVYz00Kxc&feature=channel&list=UL ...
... • http://www.youtube.com/watch?v=QjVYz00Kxc&feature=channel&list=UL ...
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.