Final "I Can Statements" Answer Key

... ideal gas –any gas that conforms to all of the parts of the KMT. Ideal gases are theoretical although some gases are close. Hydrogen and helium are the closest to ideal gases at all temperatures and pressures. A gas will act most “ideally” under the conditions of __low___ pressure and ___high_____ t ...

1.Using the table above, decide if the element mercury (Hg) should

... The metal is reduced from a cationic state to the neutral metal. b. Why is iron produced by reaction with carbon, but sodium (Na) is produced by electrolysis? Fe is easy enough to reduce that it can be done with C at reasonable temperatures. Iron could also be done via electrolysis, but that is more ...

AP Chem Summer Assign Gen Chem Rev Problems

... Suppose under perfect conditions the heat transferred should have been 943 cal. Calculate the Percent Error of the experiment in (a). c. How many joules of energy are required to melt a 17 gram ice cube? (The latent heat of fusion of water is 80 cal/g) d. Draw a heating curve for a substance that ha ...

Semester 1 exam review

... 18. The human bladder can hold up to 2 cups of urine. (for those of you that need to go to the bathroom all the time) How many liters is this? Review questions for test on Ch. 3 1. What is the kinetic theory of matter? 2. What are the two definitions of a gas? 3. What makes air pressure on the atomi ...

Introduction to Computational Chemistry

... —> operator T performs changes of the electron distribution, as expressed through the molecular orbitals φi to compute the correlation energy: ψ = eTφo H eTΨ0 = E eTΨ0 —> single, double…etc substitutions (CCD, CCSD, CCSD(T)…) —> CCSD(T) is most common and probably the best choice as the triple contr ...

Chapter 3: Atoms: The Building Blocks of Matter

...  Determine the number of electrons that can be located in each energy level and sublevel.  Define the Pauli Exclusion Principle.  Write the electron configuration of an atom in the ground state.  Using Hund’s Rule, construct an orbital diagram for an atom.  Distinguish between valence and core ...

Revision Y12 Chemistry PLC

... linear, non-linear, trigonal planar, pyramidal, tetrahedral and octahedral. Lone pairs repel more than bonded pairs and the bond angles for common examples of each shape including CH4 (109.5°), NH3 (107°) and H2O (104.5°). Electronegativity and bond polarity (i) electronegativity as the ability of a ...

Essential Standard: 8.P.1 Understand the properties of matter and

... compose all substances and determine the characteristics properties of substances. Elements are pure substances that cannot be changed into simpler substances. Elements are composed of one kind of atom. Compounds are pure substances that are composed of two or more types of elements that are chemica ...

7 Periodic Properties of the Elements

... reacts with steam, but not H 2 O(l) ...

1 - Intro to Electrochemistry

... In covalent compounds however, electrons are not really ____________________ Instead, _____________________ result from the _______________________ of the electrons involved in the covalent bond In covalent compounds, the _________________ oxidation number is arbitrarily assigned to the element havi ...

Chapter 2

... bonding partners • An example is the transfer of an electron from sodium to chlorine • After the transfer of an electron, both atoms have charges ...

Chemistry 1 Lectures

... Electron pairs align at 0, 120, and 360º around the central atom, A # of atoms bonded to central atom ...

Document

... With these problems, why use atomic mass at all? 1. Masses give information about # of p+, n0, e– 2. It is useful to know relative mass E.g. Q - What ratio is needed to make H2O? A - 2:1 by atoms, but 2:16 by mass  It is useful to associate atomic mass with a mass in grams. It has been found that ...

Chemistry General v. 2016

... distinguish among the isotopic forms of elements. Recognize discoveries form Daltons atomic theory, Thomson’s (the electron), Rutherford (the nucleus), and Bohr (the planetary model of atom). Describe Rutherford’s gold foil experiment that led to the discovery of the nuclear atom. Students will be a ...

How to Balance Chemical Equations

... involved are set and their formulas can not be altered. Hence, any change to the subscripts is NOT allowed.  ONLY COEFFICIENTS ARE ALLOWED TO BE CHANGED!! ...

Test - Regents

... 45 What occurs when a substance in an oxidationreduction reaction is reduced? (1) It loses electrons, and its oxidation number ...

SOLUBILITY RULES FOR IONIC COMPOUNDS IN WATER

... 9. group – ionization energy decreases going down due to increasing number of energy levels, which are shielding the increasing nuclear charge, resulting in less attraction for the valence electrons period – ionization energy increases moving right due to increasing nuclear charge, while the number ...

Atoms, Molecules and Ions

... forms both Fe+ and Fe2+ ions, we need to use the Stock system and call the compound iron(II) nitrate. (b) The cation is Na+ and the anion is HPO42− (hydrogen phosphate). Because sodium only forms one type of ion (Na+), there is no need to use sodium(I) in the name. The compound is sodium hydrogen ph ...

Scientific Measurement

... Fusion: change from _________________ to _________________. Solidification: change from _________________ to _________________. Condensation: change from _________________ to _________________. Vaporization: change from _________________ to _________________. _____17. I can state the change of phas ...

electron configuration

... • Atomic Orbitals are filled from lowest energy to highest energy • Full/half full atomic orbitals – Adding electrons until all orbitals are full is a lower energy state (usually) – Paired electrons are higher energy than unpaired (Hund’s Rule) – Half full orbitals reduce electrostatic repulsion (Co ...

g - Porterville College Home

... a. For anions, add one electron for each negative charge. b. For cations, subtract one electron for each charge. Use this number of electrons exactly for bonding and non-bonding in the structure. These electrons must be distributed to all atoms such that each has an octet except hydrogen (“duet”). 2 ...

Chapter 10 (Hill/Petrucci/McCreary/Perry Bonding Theory and

... valence bond theory: a covalent bond involves the overlap of atomic orbitals on two different atoms, each atom contributing one electron to the bond itself … region of overlap is the covalent bond and has a high electron density… In the valence bond approach, only valence electrons participate in th ...

Electron

... • Atoms with incomplete valence shells can share or transfer valence electrons with certain other atoms • These interactions usually result in atoms staying close together, held by attractions called chemical bonds ...

Course __Chemistry Sept Oct Nov Dec Jan Feb March April May June

... atoms in molecules such as H2, CH4, NH3, H2CCH2, N2, Cl2 and many large biological molecules are covalent. B4. Chemical and physical properties of matter result from the ability of atoms to form bonds from electrostatic forces between electrons and protons and between atoms and molecules ...

Chemistry 1st Semester Practice Exam

... D. z E. w 52. Element X reacts with sodium to form an ionic compound with the formula Na2X. Element X is a member of group __________. A. w B. x ...

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Electronegativity

Electronegativity, symbol χ, is a chemical property that describes the tendency of an atom or a functional group to attract electrons (or electron density) towards itself. An atom's electronegativity is affected by both its atomic number and the distance at which its valence electrons reside from the charged nucleus. The higher the associated electronegativity number, the more an element or compound attracts electrons towards it. The term ""electronegativity"" was introduced by Jöns Jacob Berzelius in 1811,though the concept was known even before that and was studied by many chemists including Avogadro.In spite of its long history, an accurate scale of electronegativity had to wait till 1932, when Linus Pauling proposed an electronegativity scale, which depends on bond energies, as a development of valence bond theory. It has been shown to correlate with a number of other chemical properties. Electronegativity cannot be directly measured and must be calculated from other atomic or molecular properties. Several methods of calculation have been proposed, and although there may be small differences in the numerical values of the electronegativity, all methods show the same periodic trends between elements. The most commonly used method of calculation is that originally proposed by Linus Pauling. This gives a dimensionless quantity, commonly referred to as the Pauling scale, on a relative scale running from around 0.7 to 3.98 (hydrogen = 2.20). When other methods of calculation are used, it is conventional (although not obligatory) to quote the results on a scale that covers the same range of numerical values: this is known as an electronegativity in Pauling units. As it is usually calculated, electronegativity is not a property of an atom alone, but rather a property of an atom in a molecule. Properties of a free atom include ionization energy and electron affinity. It is to be expected that the electronegativity of an element will vary with its chemical environment, but it is usually considered to be a transferable property, that is to say that similar values will be valid in a variety of situations.On the most basic level, electronegativity is determined by factors like the nuclear charge (the more protons an atom has, the more ""pull"" it will have on electrons) and the number/location of other electrons present in the atomic shells (the more electrons an atom has, the farther from the nucleus the valence electrons will be, and as a result the less positive charge they will experience—both because of their increased distance from the nucleus, and because the other electrons in the lower energy core orbitals will act to shield the valence electrons from the positively charged nucleus).The opposite of electronegativity is electropositivity: a measure of an element's ability to donate electrons.Caesium is the least electronegative element in the periodic table (=0.79), while fluorine is most electronegative (=3.98). (Francium and caesium were originally assigned both assigned 0.7; caesium's value was later refined to 0.79, but no experimental data allows a similar refinement for francium. However, francium's ionization energy is known to be slightly higher than caesium's, in accordance with the relativistic stabilization of the 7s orbital, and this in turn implies that caesium is in fact more electronegative than francium.)

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Electronegativity