Chemistry Midterm review. Units 1-7

percent error

how far off you are from what you should have gotten % error= measured val.- accepted val x 100 accepted val

Empirical formula

"simplest terms" lowest whole number, ratio of atoms in a formula. ex C2H6= CH3 ionic substances are always written empirically

summary of trends: down a group

# of electron shells increases, more shells of electrons "in the way" 1. atomic radius & metallic char. increase 2. I.E. & E.N. decrease

(net) charge of ions

# protons - # electrons

Ionic compounds

(metal + nonmetal); metal TRANSFERS electrons to nonmetal *Rules: same as for ions, subscript becomes # in front of brackets for that ion

Covalent/ Molecular Compounds

(nonmetals); atoms SHARE valence electrons to obtain a complete outer shell

Ions (L-E D)

*Rules 1. Metals: lose electrons (no dots) 2. Non-Metals: gain electrons (octet) 3. [Symbol]^charge

atoms (L-E D)

*Rules: 1. symbol with valence e-'s (dots) 2. pair first two electrons (except group 14), then keep going around

cation

+ ion

anion

- ion

-Periods -groups

-horizontal rows, number of energy levels -vertical columns, elements have similar chemical properties bc they have same number of valence e-'s

*Rules for Covalent/ Molecular compounds

1. 1st atom in the formula goes in the center (except H) 2. Place outer atoms around the center atom 3. Draw in each atom's valence e-'s 4. Connect unpaired e-'s between atoms, with lines 5. Make sure each atom has a total of exactly 8 e-'s (H only 2) 6. Re-draw to place bonds/ electrons as Far Apart as possible (e-'s in bonds repel each other)

density

how much mass is in a given value d= m/v m=d x v v= m/d

shapes of molecules (covalent only)

1. linear: straight across HCl 2. Tetrahedral: 4 sides CH4 3. Bent: H2O 4. Pyramidal: pyramid shaped NH3

to determine number of sig figs

1.circle the digit of precision -no decimal point, rightmost non zero number -decimal point, rightmost digit 2.underline all digits, starting with the 1st nonzero, until the precision runs out

trends in P.T. (2)

1.the greater the nuclear charge (# of protons), the more attracted the electrons are to the nucleus- 1 puppy vs alot of puppies 2. the closer the nucleus(protons), the more attracted the electrons are to the nucleus- sitting in last row vs. front row at concert

mass of water

18 g

ex of # of sig figs 0.023410

5 SF

mol

6.02 x 10^23 things

percent composition

how much of the mass of a substance is made up of one element (or water)

chemical properties

how something interacts with another to become something new

structural formula

how the molecule is written

Guy-Lussac's law

when temp of a gas increases, the pressure increases (direct) P1/T1 = P2/T2

excited state electron configuration

an electron gains energy and "jumps" to a higher energy level (energy of the atom is high and unstable) excited electron releases energy and falls back to the ground state (energy releases light, produces bright line spectrum)

Diatomic elements

Br2, I2, N2, Cl2, H2, O2, F2- "7-H Club", when by themselves (element form) they are in pairs

Charles law

when temp of a gas increases, the volume increases (direct) V1/T1 = V2/T2

State at STP

Gases- noble gases (monatomic), N2, Cl2, H2, O2, F2 Liquids- Br2, Hg (mercury)(metal) Solids- I2, everything else

Nonmetals

Group 17, 18

2 nearly ideal gases are

H2 and He because they are the smallest and have the weakest IMF

Group 18: Noble Gases

NOT reactive (very stable), have 8 valence e-'s (octet rule), except He, monatomic gases

E.N. electronegativity

an atoms ability to attract electrons in a bond with another atom

Ionic Covalent

Roman, no prefixes, numerals Greek, prefixes, no numerals

Polyatomic Ions

Table E; group of covalently bonded atoms that have gained or lost e-'s to form a charged ion

atomic radius & metallic character

Table S. size of an atom how much like a metal an element is. tendency to lose electrons

real gas

actual gas, what we work with in a lab, do not follow the gas laws exactly, particles do attract each other (have some IMF), particles do have some volume...atomic radii

matter

anything that has mass and volume. takes up space

Hydrogen Bonds

are FON; attractions between(not within) molecules that have H bonded to F, O, or N (small, very electronegative atoms)

Dimitri Mendelev Henry Moseley

arranged elements by their properties- Russian chemist developed modern periodic table. British physicist

indirect relationship

as one goes up or down, the other does the opposite

direct relationship

as one goes up or down, the other does the same

Boyle's law

as the pressure on a gas increases, the volume of the gas decreases (indirect) P1 x V1 = P2V2

polar

asymmetrical/ bonds b/w different atoms

Rutherford's Gold Foil Experiment

atoms are mostly empty space, atoms have small, dense, (+) charged nucleus in center

isotopes

atoms of the same element with different numbers of neutrons

ions

atoms with a + or - charge, form when an atom loses or gains e-'s, atoms want to have 8 valence e-'s(most stable. octet rule). will form ions according to this rule, have different chemical properties than they atoms they come from

Intermolecular Forces of Attraction (IMF)

attraction b/w molecules; determine state (solids: stroner IMF- higher b.p.) (gases: weak IMF- lower b.p.); weaker than bonds btwn atoms

ionic bonds

attraction between + and - ions (electrostatic attraction); have ionic character

bonds

attractions that hold atoms or ions together ("simultaneous attraction of 2 nuclei for electrons")

spectral lines

bands of colors produced when excited electrons move from excited state to ground state

ion-molecule attractions

between ions and water molecules, cause solids to dissolve (become aq)

gases are most affected by

changes in pressure, temp, volume

Lewis-electron dot structures (L-E D)

chemical symbol with dots around it to show # of valence electrons; show how e-'s are transferred or shared in a bond

Greek writing chemical formulas

covalent substances (nonmetals only), count metalloids like nonmetals. One words, just write the elements symbol (watch for diatomic elements "7H Club" Br,I,N,Cl,H,O,F). Two Words, the greek prefix becomes the subscript on the element

dependent/ independent

dependent depends on the independent

allotropes

diamond (C), graphite (C) same: element Different: structures/ properties

sig figs

digits recorded in a measurement

entropy

disorder, random-ness. increases when...temp increases, something dissolves *highest in gases*

Wave mechanical model

electrons located in orbitals (clouds) surrounding the nucleus -orbitals= regions of most probable electron location

ionization energy & electronegativity

energy to remove and e- attraction for e- in a bond w/ another atom

Avogadro's law

equal volumes of different gases at the same temp and pressure contain equal numbers of particles

molecular formula

ex. C2H6, regular form

2 ways to separate mixtures

filtration- separates s from L distillation- separates aq (based on boiling pt and uses heat)

Trends in the P.T.

force of attraction= charge of particle 1 x charge of particle 2/ distance between particles squared

Groups 3-12: transition metals

form colored solutions (aq), high melting points (hard metals)

Dalton Rutherford Bohr Current

hard sphere model (cannon ball) discovered nucleus in Gold Foil Experiment Planetary (electron shell) model **Wave mechanical model (electron cloud)(fuzzy cloud)**

Group 2: alkaline earth metals

have 2 valence e-'s, less active (more stable), from ions with a +2 charge

Group 1: alkali metals

have only 1 valence e-, very active (unstable), form ions with a positive 1 charge (+1), found in compounds (bonded to other atoms-more stable) ex. Na in water vs. NaCl in water

ideal gases

imaginary, follow the gas laws, particles NOT attracted to each other, particles have NO volume (negligible)

Romans writing chemical formulas

ionic compounds (metal + nonmetal) (polyatomic ions)

hydrates

ionic compounds that have water molecules attached to the ions and written into its chemical formula

periodic table

it is arranged based on valence electrons in columns

network solids

many atoms bonded at form a giant molecule (macro molecules), very hard solids with high m.p. and b.p. due to strong covalent bonds b/w atoms ex. diamond (C), silicon oxide (SiO2), sand

mass of proton = # of proton =

mass of neutron # of electron

Law of Conservation of Mass

matter cannot be created or destroyed. the number of atoms in the the reactants must equal the number of atoms in the products. both physical and chemical reactions follow this

separating mixtures

mixtures can be separated based on differences in physical or chemical properties

kinetic molecular theory

model that explains ideal gas behavior, 4 assumptions 1. gas particles are in continuous, random, straight-line motions 2. when particles collide, energy is transferred from particle to particle (elastic collisons) 3. gas particles have no attraction to each other (no IMF) 4. individual gas particles have no volume (negligible volume)

Gram-Formula mass

molar mass, GFM, the mass of one mol of a substance. to calculate: add together all the atomic masses of atoms in formula. measured in grams

ground state electron configuration

most stable (lowest energy) arrangement of electrons around the nucleus given on periodic table 1st shell- max 2 e-'s 2nd shell- max 8 e-'s 3rd shell- max 18 e-'s

electricity

movement of electrons

light

movement of light waves

heat

movement of particles, thermal energy

Temperature

not energy, a measure of the "AVERAGE KINETIC ENERGY" of the particles in a sample of matter. measured in degrees Celsius or Kelvins (K)

every atom/ ion has a

nuclear charge equal to the number of protons it has

charge of nucleus

number of protons

summary of trends: across a period

number of protons in nucleus increases, stronger hold/pull on electrons 1. atomic radius & metallic char. decrease 2. I.E. & E.N. increase

physical properties

observed or measured directly

valence electron shell

outermost electron shell, determines chemical properties

metals

positive nuclei surrounded by a "sea" of mobile electrons (moving charges allow for electrical conductivity). left side of staircase. Groups 1-12

2 types of energy

potential- energy of position kinetic- energy of motion

periodic law

properties of the elements are periodic (repeating) functions of their atomic NUMBERS

mass of an element

protons + neutrons

charge on ion

protons- electrons

Physical Changes between states of matter

s to L- melting/ fusion (ENDO) L to g- boiling/ evaporation (ENDO) s to g- sublimation (ENDO) g to L- condensing (EXO) L to s- freezing/ solidifying (EXO) g to s- deposition (EXO)

*Rules from polyatomic ions

same as for covalent compound - add in e-'s in - charge OR subtract e-'s if +charge -put entire ion in brackets w/ charge in upper right corner

covalent formulas (nonmetals)

share electrons

+ ions are - ions are

smaller bc they lose an electron shell bigger bc they gain an electron shell

Metalloids

staircase

STP

standard temperature and pressure, 0 Celsius (273 K), 101.3 kPa (1 atm)

nonpolar

symmetrical/ bonds b/w same atoms

subscript

tells the ratio of atoms in a substance. NEVER change these

coefficient

tells the ratio or reactants to products. change these when balancing the equation

average kinetic energy

temperature

energy

the ability to do work/ to make something happen measured in joules

mass

the amount of "stuff"(or atoms) in a substance

I.E. ionization energy

the amount of energy it takes to remove an electron from an atom in the gaseous state

degrees of polarity

the greater the difference in E.N. values of the atoms, the greater the degree of polarity

ionic character

the greater the difference in E.N. values of the atoms, the greater the ionic character of the bond

precsion

the place value a measurement is made to

stoichiometry

the study of amounts of reactants and products in chemical reactions (study of chemical recipes)

chemistry

the study of matter and energy that makes up the universe

use Table S

to look up values of I.E. & E.N.; to figure out if an element is a s, L, or g as STP (273 K); atomic radius

ionic formulas (metals + nonmetals) (polyatomic ion)

transfer electrons

gases behave most ideally

under condition of high temp and low pressure because: particles are moving faster and farther apart- less chance of gas particles attracting SUMMER

gases deviate from ideal

under conditions of low temp and high pressure because: particles are moving slowly and close together- gas particles attract each other MIDTERMS

K H D B D C M _ _ u_ _n._ _p

units of measurements K= Kilo H= Hecto D= Deca B= Base D= Deci C= Centi M= Mili u= Micro n.= Nano p= Pico

Group 17: Halogens

very active nonmetals, tend to bond with Group 1 & 2 metals, diatomic elements, 7 valence e-'s

average atomic mass

weighted average of all the naturally occuring isotopes of an element to calculate-change % to decimal x mass = products. add all products

when multiplying/dividing- rounding answers with sig figs

your answer needs to have the same # of SF as the given with the least # of SF's provided in the problem