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2: Experiments

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    • 2.1: Measurements in the Laboratory (Experiment)-Home Version
      All measuring devices are subject to error, making it impossible to obtain exact measurements. Students will record all the digits of the measurement using the markings that we know exactly and one further digit that we estimate and call uncertain. The uncertain digit is our best estimate using the smallest unit of measurement given and estimating between two of these values. These digits are collectively referred to as significant figures.
    • 2.2: The Density of Liquids and Solids (Experiment)-Home Version
      OBJECTIVES To determine the density of pure water; To determine the density of aluminum (applying the technique of water displacement) and to use this value to determine the thickness of a piece of aluminum foil; To measure the mass and volume (via measured dimensions) of several cylinders of an unknown material, and to determine the density of this material via graphical analysis of the collected data.
    • 2.3: Paper Chromatography of Washable-marker Ink Pens (Experiment)-Home Version
      Chromatography is a method of physically separating mixtures into its individual components and is used to identify unknown components in mixtures. There are several types of chromatography; all types employ a mobile phase or eluent (liquid or gas), which is forced through a stationary phase (a solid or semi-solid). Mixtures are separated because some components will be more attracted to the stationary phase while some components will be more attracted to the mobile phase.
    • 2.4: Chemical Nomenclature (Experiment)
      Ionic compounds are composed of ions. An ion is an atom or molecule with an electrical charge. Monatomic ions are formed from single atoms that have gained or lost electrons. Polyatomic ions are formed from molecules that have gained or lost electrons. Negative ions are called anions, and are formed when an atom or molecule gains electrons. All non- metals form negatively charged ions. Positive ions are called cations, and are formed when an species loses electrons.
    • 2.5: Explore and Identify the Types of Chemical Reactions around You-Home
      This experiment is to explore the five different basic reaction types. Most of the experiments are conducted using house-hold items. For double-displacement reactions, the net ionic products are to be identified, and the balanced equations along with ionic and net-ionic equations are to be written.
    • 2.6: Mole Ratios and Limiting Reactant-Home
      This wet lab experiment is to calculate the moles of reagents used in a reaction. This experiment is a derivation of the data collected in Part B of the Gas Law lab in this manual. If you have already completed the Gas Law lab transfer the data from Part B to this experiment's report sheet. If this experiment is done first, use the report sheet from this experiment for Part B of the Gas Law Lab. The mole ratios are compared with the stoichiometric ratio to find the limiting and excess reactants.
    • 2.7: Gas Laws-Simulations and Wet Lab-Home
      Both simulation and wet lab experiments are conducted to find the correlation between various gas parameters. The relation between dependent and independent variables are explored with other contributing parameters held constant. Graphical analysis and practice problems are also included.
    • 2.8: Heat of a Reaction and Coffee Cup Calorimeter-Home
      The objective of this lab is to use coffee-cup colorimeter to measure the heat exchanged during aqueous reactions. A number of practice-problems based on the concepts are also provided.
    • 2.9: Flame Tests and Atomic Spectra (Experiment)-Home Version
      The objectives of this lab are to: Watch a flame tests of metal cations video in order to observe their characteristic colors, Perform calculations to determine the frequency and energy of the emitted photons. Relate these results to the types of electronic transitions occurring in these elements. Observe and understand line emission spectra of atoms using gas-discharge tubes. Practice writing electron configurations for these (and other) elements.
    • 2.10: Lewis Structures and Molecular Shapes (Experiment)-Simulation-Home Version
      Non-metal atoms bond covalently, resulting in the formation of either neutral molecules or polyatomic ions. A covalent bond is formed when non-metal atoms share their valence electrons, which they do in order to achieve filled valence orbitals like their nearest noble gas neighbor. This means that most bonded non-metal atoms will acquire a total of eight valence electrons via the sharing process – often referred to as the octet rule.

    2: Experiments is shared under a not declared license and was authored, remixed, and/or curated by LibreTexts.

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