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Chemistry LibreTexts

6: Chemical Reactions - Mole and Mass Relationships

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    86222

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    • 6.1: The Mole and Avogadro’s Number
      This page covers the calculation of formula masses for covalent and ionic compounds, highlighting the role of the mole and Avogadro's number in understanding substance compositions. It explains how to determine molecular and formula masses, exemplified by chloroform, aspirin, aluminum sulfate, and calcium phosphate.
    • 6.2: Gram-Mole Conversions
      This page explains conversions between mass and mole units, focusing on molar mass and its application through examples, particularly with aluminum. It highlights the significance of these conversions in chemistry and addresses dietary mineral requirements for health. Additionally, it underscores the role of minerals in neurological health and the potential risks of excessive intake from supplements, referencing the film Erin Brockovich to illustrate possible health consequences.
    • 6.3: Mole Relationships and Chemical Equations
      This page explains the interpretation of balanced chemical equations in terms of molar relationships between reactants and products, highlighting that coefficients indicate both molecule counts and molar amounts. It defines stoichiometry, illustrated by the hydrogen and oxygen reaction to produce water, and emphasizes the use of stoichiometric ratios for calculating moles in chemical reactions, concluding with an example problem for reinforcement.
    • 6.4: Mass Relationships and Chemical Equations
      This page covers stoichiometric calculations in chemistry, detailing how to convert between masses and moles using balanced equations, with examples like iron oxide and sulfur trioxide reactions. It also explains mass-mass calculations, emphasizing molar mass.
    • 6.5: Limiting Reagent and Percent Yield
      This page covers the concepts of theoretical yield, actual yield, and percent yield in chemical reactions, highlighting their importance in assessing reaction efficiency. It defines the limiting reagent as the reactant that determines maximum product formation and explains how mole-mass calculations are used to identify it.

    6: Chemical Reactions - Mole and Mass Relationships is shared under a CC BY-NC-SA 3.0 license and was authored, remixed, and/or curated by LibreTexts.