Loading [MathJax]/extensions/TeX/cancel.js
Skip to main content
Library homepage
 

Text Color

Text Size

 

Margin Size

 

Font Type

Enable Dyslexic Font
Chemistry LibreTexts

Search

  • Filter Results
  • Location
  • Classification
    • Article type
    • Stage
    • Author
    • Show Page TOC
    • Cover Page
    • License
    • Transcluded
    • Number of Print Columns
    • PrintOptions
    • OER program or Publisher
    • Student Analytics
    • Autonumber Section Headings
    • License Version
    • Print CSS
  • Include attachments
Searching in
About 13 results
  • 13.8: Water Properties
    https://chem.libretexts.org/Courses/Widener_University/CHEM_175_-_General_Chemistry_I_(Van_Bramer)/13%3A_Appendices/13.08%3A_Water_Properties
    Water Kw and pKw at Different Temperatures (°C) Standard Water Melting and Boiling Temperatures and Enthalpies of the Transitions Water Cryoscopic (Freezing Point Depression) and Ebullioscopic (Boilin...Water Kw and pKw at Different Temperatures (°C) Standard Water Melting and Boiling Temperatures and Enthalpies of the Transitions Water Cryoscopic (Freezing Point Depression) and Ebullioscopic (Boiling Point Elevation) Constants If we divide 1 by this value, we will obtain the length of the path (in cm) after which the intensity of a light beam passing through water decays by a factor of the base of the natural logarithm e (e = 2.718281828).
  • 11.7: Water Properties
    https://chem.libretexts.org/Courses/Widener_University/CHEM_145%3A_FA22_Van_Bramer/11%3A_Appendices/11.07%3A_Water_Properties
    Water Vapor Pressure at Different Temperatures (°C) Water Kw and pKw at Different Temperatures (°C) C°(H 2 O(l)) = 4184 J∙K −1 ∙kg −1 = 4.184 J∙g -1 ∙°C -1 Standard Water Melting and Boiling Temperatu...Water Vapor Pressure at Different Temperatures (°C) Water Kw and pKw at Different Temperatures (°C) C°(H 2 O(l)) = 4184 J∙K −1 ∙kg −1 = 4.184 J∙g -1 ∙°C -1 Standard Water Melting and Boiling Temperatures and Enthalpies of the Transitions If we divide 1 by this value, we will obtain the length of the path (in cm) after which the intensity of a light beam passing through water decays by a factor of the base of the natural logarithm e (e = 2.718281828).
  • 12.12: Water Properties
    https://chem.libretexts.org/Courses/Nassau_Community_College/General_Chemistry_1/12%3A_Appendices/12.12%3A_Water_Properties
    Water Vapor Pressure at Different Temperatures (°C) Water Kw and pKw at Different Temperatures (°C) C°(H 2 O(l)) = 4184 J∙K −1 ∙kg −1 = 4.184 J∙g -1 ∙°C -1 Standard Water Melting and Boiling Temperatu...Water Vapor Pressure at Different Temperatures (°C) Water Kw and pKw at Different Temperatures (°C) C°(H 2 O(l)) = 4184 J∙K −1 ∙kg −1 = 4.184 J∙g -1 ∙°C -1 Standard Water Melting and Boiling Temperatures and Enthalpies of the Transitions If we divide 1 by this value, we will obtain the length of the path (in cm) after which the intensity of a light beam passing through water decays by a factor of the base of the natural logarithm e (e = 2.718281828).
  • 11.8: Water Properties
    https://chem.libretexts.org/Courses/Widener_University/Widener_University%3A_Chem_135/11%3A_Appendices/11.08%3A_Water_Properties
    Water Kw and pKw at Different Temperatures (°C) Standard Water Melting and Boiling Temperatures and Enthalpies of the Transitions Water Cryoscopic (Freezing Point Depression) and Ebullioscopic (Boilin...Water Kw and pKw at Different Temperatures (°C) Standard Water Melting and Boiling Temperatures and Enthalpies of the Transitions Water Cryoscopic (Freezing Point Depression) and Ebullioscopic (Boiling Point Elevation) Constants If we divide 1 by this value, we will obtain the length of the path (in cm) after which the intensity of a light beam passing through water decays by a factor of the base of the natural logarithm e (e = 2.718281828).
  • 7.12: Water Properties
    https://chem.libretexts.org/Courses/Nassau_Community_College/General_Chemistry_II/07%3A_Appendices/7.12%3A_Water_Properties
    Water Vapor Pressure at Different Temperatures (°C) Water Kw and pKw at Different Temperatures (°C) C°(H 2 O(l)) = 4184 J∙K −1 ∙kg −1 = 4.184 J∙g -1 ∙°C -1 Standard Water Melting and Boiling Temperatu...Water Vapor Pressure at Different Temperatures (°C) Water Kw and pKw at Different Temperatures (°C) C°(H 2 O(l)) = 4184 J∙K −1 ∙kg −1 = 4.184 J∙g -1 ∙°C -1 Standard Water Melting and Boiling Temperatures and Enthalpies of the Transitions If we divide 1 by this value, we will obtain the length of the path (in cm) after which the intensity of a light beam passing through water decays by a factor of the base of the natural logarithm e (e = 2.718281828).
  • 22.5: Water Properties
    https://chem.libretexts.org/Courses/CSU_San_Bernardino/CHEM_2100%3A_General_Chemistry_I_(Mink)/22%3A_Appendices/22.05%3A_Water_Properties
    Table: Water Density (g/mL) at Different Temperatures (°C) Table: Water Vapor Pressure at Different Temperatures (°C) Table: Water K w and pK w at Different Temperatures (°C) Table: Standard Water Mel...Table: Water Density (g/mL) at Different Temperatures (°C) Table: Water Vapor Pressure at Different Temperatures (°C) Table: Water K w and pK w at Different Temperatures (°C) Table: Standard Water Melting and Boiling Temperatures and Enthalpies of the Transitions Absorption is reported in reciprocal meters and corresponds to the inverse of the distance light may travel through water before its intensity is diminished by 1/e (~37%).
  • 10.7: Water Properties
    https://chem.libretexts.org/Courses/Williams_School/Chemistry_I/10%3A_Appendices/10.07%3A_Water_Properties
    Water Vapor Pressure at Different Temperatures (°C) Water Kw and pKw at Different Temperatures (°C) C°(H 2 O(l)) = 4184 J∙K −1 ∙kg −1 = 4.184 J∙g -1 ∙°C -1 Standard Water Melting and Boiling Temperatu...Water Vapor Pressure at Different Temperatures (°C) Water Kw and pKw at Different Temperatures (°C) C°(H 2 O(l)) = 4184 J∙K −1 ∙kg −1 = 4.184 J∙g -1 ∙°C -1 Standard Water Melting and Boiling Temperatures and Enthalpies of the Transitions If we divide 1 by this value, we will obtain the length of the path (in cm) after which the intensity of a light beam passing through water decays by a factor of the base of the natural logarithm e (e = 2.718281828).
  • 10.5: Appendix E- Water Properties
    https://chem.libretexts.org/Courses/Smith_College/CHM_118%3A_Advanced_General_Chemistry_(Strom)/10%3A_Appendices/10.05%3A_Appendix_E-_Water_Properties
    Table E1: Water Density (g/mL) at Different Temperatures (°C) Table E2: Water Vapor Pressure at Different Temperatures (°C) Table E3: Water K w and pK w at Different Temperatures (°C) Table E5: Standa...Table E1: Water Density (g/mL) at Different Temperatures (°C) Table E2: Water Vapor Pressure at Different Temperatures (°C) Table E3: Water K w and pK w at Different Temperatures (°C) Table E5: Standard Water Melting and Boiling Temperatures and Enthalpies of the Transitions Absorption is reported in reciprocal meters and corresponds to the inverse of the distance light may travel through water before its intensity is diminished by 1/e (~37%).
  • Appendix E: Water Properties
    https://chem.libretexts.org/Bookshelves/General_Chemistry/Chemistry_2e_(OpenStax)/22%3A_Appendices/Appendix_E%3A_Water_Properties
    Table E1: Water Density (g/mL) at Different Temperatures (°C) Table E2: Water Vapor Pressure at Different Temperatures (°C) Table E3: Water K w and pK w at Different Temperatures (°C) Table E5: Standa...Table E1: Water Density (g/mL) at Different Temperatures (°C) Table E2: Water Vapor Pressure at Different Temperatures (°C) Table E3: Water K w and pK w at Different Temperatures (°C) Table E5: Standard Water Melting and Boiling Temperatures and Enthalpies of the Transitions Absorption is reported in reciprocal meters and corresponds to the inverse of the distance light may travel through water before its intensity is diminished by 1/e (~37%).
  • 7.6: Water Properties
    https://chem.libretexts.org/Courses/City_College_of_San_Francisco/Foundations_-_Review_Source_for_Chem_101A/06%3A_Appendices/7.06%3A_Water_Properties
    Water Vapor Pressure at Different Temperatures (°C) Water Kw and pKw at Different Temperatures (°C) C°(H 2 O(l)) = 4184 J∙K −1 ∙kg −1 = 4.184 J∙g -1 ∙°C -1 Standard Water Melting and Boiling Temperatu...Water Vapor Pressure at Different Temperatures (°C) Water Kw and pKw at Different Temperatures (°C) C°(H 2 O(l)) = 4184 J∙K −1 ∙kg −1 = 4.184 J∙g -1 ∙°C -1 Standard Water Melting and Boiling Temperatures and Enthalpies of the Transitions If we divide 1 by this value, we will obtain the length of the path (in cm) after which the intensity of a light beam passing through water decays by a factor of the base of the natural logarithm e (e = 2.718281828).
  • 22.5: Water Properties
    https://chem.libretexts.org/Courses/CSU_San_Bernardino/CHEM_2200%3A_General_Chemistry_II_(Mink)/22%3A_Appendices/22.05%3A_Water_Properties
    Table: Water Density (g/mL) at Different Temperatures (°C) Table: Water Vapor Pressure at Different Temperatures (°C) Table: Water K w and pK w at Different Temperatures (°C) Table: Standard Water Mel...Table: Water Density (g/mL) at Different Temperatures (°C) Table: Water Vapor Pressure at Different Temperatures (°C) Table: Water K w and pK w at Different Temperatures (°C) Table: Standard Water Melting and Boiling Temperatures and Enthalpies of the Transitions Absorption is reported in reciprocal meters and corresponds to the inverse of the distance light may travel through water before its intensity is diminished by 1/e (~37%).

Support Center

How can we help?