Input interpretation
![creatine-phosphate | molar mass](../image_source/2c4bd45f372bf0a70fc95fffbe635835.png)
creatine-phosphate | molar mass
Result
![Find the molar mass, M, for creatine-phosphate: M = sum _iN_im_i Plan: • Write the chemical formula and gather atomic masses from the periodic table. • Determine values for N_i and m_i using these items. • Finally, compute the mass. Write the chemical formula: C_4H_10N_3O_5P_1 Use the chemical formula to count the number of atoms, N_i, for each element: | N_i C (carbon) | 4 H (hydrogen) | 12 N (nitrogen) | 3 O (oxygen) | 6 P (phosphorus) | 1 Look up the atomic mass, m_i, in g·mol^(-1) for each element in the periodic table: | N_i | m_i/g·mol^(-1) C (carbon) | 4 | 12.011 H (hydrogen) | 12 | 1.008 N (nitrogen) | 3 | 14.007 O (oxygen) | 6 | 15.999 P (phosphorus) | 1 | 30.973761998 Multiply N_i by m_i to compute the mass for each element. Then sum those values to compute the molar mass, M: Answer: | | | N_i | m_i/g·mol^(-1) | mass/g·mol^(-1) C (carbon) | 4 | 12.011 | 4 × 12.011 = 48.044 H (hydrogen) | 12 | 1.008 | 12 × 1.008 = 12.096 N (nitrogen) | 3 | 14.007 | 3 × 14.007 = 42.021 O (oxygen) | 6 | 15.999 | 6 × 15.999 = 95.994 P (phosphorus) | 1 | 30.973761998 | 1 × 30.973761998 = 30.973761998 M = 48.044 g/mol + 12.096 g/mol + 42.021 g/mol + 95.994 g/mol + 30.973761998 g/mol = 229.129 g/mol](../image_source/7eb240086b2badc4ccd3720d1a92d431.png)
Find the molar mass, M, for creatine-phosphate: M = sum _iN_im_i Plan: • Write the chemical formula and gather atomic masses from the periodic table. • Determine values for N_i and m_i using these items. • Finally, compute the mass. Write the chemical formula: C_4H_10N_3O_5P_1 Use the chemical formula to count the number of atoms, N_i, for each element: | N_i C (carbon) | 4 H (hydrogen) | 12 N (nitrogen) | 3 O (oxygen) | 6 P (phosphorus) | 1 Look up the atomic mass, m_i, in g·mol^(-1) for each element in the periodic table: | N_i | m_i/g·mol^(-1) C (carbon) | 4 | 12.011 H (hydrogen) | 12 | 1.008 N (nitrogen) | 3 | 14.007 O (oxygen) | 6 | 15.999 P (phosphorus) | 1 | 30.973761998 Multiply N_i by m_i to compute the mass for each element. Then sum those values to compute the molar mass, M: Answer: | | | N_i | m_i/g·mol^(-1) | mass/g·mol^(-1) C (carbon) | 4 | 12.011 | 4 × 12.011 = 48.044 H (hydrogen) | 12 | 1.008 | 12 × 1.008 = 12.096 N (nitrogen) | 3 | 14.007 | 3 × 14.007 = 42.021 O (oxygen) | 6 | 15.999 | 6 × 15.999 = 95.994 P (phosphorus) | 1 | 30.973761998 | 1 × 30.973761998 = 30.973761998 M = 48.044 g/mol + 12.096 g/mol + 42.021 g/mol + 95.994 g/mol + 30.973761998 g/mol = 229.129 g/mol
Unit conversion
![0.22913 kg/mol (kilograms per mole)](../image_source/fcd0761c4b63d5fd38ca5f4df70bbcfa.png)
0.22913 kg/mol (kilograms per mole)
Comparisons
![≈ 0.32 × molar mass of fullerene ( ≈ 721 g/mol )](../image_source/70e4e084c1f6d8c8aa896270ec468d30.png)
≈ 0.32 × molar mass of fullerene ( ≈ 721 g/mol )
![≈ 1.2 × molar mass of caffeine ( ≈ 194 g/mol )](../image_source/bb6eeab5266a29e0265fafc9b8be2596.png)
≈ 1.2 × molar mass of caffeine ( ≈ 194 g/mol )
![≈ 3.9 × molar mass of sodium chloride ( ≈ 58 g/mol )](../image_source/0572efb2212a6bb2ea8075bc6a9f6d45.png)
≈ 3.9 × molar mass of sodium chloride ( ≈ 58 g/mol )
Corresponding quantities
![Mass of a molecule m from m = M/N_A: | 3.8×10^-22 grams | 3.8×10^-25 kg (kilograms) | 229 u (unified atomic mass units) | 229 Da (daltons)](../image_source/d4378f6a0bb5db4f8b63d8687beb55d8.png)
Mass of a molecule m from m = M/N_A: | 3.8×10^-22 grams | 3.8×10^-25 kg (kilograms) | 229 u (unified atomic mass units) | 229 Da (daltons)
![Relative molecular mass M_r from M_r = M_u/M: | 229](../image_source/4d83a8d933a5ba858a7c8dd3a15cfe96.png)
Relative molecular mass M_r from M_r = M_u/M: | 229