Is density qualitative or quantitative poetry? ANSWER PLEASE.

How many atoms in the pictured molecule can form hydrogen bonds with water molecules?

ddd [48]

Answer:

3

Explanation:

Please, find the image with the pictured molecule for this question attached.

The molecule has one oxygen atom (red) covalently bonded to one hydrogen atom (light grey), one nitrogen atom (blue) covalently bonded to two hydrogen atoms (light grey), and two carbon atoms (dark grey) bonded each to two hydrogen atoms (light grey).

Hydrogen bondings are intermolecular bonds (bonds between atoms of two different molecules not between atoms of the same molecule). The hydrogen bonds are attractions between the positive end of one hydrogen atom and the negative end of a small atom of other molecule (N, O, or F).

Since, nitrogen and oxygen are much more electronegative than hydrogen atoms, you conclude that:

The two hydrogen atoms covalently bonded to the nitrogen atoms have considerably partial positive charge.

The hydrogen atom covalently bonded to the oxygen atom also has a a relative large partial positive charge.

So, those are three ends of the molecule that can form hydrogen bonds with water molecules.

The hydrogen bondings are only possible when hydrogen is covalently bonded to N, O or F atoms.

4 0

3 years ago

The O2 produced from the decomposition of the 1.0 L sample of H2O2 is collected in a previously evacuated 10.0 L flask at 300. K

Sergio [31]

The full question can be seen below:

$2H_{2}O_2_{(aq)} --> 2H_{2}O_{(l)}+O_{2}_{g}$

The decomposition of $H_{2}O_{aq}$ is represented by the equation above.

A student monitored the decomposition of a 1.0 L sample of $H_{2}O_2_(_{aq}_)$ at a constant temperature of 300K and recorded the concentration of $H_{2}O_2$ as function of time. The results are given in the table below:

Time (s) $H_{2}O_2$

0 2.7

200 2.1

400 1.7

600 1.4

The $O_2_(_{g}_)$ produced from the decomposition of the 1.0 L sample of $H_{2}O_2_(_{aq}_)$ is collected in a previously evacuated 10.0 L flask at 300 K. What is the approximate pressure in the flask after 400 s?

(For estimation purpose, assume that 1.0 mole of gas in 1.0 L exerts a pressure of 24 atm at 300 K).

Answer:

1.2 atm

Explanation:

Considering all assumptions as stated above;

$2H_{2}O_2_{(aq)} --> 2H_{2}O_{(l)}+O_{2}_{g}$

Initial 2.7 mole --- ---

Change -1.0 --- $+\frac{1.0}{2}$

Equilibrium 1.7 mole --- 0.5 mole

To determine the concentration of O₂; we need to convert the moles to concentration for O₂ = $\frac{0.5}{volume in the flask}$

= $\frac{0.5 mol}{10.0 L}$

= 0.05 $\frac{mol}{L}$

Thus, based on the assumption that "1.0 mole of gas in 1.0 L exerts a pressure of 24 atm"

∴ 0.05 $\frac{mol}{L}$ will give rise to = 0.05 $\frac{mol}{L}$ × 24

= 1.2 atm

7 0

3 years ago

Reaction between iodine solution and polysaccharides

Radda [10]

Explanation:

7 4th CNN to CNN u 4th f7 4th d7 hmm

8 0

2 years ago

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Science question: Could you have seasons without revolution? Why or why not?

marusya05 [52]

Answer:

No

Explanation:

The Earth would not have seasons if there is no revolution because the temperatures would not change.

4 0

3 years ago

Indicate the types of forces that are involved between the solute and solvent when forming a homogeneous solution between CH3CH2

Sliva [168]

Answer:

London dispersion forces

Explanation:

Intermolecular forces are the forces that facilitate interaction between solute and solvent molecules and thereby impact their solubility. These forces are broadly classified into four types arranged below from the strongest to the weakest:

1) Ionic > 2) Hydrogen bonding >3) Dipole-dipole >4) London dispersion

The hydrocarbons n-pentane $CH_{3}CH_{2}CH_{2}CH_{2}CH_{3}$ and n--hexane $CH_{3}CH_{2}CH_{2}CH_{2}CH_{2}CH_{3}$ are non-polar molecules. Therefore the only type of interaction that exists between them when forming a homogeneous solution are the weak london dispersion forces.

4 0

3 years ago

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