CHE 300: Exam # 2

Mass Spectrometry

FT-IR Spectroscopy

Signal-to-Noise Ratio (S/N)

Analytical Calculations

Final Jeopardy Advanced Instrumentation & Analysis

100

This part of the mass spectrometer is responsible for turning molecules into charged particles.

Ionization source

100

The x-axis of an IR spectrum is usually labeled in these units.

wavenumbers (cm⁻¹)

100

The “signal” in signal-to-noise ratio represents this part of the measurement.

analyte response or desired peak

100

If a molecule with a molar mass of 44 g/mol produces a parent ion with a charge of +1, what is its m/z value?

100

A compound is analyzed using both FT-IR and mass spectrometry.

The FT-IR spectrum shows a strong absorption at 1715 cm⁻¹ and a broad signal near 2500–3300 cm⁻¹.
In the mass spectrum, the molecular ion peak appears at m/z = 60 with a base peak at m/z = 43.
The signal intensity for the molecular ion is 10 units and the noise level is 0.25 units.

Based on these data:

Identify the most likely compound.
Calculate the signal-to-noise ratio for the molecular ion peak.
Explain how doubling the number of scans would affect the S/N ratio.

Likely compound: Acetic acid (CH₃COOH)
- IR 1715 cm⁻¹ → C=O stretch (carboxylic acid)
- Broad 2500–3300 cm⁻¹ → O–H stretch (acidic OH)
- m/z 60 → molecular ion (M⁺ = 60)
- m/z 43 → CH₃CO⁺ fragment
S/N ratio = 10 / 0.25 = 40:1
Doubling the number of scans improves S/N by √2 → new S/N ≈ 56.6:1

200

The x-axis of a mass spectrum represents this value, which determines how ions are separated.

mass-to-charge ratio (m/z)

200

This region of the spectrum (4000–1500 cm⁻¹) is used to identify functional groups.

functional group region

200

Increasing this number of scans can improve the signal-to-noise ratio.

The number of accumulations or measurements

200

A peak is observed at m/z 88 and is doubly charged. What is the molecular weight of the compound?

176 (m/z × charge = 88 × 2)

300

In an electron impact (EI) spectrum, the peak with the highest m/z value corresponds to this ion.

molecular ion (M⁺)

300

A broad absorption around 3200–3600 cm⁻¹ typically indicates this functional group.

An –OH group?

300

The signal-to-noise ratio increases by the square root of this factor.

The number of scans (√N rule)

300

The C=O stretch in an IR spectrum appears at 1720 cm⁻¹. What is the approximate wavelength (in µm)? (Use λ = 10⁴ / ν̅)

5.81 µm

400

This type of fragmentation results when a molecule breaks into two charged fragments.

homolytic cleavage

400

The “fingerprint region” lies below this wavenumber and is unique for every compound.

1500 cm⁻¹

400

Baseline fluctuations or random electronic disturbances are examples of this.

Noise

400

An FT-IR signal has a noise level of 0.5 and a peak intensity of 10. Calculate the signal-to-noise ratio.

20:1

500

This type of analyzer separates ions by oscillating them through a quadrupole field.

quadrupole mass analyzer

500

The “FT” in FT-IR refers to this mathematical process that converts time-domain data to frequency-domain data.

Fourier Transform

500

To double the signal-to-noise ratio, you must increase the number of scans by this factor.

four (4× the scans)

500

In a mass spectrometry run, the current signal-to-noise ratio is 5:1. How many times more scans are needed to increase S/N to 20:1?

16× more scans

(since (S₂/S₁)² = N₂/N₁ → (20/5)² = 16)