Analyze mass spectra from any common ionization method to determine the molecular ion, molecular formula, fragmentation pathways, and structural features of the analyte.
使用タイミング
Determining the molecular weight and formula of an unknown compound
Confirming the identity of a synthetic product by molecular ion and fragmentation
Identifying impurities or degradation products in a sample
Proposing structural features from characteristic fragmentation losses
Analyzing isotope patterns to detect halogens, sulfur, or metals
入力
必須: Mass spectrum data (m/z values with relative intensities, at minimum the full scan spectrum)
必須: Ionization method used (EI, ESI, MALDI, CI, APCI, APPI)
任意: High-resolution mass data (exact mass, measured vs. calculated)
任意: Molecular formula from other sources (elemental analysis, NMR)
Skills relacionados
任意: Tandem MS/MS data (fragmentation of selected precursor ions)
任意: Chromatographic context (LC-MS or GC-MS retention time, purity)
手順
ステップ1: Identify Ionization Method and Expected Ion Types
Determine what species the spectrum contains before assigning peaks:
Check for adducts and clusters: Soft ionization often produces [M+Na]+ (M+23), [M+K]+ (M+39), [2M+H]+, and [2M+Na]+ in addition to [M+H]+. Identify these before assigning the molecular ion.
Identify multiply charged ions: In ESI, multiply charged ions appear at m/z = (M + nH) / n. Look for peaks separated by fractional m/z values (e.g., 0.5 Da spacing indicates z=2).
期待結果: Ionization method documented, expected ion types listed, and adducts/clusters identified so the true molecular ion can be determined.
失敗時: If the ionization method is unknown, examine the spectrum for clues: extensive fragmentation suggests EI, adduct patterns suggest ESI, and matrix peaks suggest MALDI. Consult the instrument log if available.
ステップ2: Determine Molecular Ion and Molecular Formula
Identify the molecular ion peak and derive the molecular formula:
Locate the molecular ion (M): In EI, M+. is the highest m/z peak with a reasonable isotope pattern (it may be weak or absent for labile compounds). In soft ionization, identify [M+H]+ or [M+Na]+ and subtract the adduct to get M.
Apply the nitrogen rule: An odd molecular weight indicates an odd number of nitrogen atoms. An even molecular weight indicates zero or an even number of nitrogen atoms.
Calculate degrees of unsaturation (DBE): DBE = (2C + 2 + N - H - X) / 2, where X = halogens. Each ring or pi bond contributes one DBE. Benzene = 4 DBE, carbonyl = 1 DBE.
Use high-resolution data: If exact mass is available, calculate the molecular formula using the mass defect. Compare the measured mass with all candidate formulas within the mass accuracy window (typically < 5 ppm for modern instruments).
Cross-check with isotope pattern: The observed isotope pattern must match the proposed molecular formula (see Step 3).
期待結果: Molecular ion identified, molecular weight determined, nitrogen rule applied, and a molecular formula proposed (confirmed by HRMS if available).
失敗時: If no molecular ion is visible in EI (common for thermally labile or highly branched compounds), try a softer ionization method. If the molecular ion is ambiguous, check for loss of common small fragments from the highest m/z peak (e.g., M-1, M-15, M-18 can help identify M).
ステップ3: Analyze Isotope Patterns
Use isotopic signatures to detect specific elements:
Monoisotopic elements: H, C, N, O, F, P, I have characteristic natural abundance patterns. For molecules containing only C, H, N, O, the M+1 peak is approximately 1.1% per carbon.
Halogen patterns:
Element
Isotopes
M : M+2 Ratio
Visual Pattern
35Cl / 37Cl
35, 37
3 : 1
Doublet, 2 Da apart
79Br / 81Br
79, 81
1 : 1
Equal doublet, 2 Da apart
2 Cl
--
9 : 6 : 1
Triplet
2 Br
--
1 : 2 : 1
Triplet
1 Cl + 1 Br
--
3 : 4 : 1
Characteristic quartet-like
Sulfur detection: 34S contributes 4.4% at M+2. An M+2 peak of approximately 4--5% relative to M (after correcting for the contribution of 13C2) suggests one sulfur atom.
Silicon detection: 29Si (5.1%) and 30Si (3.4%) produce distinctive M+1 and M+2 contributions.
Compare with calculated patterns: Use the proposed molecular formula to calculate the theoretical isotope pattern. Overlay with the observed pattern to confirm or refute the formula.
期待結果: Isotope pattern analyzed, presence or absence of Cl, Br, S, Si determined, and pattern consistent with the proposed molecular formula.
失敗時: If isotope resolution is insufficient (low-resolution instrument), the M+2 pattern may be unresolvable. Note the limitation and rely on exact mass and other spectroscopic data for elemental composition.
ステップ4: Identify Fragmentation Losses and Key Fragment Ions
Map the fragmentation pathways to extract structural information:
Catalog major fragments: List all peaks above 5--10% relative intensity with their m/z values.
Calculate neutral losses from the molecular ion:
Loss (Da)
Neutral Lost
Structural Implication
1
H.
Labile hydrogen
15
CH3.
Methyl group
17
OH.
Hydroxyl
18
H2O
Alcohol, carboxylic acid
27
HCN
Nitrogen heterocycle, amine
28
CO or C2H4
Carbonyl or ethyl
29
CHO. or C2H5.
Aldehyde or ethyl
31
OCH3. or CH2OH.
Methoxy or hydroxymethyl
32
CH3OH
Methyl ester
35/36
Cl./HCl
Chlorinated compound
44
CO2
Carboxylic acid, ester
45
OC2H5.
Ethoxy
46
NO2.
Nitro compound
Identify characteristic fragment ions:
m/z
Ion
Origin
77
C6H5+
Phenyl cation
91
C7H7+
Tropylium (benzyl rearrangement)
105
C6H5CO+
Benzoyl cation
43
CH3CO+ or C3H7+
Acetyl or propyl
57
C4H9+ or C3H5O+
tert-Butyl or acrolein
149
Phthalate fragment
Plasticizer contaminant
Map fragmentation pathways: Connect fragment ions by successive losses to build a fragmentation tree from M down to low-mass fragments.
Identify rearrangement ions: McLafferty rearrangement (gamma-hydrogen transfer with beta-cleavage) produces even-electron ions from carbonyl-containing compounds. Retro-Diels-Alder fragmentation is characteristic of cyclohexene systems.
期待結果: All major fragment ions assigned, neutral losses calculated and correlated with structural features, fragmentation tree constructed.
失敗時: If fragments do not correspond to simple losses from the molecular ion, consider rearrangement processes. Unassigned fragments may indicate unexpected functional groups, impurities, or matrix/background peaks.
ステップ5: Assess Purity and Propose Structure
Evaluate the overall spectrum for purity indicators and assemble a structural proposal:
Purity check: In GC-MS or LC-MS, examine the chromatogram for additional peaks. In direct-infusion MS, look for unexpected ions that are not fragments of or adducts with the main analyte.
Background and contaminant peaks: Common contaminants include phthalate plasticizers (m/z 149, 167, 279), column bleed (siloxanes at m/z 207, 281, 355, 429 in GC-MS), and solvent clusters.
Structural proposal: Combine the molecular formula (Step 2), isotope pattern (Step 3), and fragmentation (Step 4) to propose a structure or a set of candidate structures.
Rank candidates: Use the fragmentation tree to rank structural candidates. The best structure explains the most fragment ions with the fewest ad hoc assumptions.
Cross-validate: Compare the proposed structure with data from other techniques (NMR, IR, UV-Vis). The mass spectrum alone rarely provides an unambiguous structure for novel compounds.
期待結果: Purity assessed, contaminants identified if present, and a structural proposal (or ranked candidate list) consistent with all MS data and cross-validated where possible.
失敗時: If the spectrum appears to contain multiple components and chromatographic separation was not used, flag the mixture and recommend LC-MS or GC-MS reanalysis. If no satisfactory structural proposal emerges, identify which additional data (HRMS, MS/MS, NMR) would resolve the ambiguity.
バリデーション
Ionization method identified and expected ion types documented
Molecular ion located and distinguished from adducts, fragments, and clusters
Nitrogen rule applied and consistent with proposed formula
Degrees of unsaturation calculated and accounted for in the structure
Isotope pattern matches the proposed molecular formula
Major fragment ions assigned with neutral losses and structural rationale
Fragmentation tree constructed from molecular ion to low-mass fragments
Common contaminant and background peaks identified and excluded
Structural proposal cross-validated with other spectroscopic data
よくある落とし穴
Misidentifying the molecular ion: In EI, the base peak is often a fragment, not the molecular ion. The molecular ion is the highest m/z peak with a chemically reasonable isotope pattern. Adduct ions in ESI ([M+Na]+, [2M+H]+) can also be mistaken for the molecular ion.
Ignoring the nitrogen rule: An odd-mass molecular ion requires an odd number of nitrogens. Forgetting this leads to impossible molecular formulas.
Confusing isobaric losses: A loss of 28 Da could be CO or C2H4; a loss of 29 could be CHO or C2H5. High-resolution MS or additional fragmentation data is needed to distinguish isobaric losses.
Neglecting multiply charged ions: In ESI, doubly or triply charged ions appear at half or one-third the expected m/z. Look for non-integer spacing between isotope peaks as a diagnostic for multiple charges.
Over-interpreting low-abundance peaks: Peaks below 1--2% relative intensity may be noise, isotope contributions, or minor contaminants rather than meaningful fragments.
Assuming a pure sample: Many real-world spectra are mixtures. Always check chromatographic purity and look for ions inconsistent with the proposed structure.
関連スキル
interpret-nmr-spectrum -- determine connectivity and hydrogen environments for structural confirmation
interpret-ir-spectrum -- identify functional groups that explain observed fragmentation
interpret-uv-vis-spectrum -- characterize chromophores in the analyte