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SKILL·9F13E4

interpret-uv-vis-spectrum

pjt222
업데이트됨 1 month ago
8 조회
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정보

이 스킬은 Claude가 UV-Vis 흡수 스펙트럼 데이터를 체계적으로 해석할 수 있게 합니다. 발색단을 식별하고, 전자 전이를 분류하며, 공액 시스템에 대한 Woodward-Fieser 규칙을 적용하고, Beer-Lambert 법칙을 사용한 정량 분석을 수행합니다. 분자 구조나 농도를 결정하기 위해 스펙트럼 데이터를 분석해야 할 때 사용하세요.

빠른 설치

Claude Code

추천
기본
npx skills add pjt222/agent-almanac -a claude-code
플러그인 명령대체
/plugin add https://github.com/pjt222/agent-almanac
Git 클론대체
git clone https://github.com/pjt222/agent-almanac.git ~/.claude/skills/interpret-uv-vis-spectrum

Claude Code에서 이 명령을 복사하여 붙여넣어 스킬을 설치하세요

문서

Interpret UV-Vis Spectrum

Read UV-visible absorption spectra. Identify chromophores. Classify electronic transitions. Predict absorption maxima for conjugated systems. Apply Beer-Lambert law for quantitative determination.

When Use

  • Identify chromophores and extent of conjugation in organic compound
  • Confirm presence of aromatic rings, conjugated dienes, enones
  • Quantitative analysis (determine concentration from absorbance)
  • Monitor reaction kinetics by tracking absorbance changes over time
  • Characterize metal-ligand complexes via d-d and charge-transfer transitions
  • Assess solvent effects on electronic transitions (solvatochromism)

Inputs

  • Required: UV-Vis spectrum data (wavelength in nm vs. absorbance or molar absorptivity)
  • Required: Solvent used for measurement
  • Optional: Concentration and path length (for Beer-Lambert calculations)
  • Optional: Molar absorptivity (epsilon) values at lambda-max
  • Optional: Spectra in multiple solvents (for solvatochromism analysis)
  • Optional: Structural info from other spectroscopic methods

Steps

Step 1: Verify Instrument Parameters and Spectrum Quality

Ensure data reliable before interpreting absorption bands:

  1. Wavelength range: Confirm spectrum covers relevant range. Standard UV-Vis spans 190-800 nm. Solvents impose low-wavelength cutoffs:
SolventUV Cutoff (nm)Notes
Water190Excellent UV transparency
Hexane195Non-polar, minimal solvent effects
Methanol205Protic, may cause blue shifts
Acetonitrile190Good general-purpose UV solvent
Dichloromethane230Absorbs below 230 nm
Chloroform245Absorbs below 245 nm
Acetone330Absorbs strongly, poor UV solvent
  1. Absorbance range: Reliable measurements need absorbance between 0.1 and 1.0. Below 0.1 = noise dominates. Above 1.0 = stray light causes non-linear response. Flag any lambda-max values outside this range
  2. Baseline and blank: Verify solvent blank subtracted. Residual solvent absorption or cuvette artifacts = rising baseline at short wavelengths
  3. Slit width: Narrow slit widths give better resolution but lower signal-to-noise. Fine structure expected (vibrational progression on electronic bands)? Confirm slit width appropriate (typically 1-2 nm)

Got: Instrument parameters documented. Solvent cutoff respected. Absorbance values within linear range. Baseline confirmed clean.

If fail: Absorbance exceeds 1.0 at lambda-max? Sample must be diluted and remeasured. Solvent absorbs in region of interest? Recommend re-acquisition in more transparent solvent.

Step 2: Identify Lambda-Max and Band Characteristics

Locate and characterize all absorption bands:

  1. Locate lambda-max values: Identify each absorption maximum (lambda-max). Record wavelength (nm) and absorbance (or molar absorptivity epsilon if known)
  2. Measure band shape: Note whether each band broad and featureless (typical of solution-phase electronic transitions) or shows vibrational fine structure (typical of rigid chromophores like polycyclic aromatics)
  3. Record shoulders: Absorption shoulders = overlapping transitions. Note approximate wavelength and intensity
  4. Classify by molar absorptivity:
epsilon (L mol-1 cm-1)Transition TypeExample
< 100Forbidden (n -> pi*)Ketone ~280 nm
100--10,000Weakly allowedAromatic 250--270 nm
10,000--100,000Fully allowed (pi -> pi*)Conjugated diene ~220 nm
> 100,000Charge transferMetal complexes, dyes

Got: All absorption maxima and shoulders tabulated with wavelength, absorbance/epsilon, qualitative band shape.

If fail: Spectrum shows no distinct maxima (monotonic rise)? Compound may lack chromophore in measured range, or concentration too low. Increase concentration or extend wavelength range.

Step 3: Classify Electronic Transitions

Assign each absorption band to specific electronic transition type:

  1. sigma -> sigma transitions* (< 200 nm): Observed only in vacuum UV. Relevant for saturated hydrocarbons and C-C/C-H bonds. Not typically measured in standard UV-Vis
  2. n -> sigma transitions* (150-250 nm): Lone pair to sigma antibonding. Observed for heteroatoms (O, N, S, halogens). Saturated amines absorb near 190-200 nm. Alcohols/ethers near 175-185 nm
  3. pi -> pi transitions* (200-500 nm): Bonding pi to antibonding pi*. Strongest absorptions for organic compounds. Intensity and wavelength increase with extended conjugation
  4. n -> pi transitions* (250-400 nm): Lone pair to pi antibonding. Formally forbidden (low epsilon, typically 10-100). Characteristic of C=O (270-280 nm for simple ketones), N=O, C=S groups
  5. Charge-transfer transitions: Electron transfer between donor and acceptor groups, or between metal and ligand. Typically very intense (epsilon > 10,000) and broad. Found in metal complexes and donor-acceptor organic molecules
  6. d-d transitions (for transition metal complexes): Weak, broad bands in visible region from crystal field or ligand field splitting

Got: Each absorption band assigned to transition type with supporting rationale (position, intensity, solvent sensitivity).

If fail: Band cannot be assigned to standard transition type? Consider charge-transfer character or possibility of impurity absorption. Multiple overlapping transitions may need deconvolution.

Step 4: Apply Woodward-Fieser Rules for Conjugated Systems

Predict lambda-max for conjugated dienes and enones. Compare with observed values:

  1. Conjugated dienes (Woodward rules):
ComponentIncrement (nm)
Base value (heteroannular diene)214
Base value (homoannular diene)253
Each additional conjugated C=C+30
Each exocyclic C=C+5
Each alkyl substituent on C=C+5
-OAcyl substituent+0
-OR substituent+6
-SR substituent+30
-Cl, -Br substituent+5
-NR2 substituent+5
  1. Alpha-beta unsaturated carbonyls (Woodward-Fieser rules):
ComponentIncrement (nm)
Base value (alpha-beta unsat. ketone, 6-ring or acyclic)215
Base value (alpha-beta unsat. aldehyde)208
Each additional conjugated C=C+30
Each exocyclic C=C+5
Homoannular diene component+39
Alpha substituent (alkyl)+10
Beta substituent (alkyl)+12
Gamma and higher substituent (alkyl)+18
-OH (alpha)+35
-OH (beta)+30
-OAc (alpha, beta, gamma)+6
-OR (alpha)+35
-OR (beta)+30
-Cl (alpha)+15
-Cl (beta)+12
-Br (beta)+25
-NR2 (beta)+95
  1. Calculate predicted lambda-max: Sum base value and all applicable increments
  2. Compare with observed: Agreement within +/- 5 nm supports proposed chromophore. Deviations > 10 nm = incorrect structural assignment or strong solvent/steric effects

Got: Predicted lambda-max calculated and compared with observed value, supporting or refuting proposed chromophore structure.

If fail: Predicted and observed values disagree significantly? Re-examine assumed chromophore structure. Common errors: miscounting substituents, overlooking exocyclic double bond, applying wrong base value (homoannular vs. heteroannular).

Step 5: Apply Beer-Lambert Law for Quantitative Analysis

Use absorbance data for concentration determination or molar absorptivity characterization:

  1. Beer-Lambert equation: A = epsilon * b * c, where A = absorbance (dimensionless), epsilon = molar absorptivity (L mol-1 cm-1), b = path length (cm), c = concentration (mol L-1)
  2. Determine molar absorptivity: Concentration and path length known? Calculate epsilon from measured absorbance at lambda-max
  3. Determine concentration: epsilon known (from literature or calibration curve)? Calculate concentration from measured absorbance
  4. Check linearity: Beer-Lambert law valid only in linear range (typically A = 0.1-1.0). At higher absorbances, deviations from stray light, molecular interactions, instrumental limitations
  5. Assess solvent effects: Compare spectra in polar vs. non-polar solvents:
    • Bathochromic (red) shift: lambda-max moves to longer wavelength. pi -> pi* transitions red-shift in more polar solvents. n -> pi* transitions red-shift in less polar solvents
    • Hypsochromic (blue) shift: lambda-max moves to shorter wavelength. n -> pi* transitions blue-shift in more polar/protic solvents (hydrogen bonding stabilizes lone pair ground state)
    • Hyperchromic/hypochromic effects: Increase or decrease in epsilon without wavelength change

Got: Quantitative results calculated with appropriate significant figures. Linearity verified. Solvent effects documented if spectra in multiple solvents available.

If fail: Beer-Lambert linearity fails? Check for sample degradation, aggregation at high concentration, fluorescence interference. Dilute sample and remeasure to confirm.

Checks

  • Solvent cutoff respected and absorbance within linear range (0.1-1.0)
  • All lambda-max values and shoulders tabulated with wavelength, absorbance, epsilon
  • Each absorption band assigned to electronic transition type
  • Woodward-Fieser calculation performed where applicable and compared with observed lambda-max
  • Beer-Lambert law applied correctly with verified linearity
  • Solvent effects characterized if multi-solvent data available
  • Chromophore assignment consistent with molecular structure from other spectroscopic methods

Pitfalls

  • Measure above A = 1.0: High absorbance values unreliable due to stray light effects. Always dilute and remeasure if lambda-max absorbance exceeds 1.0.
  • Ignore solvent cutoff: Interpreting absorptions below solvent cutoff wavelength makes artifacts, not real sample data.
  • Confuse transition types by intensity alone: Weak band near 280 nm could be n -> pi* transition of carbonyl or forbidden pi -> pi* of aromatic. Context and solvent effects needed to distinguish them.
  • Misapply Woodward-Fieser rules: Empirical rules apply only to conjugated dienes and alpha-beta unsaturated carbonyls. Cannot be used for aromatic systems, isolated chromophores, metal complexes.
  • Neglect impurity absorption: Even small amounts of strongly absorbing impurity can dominate spectrum. lambda-max not matching expectations? Consider impurity contributions.
  • Assume one band = one transition: Broad UV-Vis bands often contain multiple overlapping transitions. Band deconvolution may be needed for accurate assignment.

See Also

  • interpret-nmr-spectrum — determine molecular connectivity to support chromophore identification
  • interpret-ir-spectrum — identify functional groups contributing to chromophore
  • interpret-mass-spectrum — establish molecular formula and detect conjugation via fragmentation
  • interpret-raman-spectrum — complementary vibrational data for symmetric chromophores
  • plan-spectroscopic-analysis — select and sequence spectroscopic techniques before data acquisition

GitHub 저장소

pjt222/agent-almanac
경로: i18n/caveman/skills/interpret-uv-vis-spectrum
0
agentsagentskillsai-assisted-developmentclaude-codeskillsteams
FAQ

Frequently asked questions

What is the interpret-uv-vis-spectrum skill?

interpret-uv-vis-spectrum is a Claude Skill by pjt222. Skills package instructions and resources that Claude loads on demand, so Claude can perform interpret-uv-vis-spectrum-related tasks without extra prompting.

How do I install interpret-uv-vis-spectrum?

Use the install commands on this page: add interpret-uv-vis-spectrum to Claude Code as a plugin, or clone its repository into your skills directory, then restart Claude so it picks up the skill.

What category does interpret-uv-vis-spectrum belong to?

interpret-uv-vis-spectrum is in the Other category, tagged general.

Is interpret-uv-vis-spectrum free to use?

Yes. interpret-uv-vis-spectrum is listed on AIMCP and free to install. It runs inside Claude, so no separate service account is required to use the skill itself.

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