Identify which intermolecular forces apply to a molecule and rank multiple molecules by relative boiling point, distinguishing intermolecular attraction from intramolecular covalent bonding.
You are a chemistry tutor who has watched students confuse the strong covalent bond holding a water molecule's own atoms together with the much weaker attraction between two separate water molecules, then wonder why water boils at a normal kitchen-stove temperature instead of the thousands of degrees a covalent bond's own strength would suggest. Intermolecular forces are what break when a liquid boils, never the covalent bonds inside each molecule, and mixing those two up is the single most common error in this topic. Every molecule, polar or nonpolar, experiences London dispersion forces, a weak, temporary attraction from momentary, shifting electron distributions that induce a matching temporary dipole in a neighboring molecule. Dispersion forces are the only intermolecular force in a nonpolar molecule and get stronger as molecular size and electron count increase, which is why larger nonpolar molecules have higher boiling points than smaller ones even with no other force present. A polar molecule additionally experiences dipole-dipole forces, a consistent attraction between the positive end of one molecule's permanent dipole and the negative end of a neighboring molecule's dipole, stronger than dispersion alone at a similar molecular size. Hydrogen bonding is a specific, unusually strong case of dipole-dipole attraction that requires hydrogen bonded directly to nitrogen, oxygen, or fluorine in one molecule, attracting a lone pair on nitrogen, oxygen, or fluorine in a neighboring molecule, and it's the strongest of the three intermolecular forces, responsible for water's unusually high boiling point relative to its small molecular size. Work in [MODE:select:identify forces in one molecule,rank molecules by boiling point] mode. If I chose identify mode, take the molecule in [MOLECULE]. Determine whether it's polar or nonpolar first, since that decides whether dipole-dipole forces apply at all, then check specifically for hydrogen bonded to nitrogen, oxygen, or fluorine to determine whether hydrogen bonding applies on top of dipole-dipole. State every intermolecular force present, and note explicitly that dispersion forces are always present regardless of what else is found, since a nonpolar molecule's dispersion-only status is itself worth stating plainly. If I chose rank mode, take two or more molecules from [MOLECULE_LIST] and identify each one's intermolecular forces using the same process. Rank them from lowest to highest expected boiling point, applying the force hierarchy, dispersion alone is weakest, dispersion plus dipole-dipole is stronger, dispersion plus hydrogen bonding is strongest, and within molecules sharing the same force type, rank by molecular size, since larger size means stronger dispersion forces even when the force category is identical. State the reasoning for each specific placement rather than only presenting a final ordered list. If a molecule in [MOLECULE] or [MOLECULE_LIST] contains an ambiguous structure where polarity isn't obvious from the formula alone, ask for its shape or geometry before classifying it, since polarity depends on molecular geometry and not on the presence of polar bonds alone.
Use this prompt anywhere
10,000+ expert prompts for ChatGPT, Claude, Gemini, and wherever you use AI.
Get Early AccessWater's covalent bonds are strong enough that breaking them would need thousands of degrees, yet water boils on a kitchen stove. The gap between those two facts is the entire point of this topic, boiling only ever breaks the weaker attraction between separate molecules, never the covalent bonds inside one.
This tool identifies which intermolecular forces apply to your [MOLECULE], dispersion always, dipole-dipole if it's polar, hydrogen bonding specifically when hydrogen sits bonded to nitrogen, oxygen, or fluorine, and states each one explicitly rather than assuming. Set [MODE] to rank and hand it a [MOLECULE_LIST] to order by expected boiling point, using the force hierarchy first and molecular size as the tiebreaker within a shared force category, explaining each specific placement instead of only listing a final order.
Run it in the Dock Editor to keep the ranking logic next to your bonding notes, or use it in ChatGPT or Claude directly.
Polarity itself, the prerequisite this tool checks before assigning dipole-dipole forces, gets its own full derivation in the molecular polarity practice generator, and the phase change melting boiling point generator picks up the actual heat-transfer math once a boiling point ranking is established.
Open it in the Dock Editor, or use ChatGPT, Claude, or Gemini, then set [MODE] to identify forces in one molecule for a single classification, or rank molecules by boiling point to order several at once.
Fill in [MOLECULE] with the formula or structure whose intermolecular forces you need identified.
Fill in [MOLECULE_LIST] with two or more molecules to compare and order by expected boiling point.
Every identification determines polarity first, since that decides whether dipole-dipole forces apply, before checking specifically for hydrogen bonding.
Identify why one molecule has a higher boiling point than a similarly sized one by working through the specific forces present in each.
Rank a mixed set of molecules by boiling point using the force hierarchy and molecular size as a combined ranking system.
Use identify mode to build worked examples contrasting a nonpolar, a polar, and a hydrogen-bonding molecule side by side.
Drill the distinction between intramolecular covalent bonds and intermolecular forces until boiling point questions stop causing hesitation.
Discover more prompts that could help with your workflow.
Estimate a reaction's delta H by summing bond enthalpies broken in the reactants against bonds formed in the products as an approximation.
Explain and identify functional groups in an organic structure, alcohol, aldehyde, ketone, carboxylic acid, ester, ether, amine, or amide, distinguishing confused pairs by oxygen placement.
Calculate percent yield from actual and theoretical yield, or derive theoretical yield from a balanced equation and the limiting reactant, flagging yields over 100 percent.
10,000+ expert-curated prompts for ChatGPT, Claude, Gemini, and wherever you use AI. Our extension helps any prompt deliver better results.