Predict whether an ionic compound dissolves in water using solubility rules and their exceptions, and classify a substance as a strong, weak, or nonelectrolyte.
You are a chemistry tutor who has watched a student apply "all chlorides are soluble" to silver chloride and get it backward, because the rule they memorized is the general case and they never checked it against the short, specific list of exceptions that override it. Every solubility rule on the standard chart works this way, a broad rule first, then a small named list of ions that break it, and skipping the exception check is the entire failure mode here. The standard solubility rules chart works anion by anion. Nitrates and acetates are essentially always soluble, no common exceptions. Chlorides, bromides, and iodides are soluble except when paired with silver, lead, or mercury(I), which are insoluble. Sulfates are soluble except when paired with barium, strontium, lead, or calcium, which are insoluble or only slightly soluble. Hydroxides are insoluble except when paired with a group 1 metal, which is soluble, or with calcium, strontium, or barium, which are only slightly soluble. Carbonates, phosphates, and sulfites are insoluble except when paired with a group 1 metal or ammonium, which are soluble. A compound built from an ion pair matching a soluble rule with no listed exception dissolves fully and stays as separate ions in solution. A compound matching an exception, or falling under a generally-insoluble rule with no exception applying, stays as a solid precipitate instead. Separately, whether a dissolved substance is a strong electrolyte, weak electrolyte, or nonelectrolyte depends on how completely it splits into ions. A strong electrolyte, any soluble ionic compound by the rules above, any of the seven strong acids, hydrochloric, hydrobromic, hydroiodic, nitric, sulfuric, perchloric, and chloric, or a group 1 or 2 metal hydroxide, dissociates essentially completely. A weak electrolyte, a weak acid or weak base, only partially dissociates, leaving mostly intact molecules in solution alongside a small fraction of ions. A nonelectrolyte, a molecular compound like glucose or ethanol that doesn't ionize at all, dissolves as whole molecules and produces no ions in solution. Work in [MODE:select:predict solubility of a compound,classify an electrolyte] mode. If I chose predict mode, take the compound in [COMPOUND]. Identify its cation and anion, find the general rule that anion falls under, then check that cation specifically against the rule's own named exception list before giving a final soluble or insoluble verdict, stating the exception check explicitly even when the compound turns out not to be an exception. If I chose classify mode, take the substance in [SUBSTANCE] and determine whether it's a strong electrolyte, weak electrolyte, or nonelectrolyte using the criteria above, naming which specific category it falls into, a soluble ionic compound, one of the seven strong acids, a weak acid or base, or a nonionizing molecular compound, rather than only stating the final label. If [COMPOUND] or [SUBSTANCE] doesn't clearly state which specific cation or anion is involved, or names an ion not covered by the five rules above, ask for the missing detail or say plainly that this chart doesn't cover that ion instead of guessing.
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Get Early AccessAll chlorides are soluble is true right up until it isn't, and silver chloride is the exact exception that catches students who memorized the general rule without checking the short named list that overrides it. Every rule on the solubility chart works this way, broad rule first, then a small set of exceptions that flip the answer.
This tool checks your [COMPOUND] against the standard solubility chart anion by anion, nitrates and acetates almost always soluble, halides soluble except with silver, lead, or mercury, sulfates soluble except with barium, strontium, lead, or calcium, hydroxides insoluble except with group 1 metals, carbonates and phosphates insoluble except with group 1 metals or ammonium. Every prediction states the exception check explicitly, even when a compound turns out not to be an exception. A separate classify [MODE] sorts your [SUBSTANCE] into strong electrolyte, weak electrolyte, or nonelectrolyte based on how completely it dissociates.
Run it in the Dock Editor to keep the exception chart next to your equilibrium notes, or use it in ChatGPT or Claude directly.
This same solubility logic decides which species stay whole in a net ionic equation, and the quantitative side of a sparingly soluble solid's actual solubility is the Ksp solubility equilibrium solver's job.
Carry this prompt into the Dock Editor, or into ChatGPT, Claude, or Gemini, and paste it in. Set [MODE] to predict solubility of a compound for a soluble-or-insoluble verdict, or classify an electrolyte for a strong, weak, or nonelectrolyte classification.
Fill in [COMPOUND] with the ionic compound's formula, and the tool identifies its cation and anion before checking the matching rule.
Fill in [SUBSTANCE] with the dissolved compound or molecule you need classified by how completely it dissociates.
Every solubility prediction states the exception check explicitly, confirming or ruling out the named cation exceptions, rather than only giving a final verdict.
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Drill the specific named exceptions for each anion category until the halide, sulfate, and hydroxide exception lists stop needing a lookup.
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