The Science Behind Burnt Taste: What Happens Inside When a Coil “Dry Hits”

Every vaper has experienced it: that sudden, acrid taste that makes you instinctively recoil—the dreaded dry hit. It’s one of the most unpleasant sensations in vaping, leaving a burnt taste that lingers long after the puff. But what exactly is happening inside your device when you experience a dry hit? Understanding the science behind this phenomenon can help you prevent it and appreciate the delicate balance required for optimal vaping.

What Is a Dry Hit? Defining the Problem

A dry hit occurs when the heating coil vaporizes insufficient or absent e-liquid, instead burning the wicking material (usually cotton) and any residual organic compounds. The result is inhaling the harsh, toxic byproducts of pyrolysis—the thermal decomposition of organic material in the absence of oxygen or with limited oxygen.

Unlike a simple “harsh hit” caused by high nicotine strength or excessive wattage, a true dry hit involves actual combustion or near-combustion of the wick material, producing not just unpleasant flavor but potentially harmful compounds.

The Normal Vaping Process: A Delicate Balance

To understand what goes wrong, let’s first examine what happens during normal vaping:

The Ideal Vaporization Cycle

1. Saturation: Cotton wicking material is fully saturated with e-liquid through capillary action
2. Heat Application: Electrical current flows through the coil, generating heat (typically 150-250°C / 300-480°F)
3. Vaporization: E-liquid components reach their boiling points:
   • Propylene Glycol (PG): ~188°C (370°F)
   • Vegetable Glycerin (VG): ~290°C (554°F)
   • Flavorings: Varies, typically 150-250°C (300-480°F)
   • Nicotine: ~247°C (477°F)
4. Vapor Formation: Liquid transforms to aerosol, carrying flavor and nicotine
5. Cooling: The inhalation itself cools the coil, and the continuous e-liquid supply maintains temperature equilibrium

This process operates in a carefully balanced thermal range where e-liquid vaporizes but cotton remains well below its decomposition temperature.

What Causes a Dry Hit? The Root Causes

Several factors can disrupt this balance, leading to insufficient e-liquid at the coil:

1. Insufficient Wicking / Chain Vaping

Cotton can only absorb and transport e-liquid at a certain rate through capillary action. When you vape repeatedly without pausing (chain vaping), the coil vaporizes liquid faster than the wick can replenish it. The wick gradually dries out, and eventually, there’s insufficient liquid to absorb the heat.

The physics: Cotton wicking relies on surface tension and capillary pressure. The rate of liquid transport is governed by the Washburn equation, which depends on liquid viscosity, surface tension, and pore radius. High-VG liquids (which are more viscous) wick more slowly than high-PG liquids.

2. High Wattage / Temperature

Exceeding the recommended wattage for a coil generates more heat than the e-liquid supply can absorb. Even with adequate wicking speed, the vaporization rate outpaces liquid delivery.

The thermodynamics: Heat generation in the coil follows Joule’s law (H = I²Rt), where heat is proportional to current squared times resistance. When this heat exceeds the cooling capacity provided by e-liquid vaporization and airflow, temperature escalates rapidly.

3. Depleted E-Liquid

When the tank or pod runs low, gravity and capillary action can’t effectively draw liquid to the wick, particularly in certain orientations or with high-viscosity liquids.

4. Degraded or Gunked-Up Coil

Over time, sweeteners and flavorings in e-liquid caramelize on the coil surface, forming a dark, sticky residue known as “coil gunk.” This residue:

• Blocks wicking pores, restricting liquid flow
• Acts as an insulator, preventing even heat distribution
• Contains carbonized organic material that burns at lower temperatures

5. Improper Priming

New coils must be pre-saturated before first use. Failing to prime a coil means starting with dry cotton, guaranteeing an immediate dry hit.

6. Airflow Restriction

Ironically, insufficient airflow can contribute to dry hits. Proper airflow serves two functions: it cools the coil and creates negative pressure that assists liquid flow to the wick. Blocked or inadequate airflow reduces both cooling and liquid delivery.

The Chemistry of Burning: What Actually Happens

When a dry hit occurs, you’re witnessing and inhaling the products of cotton pyrolysis and thermal degradation:

Cotton Decomposition

Cotton (cellulose) begins thermal degradation around 150-200°C, but significant decomposition accelerates above 250°C. Without adequate liquid cooling, coil temperatures can spike to 400-600°C or higher within seconds.

The chemical breakdown:

1. Dehydration (200-280°C): Water molecules are stripped from cellulose structure, forming anhydrocellulose
2. Depolymerization (280-340°C): Cellulose chains break down into smaller molecules, releasing:
   • Levoglucosan
   • Carbon monoxide (CO)
   • Carbon dioxide (CO₂)
   • Various aldehydes
3. Carbonization (>340°C): Organic compounds break down into pure carbon char and volatile organic compounds (VOCs)

Formation of Harmful Compounds

Research on e-cigarette emissions under dry hit conditions has identified several concerning byproducts:

Formaldehyde: A known carcinogen formed when propylene glycol and vegetable glycerin thermally decompose at excessive temperatures (above 300°C). Normal vaping temperatures don’t produce significant formaldehyde, but dry hits absolutely can.

Acetaldehyde: Another aldehyde formed during thermal degradation, classified as a possible carcinogen and respiratory irritant.

Acrolein: An extremely irritating aldehyde that causes the harsh, acrid sensation characteristic of dry hits. It forms from glycerin dehydration at high temperatures.

Polycyclic Aromatic Hydrocarbons (PAHs): Complex organic molecules formed during incomplete combustion of organic material, some of which are carcinogenic.

Free Radicals: Highly reactive molecules that can cause oxidative stress and cellular damage.

The Role of Metal Coil Material

The coil itself doesn’t burn, but it acts as a catalyst for thermal decomposition. Different coil materials affect dry hit chemistry:

• Kanthal (FeCrAl): Most common; relatively inert but can reach very high temperatures
• Stainless Steel: Can release trace metal particles at extreme temperatures
• Nickel/Titanium: Used in temperature control; can release toxic compounds if overheated beyond design parameters

The Physiological Response: Why Dry Hits Feel So Bad

The intense, unpleasant sensation of a dry hit results from multiple physiological responses:

Respiratory Irritation

The aldehydes and particulate matter from burnt cotton directly irritate the mucous membranes of the throat and lungs. These compounds trigger:

• Nociceptor activation: Pain receptors in the respiratory tract
• TRPV1 receptors: The same receptors activated by capsaicin (hot peppers)
• Inflammatory response: Immediate inflammation and potential bronchial constriction

Olfactory Assault

Burnt organic compounds produce intensely unpleasant odors that trigger the brain’s disgust response—an evolutionary mechanism to avoid consuming toxic substances.

Lingering Taste

Carbonized particles coat the mouth and tongue, and volatile compounds can persist in the nasal passages, explaining why the burnt taste lingers even after the hit.

Temperature Dynamics: The Tipping Point

Understanding the temperature progression during a dry hit reveals why they happen so suddenly:

Normal vaping cycle:

• Coil surface temperature: 150-250°C
• Cotton temperature: 100-150°C (actively cooled by evaporating liquid)
• Stable thermal equilibrium maintained by latent heat of vaporization

Dry hit progression:

• T+0.0s: Normal operation, fully saturated wick
• T+0.5s: Liquid begins depleting faster than wicking replenishes
• T+1.0s: Cotton moisture drops below critical threshold
• T+1.5s: Without cooling from vaporization, coil temperature spikes to 400°C+
• T+2.0s: Cotton surface reaches pyrolysis temperature; decomposition begins
• T+2.5s: User tastes burnt compounds; immediate cessation of puff

This happens remarkably quickly—often within a single prolonged puff—because the thermal mass of vape coils is intentionally low for rapid heat-up. This same property means they overheat equally fast when cooling is removed.

The Spectrum of Severity: Not All Dry Hits Are Equal

Dry hits exist on a spectrum from mild to severe:

Mild Dry Hit (“Muted” or “Off” Taste)

• Cotton partially dry but not burning
• Reduced flavor, slightly harsh sensation
• Minimal thermal decomposition
• Reversible if caught early

Moderate Dry Hit (Noticeable Burnt Taste)

• Cotton surface layer reaching early decomposition
• Clear burnt taste, throat irritation
• Some aldehyde formation
• Coil likely needs replacement soon

Severe Dry Hit (Intense Burning)

• Complete cotton desiccation and charring
• Overwhelming acrid taste, possible coughing
• Significant toxic compound formation
• Coil replacement necessary; cotton permanently damaged

The “Popcorn Lung” Myth and Real Dry Hit Risks

It’s worth addressing a common misconception: dry hits don’t cause “popcorn lung” (bronchiolitis obliterans). This condition was linked to diacetyl, a buttery flavoring compound, not to burnt cotton. However, dry hits do pose legitimate concerns:

Short-term effects:

• Throat and lung irritation
• Coughing and discomfort
• Temporary inflammation
• Unpleasant experience

Potential long-term concerns with repeated exposure:

• Chronic respiratory irritation
• Possible cellular damage from aldehydes and free radicals
• Uncertain cumulative effects of repeated inhalation of pyrolysis products

While occasional dry hits are unlikely to cause lasting harm, regularly experiencing them suggests improper device use that should be corrected.

Prevention Strategies: Applying the Science

Understanding the mechanisms allows for targeted prevention:

1. Respect Wattage Limits

Use coils within their rated wattage range. The recommended range isn’t arbitrary—it’s calculated based on the wick’s liquid transport capacity and heat dissipation.

2. Adjust for E-Liquid Viscosity

High-VG liquids (70% VG or higher) wick more slowly. Consider:

• Using slightly lower wattage
• Choosing coils with larger wicking ports
• Allowing more time between puffs

3. Prime New Coils Properly

Apply e-liquid directly to the cotton wicking ports and let the coil sit for 5-10 minutes after installation. This ensures complete saturation throughout the cotton.

4. Monitor E-Liquid Levels

Refill before the liquid drops below the wicking ports. In many tanks, this occurs around 25-30% capacity.

5. Pace Your Vaping

Allow 20-30 seconds between puffs—longer with high-VG liquids or higher wattages. This gives the wick time to resaturate completely.

6. Maintain Your Coils

Replace coils showing signs of degradation:

• Dark, caramelized residue
• Reduced flavor
• Decreased vapor production
• Any slight burnt taste

7. Use Temperature Control (If Available)

TC devices can detect when the coil temperature exceeds safe limits and automatically reduce power, preventing most dry hits before they occur.

8. Ensure Adequate Airflow

Keep airflow vents clear and adjust them appropriately for your device and coil resistance.

What to Do After a Dry Hit

If you experience a dry hit:

1. Stop vaping immediately – Continuing will worsen cotton damage
2. Check e-liquid level – Refill if low
3. Prime the coil – Add drops of e-liquid directly to exposed cotton
4. Wait 5-10 minutes – Allow full resaturation
5. Start at lower wattage – Gradually increase to ensure the coil is working properly
6. Consider coil replacement – Severe dry hits can permanently damage wicking

If the burnt taste persists after these steps, the cotton is likely charred and the coil needs replacement.

The Bottom Line: Respecting the Physics

Dry hits represent a failure of the delicate thermal and fluidic balance that makes vaping work. They occur when heat generation exceeds the cooling capacity provided by e-liquid vaporization, causing cotton to reach temperatures where it thermally decomposes rather than the liquid vaporizing cleanly.

The science reveals that dry hits aren’t just unpleasant—they temporarily transform your vaping device into something closer to a combustion device, producing many of the same toxic compounds that vaping was designed to avoid.

By understanding what happens inside your device at the molecular level, you can better appreciate why proper technique, maintenance, and equipment choices matter. Vaping technology has evolved to operate within specific thermal parameters where e-liquid vaporizes cleanly and safely. Dry hits occur when we inadvertently—or through equipment failure—push beyond those parameters.

The good news? Armed with this knowledge, dry hits are almost entirely preventable. Respect your coil’s limits, maintain adequate e-liquid saturation, and your wicking will happily continue doing what it does best: keeping your coil cool and your vapor flavorful, puff after puff.