Category: Systems & Components

A radon mitigation system has six primary components and several secondary ones. Each serves a specific function in the chain from soil gas collection to safe discharge above the roofline. Understanding what each part does — and what failure looks like — turns a mysterious pipe in your basement into a system you can actually monitor and maintain.

Component 1: The Suction Point

The suction point is where the mitigation system makes contact with the radon source. It is the entry point for the entire system — everything else serves only to move radon from here to outside.

In Slab and Basement Homes (ASD)

A 3.5″–4″ diameter core hole drilled through the concrete slab, penetrating into the sub-slab aggregate or soil layer beneath. The riser pipe seats directly into this hole. Around the pipe, the annular gap is sealed with hydraulic cement to prevent uncontrolled air entry at the penetration point.

The sub-slab aggregate — typically 3/4″ clean gravel installed during construction — is the reservoir from which the fan draws. The aggregate allows pressure to distribute laterally, so a single suction point can depressurize a large area. Homes with poor aggregate (clay, sand fill) have limited pressure distribution and may require multiple suction points.

In Crawl Space Homes (ASMD)

The suction point penetrates through the vapor barrier membrane and connects to a perforated collection mat placed beneath it. The mat creates an air gap between the soil and the membrane, allowing the fan to draw from a distributed area rather than a single point. Multiple suction points connected via manifold pipe are common in crawl space systems.

Sump Pit Integration

When a sump pit is present, the pit itself serves as a highly effective suction point. An airtight lid replaces the standard pit cover, with a pipe fitting connecting the pit to the fan system. The drain tile network surrounding the foundation perimeter communicates with the sump, creating a distributed collection network that can cover the entire foundation footprint from a single connection.

Component 2: The Riser Pipe

The riser pipe is the vertical backbone of the system — 3-inch or 4-inch Schedule 40 PVC that carries radon-laden soil gas from the suction point at the slab up to the fan location in the attic or on the exterior wall.

Pipe Specifications

• Material: Schedule 40 PVC — the same material used for residential drain, waste, and vent (DWV) plumbing
• Diameter: 3″ for most residential installations; 4″ for high-flow applications or when the diagnostic test shows high static pressure requirements
• Joints: All joints made with PVC primer and solvent cement — never dry-fitted. A dry-fitted joint will eventually separate or allow air to bypass the system.
• Slope: Pipe should have positive slope toward the suction point (condensate drains back to the sub-slab rather than pooling in the pipe)
• Strapping: Secured to framing with pipe hangers every 4–6 feet; pipe should not flex or vibrate during fan operation

Routing Paths

The riser pipe takes one of two primary paths from slab to fan:

• Interior routing: Pipe runs through the home’s interior — through a wall cavity, utility chase, or closet — to the attic. The fan is mounted in the attic, protected from weather. This is the preferred approach for fan longevity and noise isolation.
• Exterior routing: Pipe penetrates through the foundation wall or rim joist directly to the exterior, running up the outside of the home. Faster to install and avoids interior framing work, but the fan is exposed to weather and temperature extremes.

Component 3: The Radon Fan

The radon fan is the active heart of the system. It creates continuous negative pressure in the pipe network, drawing radon-laden air from the sub-slab and routing it to discharge.

Fan Placement Rules

AARST-ANSI SGM-SF has an absolute requirement: the fan must be installed in unconditioned space (attic, exterior, or garage) — never in conditioned living space, including finished basements and utility rooms inside the thermal envelope. The reason: radon fan housings can develop minor leaks over time. If the fan leaks in conditioned space, radon enters the home at the leak point. In unconditioned space, any leak discharges into air that is not routinely occupied.

Common Fan Models

• RadonAway RP145: 20W, ~40 CFM at 0.5″ WC. Lowest energy use; ideal for excellent aggregate, small footprint, or homes with measured low static pressure at the suction point.
• RadonAway RP265: 55W, ~75 CFM at 0.5″ WC. The most-installed residential radon fan in the U.S. Covers the majority of single-family residential conditions.
• RadonAway GP301/GP501: 85–90W. High-static fans for demanding conditions: dense sub-slab fill, large footprints, multiple suction points, or unusually deep aggregate requiring high lift.
• Festa DP3: Alternative brand in the RP265 performance class, used by some contractors.

Fan Sizing Logic

Fan selection is determined by the pre-installation diagnostic test — specifically the measured static pressure at the suction point under test vacuum conditions. A mitigator who selects a fan without performing a diagnostic test is guessing. Oversized fans consume unnecessary electricity and can over-depressurize the sub-slab (drawing conditioned air into the soil, increasing heating costs). Undersized fans leave radon reduction incomplete.

Fan Lifespan and Warranty

RadonAway fans carry a 5-year manufacturer warranty. Expected operational lifespan is:

• Interior/attic-mounted fans: 10–15 years
• Exterior-mounted fans: 7–12 years (weather exposure shortens bearing life)

Fan replacement is the most common maintenance event in a radon system’s life. Because the pipe network and all fittings remain in place, a fan replacement is typically a 30–60 minute job costing $100–$300 in labor plus the replacement fan ($80–$200).

Component 4: The Discharge Pipe and Termination Cap

From the fan outlet, a discharge pipe routes the extracted radon above the roofline and terminates with a weatherproof cap. This is where radon exits the system and disperses into the atmosphere.

Termination Requirements (AARST SGM-SF)

• Discharge must extend at least 12 inches above the roof surface at the penetration point
• Discharge must not terminate within 10 feet horizontally of any window, door, or mechanical ventilation opening
• Termination cap must prevent precipitation entry and pest intrusion while allowing free airflow
• For exterior-routed systems: discharge must terminate above the roof eave line — not at the side of the house below the eave

Roof vs. Gable Discharge

Discharge can exit through the roof (via a plumbing pipe boot flashing) or through the gable end of the attic. Gable discharge is preferred by many contractors because it avoids a roof penetration — reducing the potential for future leak points and typically faster to install. Both are compliant when termination height requirements are met.

Component 5: The System Performance Indicator (Manometer)

The U-tube manometer is the system’s dashboard — the only component visible inside the living area that tells you whether the system is operating correctly without requiring a radon test.

How the Manometer Works

The U-tube manometer is a small glass or plastic tube filled with colored liquid, installed on the riser pipe at a visible interior location. It connects to the inside of the pipe via a small fitting. When the fan is running and creating negative pressure:

• Liquid displaced (one side higher than the other): Fan is generating suction — system operating normally
• Liquid level (both sides equal): Fan is not generating suction — fan may be off, failed, or the pipe has a breach

AARST SGM-SF requires a performance indicator on every active system installation. Check it monthly.

Digital Pressure Gauges

Some installations use a digital magnehelic gauge instead of a liquid U-tube, providing a numeric pressure reading in inches of water column. These are more precise but add cost ($30–$80 vs. $5–$15 for a U-tube). Both are AARST-compliant performance indicators.

Component 6: Sealing and Caulk

Sealing is not a glamorous component, but it is frequently the difference between a system that achieves 95% reduction and one that achieves 70%. Every unsealed gap in the slab, wall joint, or floor penetration is a pathway for radon to bypass the sub-slab vacuum and enter the home directly.

Sealing Materials Used

• Hydraulic cement or non-shrink epoxy grout: Used to seal the annular gap around the riser pipe at the slab core hole. Sets hard and does not compress over time. The correct material — spray foam is NOT appropriate for this application (foam compresses).
• Polyurethane caulk: Used to seal expansion joints, control joints, visible cracks, and the floor-wall perimeter joint. More flexible than hydraulic cement — accommodates minor foundation movement.
• Backer rod: Foam rod inserted into wide joints before caulking, to provide backing and reduce the volume of caulk required for deep gaps.
• Rigid foam board: Used to seal foundation vents in crawl space ASMD systems.
• Fire-rated caulk: Required where the pipe passes through fire-rated floor/ceiling assemblies per local building code.

Required Labeling

AARST standards require a permanent warning label applied to the riser pipe at a visible location. The label identifies the pipe as a radon reduction system and includes:

• “RADON REDUCTION SYSTEM — Do not cover or obstruct”
• Installer name and state license/certification number
• Installation date
• Fan model (typically noted on the fan body itself)

This label serves homeowners, future buyers, home inspectors, and any contractor who works on the home after installation. A system without a label is a system that has no installation record attached to it — a flag during real estate transactions in states with radon disclosure requirements.

Frequently Asked Questions

What does the pipe sticking out of my basement floor connect to?

The pipe connects to a core hole drilled through the concrete slab, which opens into the aggregate or soil layer beneath your foundation. This is the suction point — the pipe draws radon-laden soil gas from beneath the slab and routes it up through the home to a fan in the attic, then discharges it above the roofline.

What is the liquid-filled gauge on my radon pipe?

That is the U-tube manometer — the system’s performance indicator. The colored liquid in the tube should be displaced (one side higher than the other) when the system is running correctly. A level liquid column means the fan is not generating suction and should be inspected.

Why does the fan need to be in the attic and not the basement?

AARST standards require the fan to be in unconditioned space — never in conditioned living area. If the fan housing develops a minor leak, radon discharges into unconditioned space (attic, exterior) rather than into the living area. This is a safety requirement, not a preference.

How many suction points does a radon system need?

Most slab and basement homes with good aggregate need one. Larger footprints (3,000+ sq ft), poor sub-slab fill (clay, sand), or complex foundation geometry may need two or three. Crawl space systems typically need two to four. The pre-installation diagnostic test determines the correct number — a mitigator should not determine suction point count without testing first.

What should I check on my radon system each month?

Check the U-tube manometer — confirm the liquid column is displaced, indicating the fan is generating suction. Listen for the fan (a faint hum from the attic area is normal; silence or new grinding sounds are not). Visually confirm the pipe labels and required signage are still in place. Conduct a post-mitigation radon test every 2 years per EPA recommendations.

There is no single radon mitigation system. There are six primary system types, each designed for specific foundation conditions — and most homes with elevated radon require one primary method plus supplemental sealing. Knowing which system type applies to your home’s foundation eliminates confusion about what a contractor is proposing and whether the approach matches your situation.

1. Active Sub-Slab Depressurization (ASD)

Active Sub-Slab Depressurization is the most widely installed radon mitigation system in the United States. It is the standard approach for slab-on-grade homes and basement homes with concrete slab floors.

How ASD Works

A suction pipe penetrates the concrete slab, connecting to the aggregate or soil layer beneath. A continuously running electric fan draws air (and with it, radon) from beneath the slab, routing it through PVC pipe to discharge above the roofline. This creates negative pressure in the sub-slab zone relative to the home’s interior — preventing radon from finding pathways through cracks, joints, and penetrations into the living space.

ASD Applications

• Slab-on-grade homes (full footprint slab, no basement)
• Basement homes with concrete slab floors
• Homes with both a basement and upper-level slab additions
• Garage slabs connected to the main living area slab

ASD Governing Standard

AARST-ANSI SGM-SF (Standard of Practice for Mitigation of Radon in Schools and Large Buildings, adapted for single-family) governs ASD installation requirements including diagnostic testing, pipe sizing, fan placement, and performance verification.

2. Active Sub-Membrane Depressurization (ASMD)

Active Sub-Membrane Depressurization is the crawl space equivalent of ASD. Instead of drilling through concrete, the system creates negative pressure beneath a vapor barrier (membrane) installed over the crawl space soil.

How ASMD Works

A heavy-duty polyethylene vapor barrier (minimum 6-mil; professional installations use 10–20 mil) is installed across the entire crawl space floor, lapped up foundation walls, and sealed at all edges and penetrations. A suction pipe penetrates the barrier and connects to the soil or aggregate below via a perforated collection mat. The fan draws soil gas from beneath the barrier, routing it above the roofline through the same type of PVC pipe system used in ASD.

ASMD Requirements

• Foundation vents must be sealed — open vents allow outdoor air into the crawl space, defeating the sub-membrane vacuum
• Barrier seams must be lapped (minimum 12″ overlap) and taped
• Multiple suction points are often needed — crawl spaces typically require 2–4 collection points versus the 1–2 typical in ASD installations
• AARST-ANSI RMS-LB governs ASMD installation standards

3. Drain-Tile Depressurization

Many basement homes — particularly those built after 1980 — were constructed with a drain-tile system: a perforated pipe network running around the interior or exterior perimeter of the foundation, at or below the footing level, designed to channel groundwater to a sump pit. This drain tile can serve as a highly effective radon collection network.

How Drain-Tile Depressurization Works

When a sump pit is present and the drain tile is functional, the mitigator creates suction at the sump pit — either by sealing the pit with an airtight lid and connecting a fan, or by installing a dedicated suction pipe into the drain tile network. Because the drain tile runs around the full foundation perimeter, a single suction point at the sump can create negative pressure across a very large area — often the entire foundation footprint without any slab drilling.

Advantages Over Standard ASD

• No slab drilling required (the drain tile network is already in place)
• Often achieves better sub-foundation coverage than a single slab core hole
• Sump pit is already present — lid modification is the primary work
• Lower installation cost when drain tile is accessible

Limitations

• Requires a confirmed functional drain-tile system — older or poorly maintained tile may be silted or blocked
• Not present in all homes — many older homes and slab-on-grade construction have no drain tile
• May need to be supplemented with slab suction point(s) if tile coverage is incomplete

4. Block-Wall Depressurization

Concrete masonry unit (CMU) block foundation walls have hollow cores that communicate directly with the soil — a significant secondary radon entry pathway in older homes. Block-wall depressurization addresses this specifically.

How Block-Wall Depressurization Works

Small holes (2″–3″ diameter) are drilled through the interior face of the CMU block wall, typically just above the slab level, at 6–8 foot intervals around the affected perimeter. PVC pipe connects these holes, manifolding into the main ASD fan system or a dedicated fan. The fan draws radon from inside the block core cavities before it can migrate through mortar joints and wall cracks into the basement air.

When Block-Wall Depressurization Is Needed

• Post-mitigation testing still shows levels above 4.0 pCi/L after standard ASD is installed
• Visual inspection reveals significant efflorescence, spalling, or moisture infiltration through block walls (indicating active soil gas pathways)
• Home is pre-1975 CMU construction with no poured concrete wall facing

Block-wall depressurization is almost always an add-on to ASD, not a standalone system. Cost: $300–$600 in additional materials and labor when added to an existing ASD installation.

5. Heat Recovery Ventilator (HRV) or Energy Recovery Ventilator (ERV)

HRV and ERV systems are whole-house mechanical ventilation systems that exchange stale indoor air with fresh outdoor air while recovering heat (HRV) or both heat and moisture (ERV). They are sometimes used as a radon reduction strategy — primarily in situations where other methods are impractical or as a supplemental approach.

How HRV/ERV Reduces Radon

By continuously introducing fresh outdoor air into the home, HRV/ERV dilutes indoor radon concentrations. They also reduce the negative pressure differential that draws radon into the home from the soil, because they balance indoor and outdoor pressure rather than allowing the home to depressurize relative to the soil.

Limitations as Radon Mitigation

• Less reliable reduction than ASD/ASMD — radon dilution depends on outdoor air exchange rate, and results vary significantly by climate and home tightness
• Higher operating cost — HRV/ERV units consume 100–400 watts versus 20–90 watts for a radon fan
• Does not address the root cause (radon entry from soil) — only dilutes after entry
• Not accepted as primary mitigation in all state radon programs
• Best suited as supplemental to ASD in homes where additional air quality improvement is also desired

EPA and AARST consider ASD/ASMD the preferred primary mitigation method. HRV/ERV may be appropriate as supplemental mitigation or in unusual foundation situations where ASD is genuinely impractical.

6. Natural Ventilation Enhancement

Natural ventilation — opening windows, operating exhaust fans, increasing air exchange — can temporarily reduce radon concentrations. It is not a mitigation system and is not recommended by EPA or AARST as a radon control strategy for several reasons:

• Effective only while windows are open — unpractical in most U.S. climates for the majority of the year
• Increases heating and cooling costs significantly
• Can create negative pressure that worsens radon entry
• Provides no permanent solution

Natural ventilation may be used as a short-term measure while a permanent system is being installed, but it is not a substitute for ASD, ASMD, or other mechanical systems.

Choosing the Right System: Decision Guide

Frequently Asked Questions

What is the most common type of radon mitigation system?

Active Sub-Slab Depressurization (ASD) is the most commonly installed radon mitigation system in the U.S. It applies to slab-on-grade and basement homes — the two most prevalent residential foundation types. For crawl space homes, Active Sub-Membrane Depressurization (ASMD) is the standard.

Can one system work for multiple foundation types in the same home?

Yes, but it typically requires separate or manifolded systems. A home with a basement and a slab-on-grade addition, for example, may need ASD suction points in both zones, connected to a single fan via manifold pipe — or two separate fans if the zones are not contiguous. An experienced mitigator will design for the full footprint, not just the primary foundation type.

Does the type of radon system affect the cost?

Yes, significantly. A standard single-point ASD in a poured concrete basement is the least expensive ($800–$1,500). Adding drain-tile depressurization at the sump typically adds $100–$300. Block-wall depressurization adds $300–$600. ASMD with full crawl space encapsulation can run $2,500–$5,000+ depending on crawl space size and membrane quality.

What type of radon system works in a home with no basement and no crawl space?

Slab-on-grade homes use ASD — a suction pipe drilled through the concrete slab connects to the aggregate beneath. Interior routing typically runs through a garage wall or utility closet to the attic. Exterior routing is an alternative when interior access is limited. The challenge in slab homes is pipe routing to above the roofline without a basement or crawl space to work through — but it is fully achievable in almost all cases.

What is the difference between ASD and ASMD?

Both use a fan to create negative pressure below the home’s floor system. ASD drills through a concrete slab and draws suction from the sub-slab aggregate or soil. ASMD installs a vapor barrier over the crawl space soil and draws suction from beneath the barrier — no concrete is present to drill through. The fan, pipe, and discharge components are identical; only the suction connection method differs.

Every radon mitigation system is either active or passive. The distinction controls whether your system runs on a fan or relies on natural physics — and it determines whether your radon levels will reliably stay below the EPA’s 4.0 pCi/L action level or merely reduce somewhat. Understanding the difference helps you evaluate what you have, what you need, and what a contractor is actually installing.

What Is a Passive Radon Mitigation System?

A passive radon mitigation system uses no mechanical fan. It relies entirely on natural pressure differentials — specifically, the stack effect — to draw radon-laden soil gas out from under your home and vent it above the roofline.

The stack effect is the same phenomenon that makes a fireplace draw: warm air rises, creating upward airflow through any vertical channel. In a passive radon system, a 3–4 inch PVC pipe runs from a suction point beneath the slab, through the home’s interior, and terminates above the roof. When the home’s interior is warmer than the outside air — which is most of the year in most U.S. climates — warm air rising through the pipe creates mild negative pressure at the bottom, drawing soil gas upward and out.

When Passive Systems Are Installed

• Radon-Resistant New Construction (RRNC): The standard passive system installed during home construction — pipe, vapor barrier, gas-permeable layer — before a radon problem has been confirmed. The passive infrastructure is in place; a fan can be added if post-construction testing shows elevated levels.
• Low-radon environments: A home testing at 1.5–2.5 pCi/L might achieve adequate reduction with passive-only in favorable conditions.
• Supplemental to other measures: In some crawl space installations, passive ventilation combined with encapsulation can achieve adequate reduction without a fan.

Passive System Limitations

Passive systems are inherently unreliable as standalone mitigation for confirmed elevated radon levels. The stack effect weakens or reverses under specific conditions:

• Summer months: When outdoor temperatures match or exceed indoor temperatures, the stack effect diminishes — exactly when windows are open and radon testing results vary most
• Windy conditions: Wind pressure can reverse airflow direction in the pipe
• High-efficiency sealed homes: Tight building envelopes can create neutral or positive pressure at the slab level, counteracting passive stack draw
• Poor sub-slab communication: Homes with clay or sand sub-slab fill have limited natural airflow regardless of stack effect

EPA testing has found that passive RRNC systems achieve below 4.0 pCi/L in roughly 50–70% of new construction cases. For the remaining 30–50%, activation with a fan is required. As a standalone fix for a home that has already tested elevated, passive-only is not recommended.

What Is an Active Radon Mitigation System?

An active radon mitigation system adds a continuously operating electric fan to the pipe network. The fan creates reliable, consistent negative pressure in the sub-slab zone — regardless of outdoor temperature, wind, or building pressure conditions. The fan runs 24 hours a day, 7 days a week, 365 days a year, typically consuming 20–90 watts (similar to a light bulb).

Active Sub-Slab Depressurization (ASD) is the most common form — used for slab-on-grade and basement foundations. Active Sub-Membrane Depressurization (ASMD) uses the same fan-powered approach for crawl space homes, with suction applied beneath the vapor barrier rather than directly below a concrete slab.

Why Active Systems Perform Consistently

The fan’s mechanical suction creates 0.02–0.15 inches of water column negative pressure at the slab — a controlled, measurable value. This negative pressure is:

• Independent of outdoor temperature (stack effect is irrelevant when the fan is running)
• Consistent across seasons and weather conditions
• Verifiable via the U-tube manometer installed on the pipe — the displaced liquid column confirms the fan is generating suction
• Adjustable by swapping to a higher or lower capacity fan if conditions change

AARST-ANSI standard SGM-SF governs active ASD system installation. The standard requires a performance indicator (manometer) on every active system precisely because consistent, verifiable performance is the system’s primary advantage over passive.

Side-by-Side Comparison

Converting Passive to Active: The Fan Activation

If you have a home built with RRNC passive infrastructure and post-construction testing reveals levels at or above 4.0 pCi/L, activating the system is the simplest mitigation work available:

• The existing pipe runs from sub-slab to above the roofline — no new routing required
• A radon fan is installed in the pipe run (typically in the attic between the riser and discharge pipe)
• Fan connects to the pre-installed electrical outlet in the attic
• A U-tube manometer is installed on the visible portion of the pipe inside the home
• Total installation: 1–2 hours, $200–$500 in labor plus $100–$300 for the fan

Post-activation radon testing confirms results (48-hour charcoal test under closed-house conditions, placed at least 24 hours after activation).

Fan Selection for Active Systems

The fan is the heart of an active system. Fan selection is based on the sub-slab diagnostic test — specifically, the measured airflow resistance (static pressure) the fan must overcome to achieve adequate negative pressure across the full slab footprint.

• RadonAway RP145: Low-static, 20W, ~40 CFM at 0.5″ WC. Best for excellent aggregate, small slab. Quietest option.
• RadonAway RP265: Mid-range, 55W, ~75 CFM at 0.5″ WC. Most commonly installed residential fan. Covers most standard conditions.
• RadonAway GP501/GP301: High-static, 85–90W. For dense fill, multiple suction points, or large footprints requiring greater suction field.
• Festa DP3: Alternative brand in the RP265 performance range used by some contractors.

Oversizing a fan (installing a GP501 when an RP145 would suffice) wastes electricity and can create too much depressurization — pulling conditioned air into the soil and increasing heating/cooling costs. Undersizing leaves radon reduction incomplete. The diagnostic test, not guesswork, determines the right fan.

Maintenance: Active vs Passive

Passive systems require essentially no maintenance — no moving parts, no electrical connections. Annual visual inspection to confirm the pipe is unobstructed is sufficient.

Active systems require:

• Monthly manometer check: Confirm the liquid column is displaced (fan generating suction)
• Annual visual inspection: Fan housing for cracks, pipe connections for separation, discharge cap for obstruction
• Fan replacement when needed: RadonAway fans carry 5-year warranties; typical lifespan is 10–15 years for interior/attic-mounted fans, 7–12 years for exterior-mounted fans exposed to weather
• Periodic radon retesting: EPA recommends retesting every 2 years even with an active system — to confirm continued performance and catch any new entry pathways that develop from foundation settling or remodeling

Frequently Asked Questions

Is a passive radon system good enough?

For new construction in lower-risk zones, a passive RRNC system reduces radon risk and provides fan-ready infrastructure if needed. For a home that has already tested at or above 4.0 pCi/L, passive-only is rarely sufficient — active (fan-powered) mitigation is the standard of care for confirmed elevated radon.

How much electricity does an active radon fan use?

Most residential radon fans consume 20–90 watts running continuously. At average U.S. electricity rates (~$0.13/kWh), a 55-watt fan (RP265) costs approximately $63/year to operate. A 20-watt fan (RP145) costs roughly $23/year. This is comparable to leaving a small light bulb on permanently.

Can I add a fan to my existing passive radon pipe?

Yes — if you have RRNC passive infrastructure (pipe already routed from sub-slab to above roofline), adding a fan is a 1–2 hour job. The fan is installed in the pipe run in the attic and connected to an outlet. If there is no pre-installed outlet, an electrician may need to add one first.

What happens if the fan in an active radon system stops working?

If the fan fails, the system reverts to passive-only operation. Radon levels will likely rise — potentially back toward pre-mitigation levels over days to weeks depending on soil conditions and building pressure. The U-tube manometer will show a level (not displaced) liquid column — the homeowner’s alert that the fan needs replacement. Most fan failures are caught this way during routine monthly checks.

Do both active and passive systems need to vent above the roofline?

Yes. Both active and passive systems must discharge radon above the roofline per AARST standards — at least 12 inches above the highest eave and at least 10 feet horizontally from any window, door, or ventilation opening. This ensures discharged radon disperses into the atmosphere rather than being drawn back into the home through openings.

A radon mitigation system is a small piece of mechanical infrastructure that quietly does something remarkable: it reverses the airflow physics of your home, turning the ground beneath your foundation from a source of radioactive gas into a controlled exhaust pathway. It looks like a PVC pipe and a fan. It behaves like a tiny, purpose-built climate system for the cubic yards of soil you will never see.

Most explanations of how these systems work stop at the pipe-and-fan level. That’s fine if you only need to nod along during a contractor’s pitch. But if you’ve just learned your home tests above the EPA action level of 4.0 pCi/L, or you’re trying to decide whether a system on the house you’re buying is actually doing its job, or you simply want to understand the one piece of permanent hardware a mitigator is about to bolt to your house for the next twenty-five years, the pipe-and-fan description is not enough. It’s the outline of an answer, not the answer.

This is the deep version. It starts with the physics, walks through every component, explains why each one is there, covers how the system is designed and commissioned, describes what installation day actually looks like, and ends with what effectiveness really means, what failure looks like, and what to watch for across the system’s working life.

The physics: why radon gets into your house in the first place

Radon is a noble gas, chemically inert, colorless, odorless, tasteless, and radioactive. It forms continuously in the soil wherever uranium exists in rocks and minerals — which is nearly everywhere, in varying concentrations. As uranium decays over its multi-billion-year half-life, it passes through radium, and radium decays into radon. Radon, being a gas, moves. It percolates up through soil pore spaces, cracks, and fissures, driven by pressure and concentration gradients, until it reaches the surface and disperses into the open atmosphere where it’s diluted into irrelevance.

Unless there’s a house in the way.

Houses sit on their foundations like inverted cups over the soil, and houses breathe. Warm air inside a home rises and escapes through upper-level windows, attic penetrations, and leaky building envelopes. This creates what building scientists call the stack effect: as warm air leaves the top of the house, cooler air gets pulled in at the bottom to replace it. Some of that replacement air comes from outside through lower-level leaks. Some of it comes from below — drawn up through cracks in the slab, gaps around plumbing penetrations, sump pit openings, crawl space dirt, and any other pathway the soil gas can find. That upward draw from the soil is a partial vacuum on your foundation, and the soil gas it pulls in carries radon with it.

This is the central insight that makes every mitigation system make sense. Your home, just by being warm and occupied, is actively drawing radon out of the soil beneath it. The soil is not pushing radon into your house. Your house is pulling radon out of the soil. Mitigation works by canceling that pull.

What “active soil depressurization” actually does

The dominant technique for residential radon mitigation — the one you will encounter in more than ninety percent of installations — is called active soil depressurization, usually abbreviated ASD. The name describes the mechanism precisely: it actively creates a pressure difference between the soil and the house that is larger than and opposite to the natural pressure difference the house was creating on its own.

A mitigation fan, running continuously, creates a slight vacuum inside a sealed pipe that penetrates the slab or membrane beneath the home. That vacuum pulls soil gas out of the pipe, which in turn pulls soil gas out of the ground around the pipe’s suction point, which in turn creates a low-pressure zone underneath the foundation. When the soil beneath your foundation is at lower pressure than the air inside your basement, soil gas can no longer be drawn up through cracks and openings. It has somewhere easier to go: the pipe. The radon is captured at its source, routed through the vent stack, and released outdoors high above the roofline where it dilutes harmlessly into the open atmosphere.

The key number is the magnitude of that pressure differential. Research cited by the EPA and documented in the AARST standards shows that a well-designed ASD system typically establishes a negative pressure field of around one to five pascals beneath the slab, which is enough to overcome the stack effect in any normally occupied home. That is a tiny pressure — roughly the weight of a single sheet of paper spread across a square meter. It does not need to be large. It just needs to be consistent and continuous.

The components, one by one

A radon mitigation system is intentionally simple. Complexity hides failure modes. The entire assembly usually has fewer than a dozen named components, and each one exists for a specific reason.

The suction point

The suction point is the anchor of the whole system. It is the hole cored through the concrete slab, typically four to six inches in diameter, that gives the fan a path to the soil gas beneath the foundation. Underneath the slab, the installer excavates a small pit — fifteen to twenty-five gallons of soil removed, depending on permeability — to create a plenum. This plenum acts as a collection chamber that lets the suction field extend out through the gravel and soil under the slab instead of being choked at a single pinhole.

The number and placement of suction points is the single most important design decision in the entire system. A small, tight slab on highly permeable gravel might only need one suction point. A sprawling, multi-section foundation with interior footings and fractured permeability may need three or four. The way a competent mitigator makes this call is with pressure field extension testing, commonly called PFE. A diagnostic vacuum is pulled at a test point, and micromanometers measure whether the vacuum reaches adjacent holes drilled elsewhere in the slab. If pressure extends freely, one suction point covers a wide area. If it attenuates quickly, more points are needed. Mitigators who skip PFE testing are guessing.

In homes with existing sumps or French drain perimeter systems, the sump pit or drain tile loop can serve as the plenum itself. A sealed sump cover with a pipe penetration, connected to the fan, turns the entire perimeter drain network into one continuous suction point. This is often the cleanest and highest-performing configuration when it’s available.

The vent pipe

Three- or four-inch schedule 40 PVC is the standard, selected specifically because the AARST standard ANSI/AARST SGM-SF calls for a pipe diameter sized to the expected airflow of the specified fan. Four-inch pipe is more common in high-airflow applications and in homes where sub-slab permeability is high. Three-inch pipe is used for tighter systems where high static pressure and lower airflow are expected. Undersized pipe creates excessive back-pressure and starves the fan. Oversized pipe can trap condensation. The sizing is not arbitrary.

The pipe runs from the suction point up through the conditioned space and exits through the roof, or alternately runs outside the home along an exterior wall and rises above the eave. Either configuration is code-compliant if done correctly. The rule is the same in both cases: the discharge point must be at least ten feet above grade, at least ten feet away from any window, door, or air intake that sits within two feet below the discharge, and above the eave line. These distances exist to prevent discharged radon from re-entering the home through any nearby opening.

Inside the conditioned space, the vent pipe must run in a way that doesn’t trap moisture. Long horizontal runs are avoided. Any unavoidable horizontal section is pitched back toward the suction point so condensate can drain downward. In cold climates, the upper outdoor section of the pipe is sometimes insulated to prevent fan freeze-up when warm, humid soil gas meets sub-freezing ambient temperatures at the top of the stack.

The fan

The radon fan is the system’s heart. It is a sealed inline centrifugal fan purpose-built for continuous twenty-four-hour operation in a corrosive, moisture-laden, low-pressure environment that would destroy a standard HVAC booster fan within months. The two dominant manufacturers in the North American market are RadonAway (makers of the RP-series and GP-series fans) and Fantech. Each fan model has a characteristic fan curve — a relationship between static pressure and airflow — that a qualified mitigator matches to the system’s expected resistance.

An RP145 fan, for example, handles most standard single-family slab homes with moderate permeability. The RP265 is specified for larger homes or tighter soil conditions where more suction is required. The GP501 is typically used for the highest-pressure, lowest-airflow applications. Picking the wrong fan — too small and the system can’t generate enough vacuum to hold the pressure field, too large and it pulls conditioned air out of the house and wastes energy — is one of the most common design errors in low-quality installations.

The fan is always installed outside the conditioned envelope of the home. It lives in an unheated attic, in a garage without living space above it, on an exterior wall, or on the roof. It is never installed in a basement, a utility room, or anywhere a pressurized leak in the fan housing could push radon-laden air back into the living space. This is a building code issue, not a preference. A fan on its discharge side is pressurizing the pipe. Any crack or joint failure downstream of the fan becomes a radon emitter.

Power consumption for a typical residential fan runs between sixty and ninety watts continuous. Annual operating cost, at average U.S. electricity rates, is typically between seventy and a hundred and forty dollars per year. Fans run continuously for the life of the system, which is usually specified at five years under warranty but often reaches ten to twelve years in practice before replacement is needed.

The manometer

The manometer is the smallest component in the system and the one homeowners should care about most. It is a simple, sealed U-shaped tube, partially filled with colored oil or water, mounted on the vent pipe downstream of the fan. One side of the U is open to the atmosphere. The other side is connected by a small tap into the vent pipe. When the fan is running and the pipe is under vacuum, the liquid in the U is pulled toward the pipe side, creating a visible offset between the two fluid columns. That offset, measured in inches of water column, is the system’s operating vacuum.

A functioning system will show a consistent, stable offset — typically between 0.5 and 2.0 inches of water column, depending on the fan, the pipe configuration, and the sub-slab permeability. If the liquid levels equalize — meaning both sides of the U are at the same height — the fan has stopped, the pipe has cracked, or the suction has failed. A stable manometer is the cheapest and most reliable diagnostic tool in residential mechanical systems. A homeowner who checks the manometer once a month will catch a failed fan within thirty days. A homeowner who never looks at it might discover the system has been off for two years only when a real estate retest comes back elevated.

The labels and the instruction packet

These are not optional flourishes. The AARST standards require that every mitigation system be permanently labeled with the installer’s name and contact, the installation date, the measured pre-mitigation radon level, the fan make and model, and a warning that the fan must run continuously. A second label, placed near the manometer, identifies the baseline fluid position so a future homeowner or inspector can tell at a glance whether the pressure has drifted. The instruction packet — often a folder or envelope zip-tied to the pipe — contains the warranty documents, the owner’s manual for the fan, and the post-mitigation test results that proved the system worked at commissioning.

These details feel bureaucratic until they matter. When a home changes hands in ten years, the buyer’s inspector will read the label, check the manometer, and know within ninety seconds whether the system is legitimate, compliant, and working as designed.

The design process, before installation day

A competent radon mitigation installation does not start with coring a hole. It starts with a walk-through of the home, a diagnostic session, and a design conversation.

The mitigator will inspect the foundation type, identify the locations of footings and interior walls that might divide the sub-slab into isolated zones, look for existing sumps and drain tile networks, assess the routing options for the vent pipe, and check for cosmetic constraints (some homeowners do not want a white PVC pipe running through a finished living room, and exterior routing needs to be evaluated for feasibility). The mitigator will then perform at least one PFE test if the foundation is not trivial, drilling a small test hole and measuring pressure propagation across the slab to determine whether one suction point is enough or whether more are needed.

This diagnostic phase is what separates a twelve-hundred-dollar cookie-cutter installation from a twenty-five-hundred-dollar engineered solution. Both systems may look similar when finished. Only one of them is certain to pass post-mitigation testing on the first try.

The design output is a proposal — a document that should specify where the suction point or points will be cored, what fan model will be installed, where it will be mounted, how the vent pipe will be routed, what sealing of the slab will be performed, whether any sump or drain tile connections are included, and what the post-mitigation target is in pCi/L. Any proposal that does not contain those specifics is a ticket to later regret.

What installation day actually looks like

A typical single-family residential mitigation installation is a one-day job. Two technicians arrive in the morning with a coring rig, a reciprocating saw, a supply of PVC pipe and fittings, a fan, sealant, a manometer, and the paperwork. Here is the actual sequence.

First, the core. A water-cooled diamond coring bit drills the suction point through the slab. The slurry is vacuumed. The sub-slab pit is excavated with a shop vac and a small pry bar until a small plenum chamber is hollowed out. The suction pipe is inserted into the hole, sealed to the slab with polyurethane sealant rated for the application, and allowed to cure.

Second, the route. The vent pipe is assembled in sections using primer and solvent cement, rising from the suction point through the planned routing. In an interior route, the pipe passes through an unused closet, a utility chase, an attic, and out through the roof with a rubber flashing boot. In an exterior route, the pipe exits the rim joist, runs up the outside wall, and rises above the eave.

Third, the fan. The fan is cut into the line outside the conditioned envelope, secured to a bracket or strap, and connected to power. Electrical codes vary by jurisdiction; in some states a licensed electrician is required for the fan hookup, and in others a radon mitigator with appropriate licensure can perform the connection as part of the installation.

Fourth, the manometer. The small plastic U-tube is tapped into the pipe on the vacuum side of the fan, usually just downstream of the suction point, and its baseline fluid position is marked on the label.

Fifth, the seal. Visible cracks in the slab, the sump pit perimeter if applicable, any floor drain openings, and any utility penetrations that communicate with the sub-slab area are sealed with backer rod and urethane sealant. Sealing alone is never sufficient to reduce radon — the EPA and AARST are emphatic on this point — but it makes the ASD system more efficient by reducing air short-circuits that would otherwise bleed conditioned air through the soil.

Sixth, the label. The installer’s label and the system data label are applied in a prominent location.

Seventh, the test. A short-term radon test is placed in the lowest lived-in level of the home no sooner than twenty-four hours after the fan has been running. The test runs for forty-eight to ninety-six hours, closed-house conditions are maintained, and the result is sent to a lab. That number is the post-mitigation verification. Under AARST standards and most state requirements, it should be below 4.0 pCi/L. A high-quality installation routinely achieves below 2.0 pCi/L. American Radon Mitigation, one of the mitigators ranking on the first page of Google, guarantees 1.5 pCi/L or below for five years. That number represents the genuine ceiling of what’s achievable in a well-designed system.

From coring to final cleanup, the whole job usually takes between four and eight hours.

What effectiveness really means

Radon mitigation is one of the few home-improvement interventions with decades of outcome data behind it. Follow-up studies cited in AARST literature and the EPA’s Consumer’s Guide show that properly installed active soil depressurization systems reduce indoor radon levels by eighty to ninety-nine percent in the vast majority of homes. The variance comes from design quality and site conditions, not from the fundamental technique.

A home that tested at 10 pCi/L before mitigation will typically test between 0.5 and 2.0 pCi/L afterward. A home that tested at 20 pCi/L might come down to 1.0 pCi/L. The best systems push levels below the outdoor ambient background, which in most of North America sits around 0.4 pCi/L. Below that number, further reduction is physically impossible because you are now below the radon concentration of the atmosphere the fan is exhausting into.

Whether mitigation “works” is not a meaningful question in the academic sense. It does. The meaningful questions are whether the specific system in your home was designed correctly, whether it was installed to AARST standards, whether the commissioning test verified the reduction, and whether the system is still running on the day you ask.

What failure looks like

Radon mitigation systems fail in a small number of recognizable ways.

The fan dies. Over five to ten years, fan bearings wear, seals degrade, and the motor eventually stops. When it does, the manometer equalizes and the system is silent. If the homeowner never looks at the manometer, the failure can go undetected for years. Fan replacement is typically a one- to two-hundred-dollar part plus an hour of labor, unless the original installation routed the pipe in a way that makes fan access difficult.

The pipe cracks or disconnects. Usually at a glue joint that was under-cured or at a penetration that shifted during seasonal slab movement. A cracked pipe on the vacuum side of the fan is less dangerous than one on the pressure side, but both cause the pressure field to collapse. The manometer will show it.

The slab develops new cracks. Over long time scales, foundation settling can create new openings that the original sealing job didn’t catch. This is more of a maintenance issue than a system failure — the ASD pressure field usually overwhelms the effect of small new cracks — but it can incrementally reduce system performance in edge cases.

The system was never actually working. This is the most pernicious failure mode because it’s invisible from the outside. An installer who skipped PFE testing, put a too-small fan on a too-large foundation, or cored the suction point in the wrong location can produce a system that looks exactly like a good one but never hit the target. The only way to catch this is the post-mitigation test. Anyone who buys a home with an existing radon system should request the post-mitigation test results along with the installation documentation, and if those results don’t exist, should perform their own retest before closing.

The thirty-year view

A radon mitigation system, properly installed, is expected to last the structural lifetime of the foundation it’s attached to. Fans are the only component with a realistic service life limit, and they are inexpensive and quick to replace. The pipe, the seals, and the sub-slab plenum itself will outlast the occupants. AARST recommends a system inspection every two years and a retest of the home every two years, both of which are simple enough that a conscientious homeowner can schedule them around other routine maintenance.

Over thirty years, the realistic total cost of ownership for a typical residential ASD system is the initial installation (roughly fifteen hundred to three thousand dollars in 2026), plus two or three fan replacements (two hundred to four hundred dollars each), plus thirty years of electricity (roughly two to four thousand dollars at current rates), plus fifteen retests (seven hundred and fifty to fifteen hundred dollars). The lifetime all-in is in the range of five to seven thousand dollars.

Weighed against a documented reduction in lung cancer risk — radon is classified by the WHO and the U.S. Surgeon General as the second-leading cause of lung cancer after smoking and the leading cause among non-smokers — the math is not subtle. A radon mitigation system is one of the highest-value mechanical interventions you can make in a home. It is also one of the quietest: once it’s installed and verified, it simply runs, continuously, for decades, and the problem it was installed to solve stops being a problem.

That’s what a radon mitigation system does. It cancels a pressure gradient, captures a gas at its source, and keeps doing it for as long as you keep the fan plugged in. The rest is engineering detail.

Frequently asked questions

Do radon mitigation systems really work?

Yes. Active soil depressurization, the technique used in more than ninety percent of residential installations, is supported by decades of field data showing eighty to ninety-nine percent reductions in indoor radon levels when the system is designed and installed correctly. The EPA and AARST both treat the effectiveness of the technique as established. The real variable is installation quality, which is why post-mitigation testing is required and why homeowners should verify the system is reaching its target after commissioning.

What’s the average cost of a radon mitigation system?

Most residential installations in 2026 fall between fifteen hundred and three thousand dollars. Simple single-suction-point systems on accessible slabs with good sub-slab permeability can come in under fifteen hundred. Complex multi-zone foundations, homes with finished basements requiring careful routing, or installations requiring multiple suction points can run three to five thousand. Ongoing costs are the fan’s electricity (seventy to one hundred forty dollars per year) and occasional fan replacement every eight to twelve years.

What houses are most likely to have radon?

Any house can have elevated radon — the EPA has documented high levels in every state — but the highest concentrations are associated with specific geological formations rich in uranium-bearing rock. States with the highest average indoor radon levels include Iowa, Pennsylvania, Ohio, Colorado, Montana, Wisconsin, Minnesota, and parts of the Appalachian, Rocky Mountain, and Upper Midwest regions. Homes with basements, homes with sealed sumps, and homes with crawl spaces over exposed dirt are typically at higher risk than slab homes, but the only reliable way to know a specific house’s level is to test it.

How can I reduce radon naturally?

Opening windows and running ventilation fans can temporarily lower indoor radon levels but not to a sustainable or reliable degree in any climate where closing the windows is necessary. Sealing foundation cracks without installing an active depressurization system has been proven unreliable on its own — the EPA and sosradon.org both explicitly note that sealing alone is not a durable mitigation technique. The only approach that consistently and durably reduces radon to below the action level is active soil depressurization or one of its variants (sub-membrane depressurization for crawl spaces, drain tile suction for homes with perimeter drainage). “Natural” alternatives do not work at the level required to protect occupants over time.

Should I buy a house with a radon mitigation system?

Generally yes, provided three things check out. First, the system should have AARST-compliant labels showing the installer, installation date, and pre-mitigation radon level. Second, the manometer should show a clear, stable offset indicating the fan is running under vacuum. Third, the seller should be able to produce post-mitigation test results proving the system achieved its target, and ideally a more recent test within the last two years confirming it’s still working. A home with a professionally installed, documented, functioning mitigation system is a safer purchase than an untested home that might have an unknown radon problem.

How long does a radon mitigation system last?

The pipe, seals, and sub-slab plenum are expected to last the life of the foundation. The fan is the only component with a defined service life and is typically warranted for five years, with real-world lifespans between eight and twelve years before replacement becomes advisable. Regular inspection of the manometer catches fan failures within days of occurrence. A well-maintained system, tested every two years and with the fan replaced on schedule, can realistically operate for the full thirty-year structural lifetime of most homes without meaningful degradation in performance.