Wright State University

Dayton, OH · serves 16,469 · GroundwaterOH2902012

All clear

All monitored contaminants within federal limits. Last updated from the most recent CCR and EPA monitoring data available.

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Violations

No action needed

Minor violations on record, all resolved

All clear

PFAS

No action needed

No PFAS detected in this water system

not detected

All clear

Lead

No action needed

Low lead service line risk

no lead lines identified

All clear

Chromium-6

No action needed

Not detected in this water system

not detected

All clear

Lithium

Lithium not detected in this system

Not detected in this water system

not detected

All clear

Measured in your 2025 water report

From your utility's Consumer Confidence Report · 23 contaminants tested

ℹ

Above advisory guidelines

No federal limit exists. These reference values are from WHO or state guidelines.

Contaminant	Detected Level	Guideline	How Far Over
Hardness	499 mg/L	180 mg/L	~2.8× the limit

Above limit

Approaching limit

Within limits

Regulated contaminants — legally enforceable limits

Nitrate (as N)▸

0.11 mg/L

What is it?

Comes from fertilizer runoff, septic systems, and erosion of natural deposits. One of the most common groundwater contaminants in agricultural areas.

Why it matters

Nitrate above 10 mg/L can cause "blue baby syndrome" (methemoglobinemia) in infants under 6 months — it interferes with blood's ability to carry oxygen. Adults can tolerate higher levels.

What to do

If you have an infant on formula and your water is above 5 mg/L, consider using bottled water for formula preparation. Boiling water does NOT remove nitrate — it concentrates it.

What the research says

Multiple peer-reviewed studies have found neural tube defects, preterm birth, and low birth weight at concentrations as low as 5 mg/L — 2x below the US federal limit.

Ward et al., 2018 · Lin et al., 2023 · Clemmensen et al., 2023

Nitrate + Nitrite (as N)▸

0.11 mg/L

No additional information available for this contaminant.

Lead & copper — tested at your tap

Copper▸

0.58 mg/L

What is it?

Leaches from copper household plumbing and pipes. Some copper is a normal part of drinking water infrastructure.

Why it matters

Short-term exposure above the action level of 1.3 mg/L can cause gastrointestinal distress. Long-term exposure can cause liver and kidney damage. At typical detected levels (well below the AL), copper is not a health concern.

What to do

If above the action level, run your tap for 30 seconds before drinking. Copper levels decrease as water flows through the pipes.

Disinfection byproducts

DBAA▸

1.5 µg/L

What is it?

A brominated haloacetic acid formed in chlorinated water with elevated bromide. One of five HAAs regulated together as HAA5.

Why it matters

EPA has not established an individual MCLG for DBAA — there isn't enough data yet to identify a no-effect level. Regulated as part of HAA5 (60 µg/L), since the group is associated with cancer and developmental concerns.

What to do

Reduced by point-of-use carbon-block filtration (NSF/ANSI 53). Source-water treatment is the more effective control.

DCAA▸

2.9 µg/L

What is it?

A haloacetic acid formed when chlorine reacts with natural organic matter during disinfection. One of five HAAs regulated together as HAA5 (limit: 60 µg/L).

Why it matters

EPA classifies DCAA as a likely human carcinogen and sets the MCLG at zero. Animal studies show liver, neurological, and reproductive effects, and developmental concerns have been raised at high prenatal exposures. The HAA5 group limit reflects feasibility, not the MCLG.

What to do

DCAA forms in your utility's treatment process. Point-of-use carbon-block filters certified for VOC reduction (NSF/ANSI 53) can reduce HAAs. Running cold tap water briefly before drinking helps clear water that has sat in pipes where DBPs continue to form.

DBCM▸

8 µg/L

What is it?

A brominated trihalomethane formed when chlorine reacts with bromide-containing organic matter. More common in source waters with higher bromide levels — often coastal or groundwater systems.

Why it matters

EPA sets the MCLG at 0.06 mg/L based on liver and kidney effects. Some evidence suggests DBCM may be carcinogenic, though the data is less clear than for BDCM and bromoform. Regulated together with the other three trihalomethanes under TTHM.

What to do

Like other THMs, DBCM forms in the distribution system as chlorine reacts over time. A point-of-use carbon-block filter (NSF/ANSI 53) reduces it along with related compounds.

Chloroform▸

6.7 µg/L

What is it?

A disinfection byproduct formed when chlorine reacts with naturally occurring organic matter in source water. The most common of the four trihalomethanes.

Why it matters

Long-term exposure has been associated with increased risk of bladder cancer and possibly colorectal cancer. EPA classifies it as a probable human carcinogen and sets an MCLG of 0.07 mg/L based on liver effects. Regulated together with three other trihalomethanes under the TTHM standard (80 µg/L).

What to do

Chloroform levels are largely a function of how your utility manages disinfection. If TTHM is approaching the limit, a carbon-block filter (NSF/ANSI 53 certified for VOCs or specifically for trihalomethanes) at point-of-use reduces it. Letting cold water run for 30 seconds before drinking can also help, since chloroform forms in the distribution system.

BDCM▸

7.1 µg/L

What is it?

A brominated trihalomethane formed when chlorine reacts with organic matter and bromide in source water. One of four trihalomethanes regulated together under TTHM.

Why it matters

EPA classifies BDCM as a probable human carcinogen and sets the MCLG at zero, meaning the agency identifies no safe lifetime exposure level. Studies link it to bladder and colon cancer, and to reproductive and developmental effects at high exposures. The enforceable limit (80 µg/L for total TTHM) reflects what's feasible to achieve, not what's safest.

What to do

BDCM is formed in your utility's system, so reducing it generally means reducing total disinfection byproducts there. At point-of-use, a carbon-block filter certified for VOCs or trihalomethanes (NSF/ANSI 53) reduces BDCM along with other THMs.

Bromoform▸

3.2 µg/L

What is it?

A fully brominated trihalomethane, formed when chlorine reacts with high-bromide source water. More common in coastal and arid-region systems where source water naturally contains bromide.

Why it matters

EPA classifies bromoform as a probable human carcinogen, with an MCLG of zero. Animal studies show liver and intestinal tumors; human evidence is more limited but consistent with the other brominated THMs. Regulated under the TTHM standard (80 µg/L for the sum of all four).

What to do

Reducing bromoform usually means working at the source — your utility may need to adjust disinfection or pretreatment. At home, an NSF/ANSI 53 carbon-block filter reduces bromoform along with the other THMs.

TTHM▸

25 µg/L

What is it?

Formed when chlorine used to disinfect water reacts with natural organic matter. Includes chloroform, bromoform, and related compounds. The trade-off: disinfection prevents waterborne disease, but creates these byproducts.

Why it matters

Long-term exposure above the MCL of 80 µg/L (0.080 mg/L) is associated with increased cancer risk and possible reproductive effects. The MCL is based on a running annual average, not a single sample.

What to do

If your system is near or above the limit, an activated carbon filter (including pitcher filters like Brita) can reduce THMs. Running water for a minute before drinking also helps, as THMs are volatile and dissipate.

PFAS

PFPeA▸

0.5 ng/L

No additional information available for this contaminant.

Disinfectants — MRDL

Chlorine▸

1.2 mg/L

What is it?

Added intentionally to kill bacteria and viruses. A chlorine residual in your tap water means the disinfection is still active through the distribution system — this is by design.

Why it matters

The MRDL of 4 mg/L is the maximum allowed. Typical levels are 0.5–2 mg/L. Chlorine at normal levels is not a health concern — the disease risk from untreated water is far greater.

What to do

If you don't like the taste, let water sit in an open pitcher for 30 minutes or use an activated carbon filter. Both remove chlorine taste and odor.

OTHER

DISSOLVED INORGANIC CARBON▸

22 MG/L

No additional information available for this contaminant.

PHOSPHORUS, TOTAL▸

0.52 MG/L

No additional information available for this contaminant.

% of limit

Other measurements

These describe characteristics of the water that aren’t health risks at typical levels — mineral content, taste, hardness, and similar.

▸

8.1 SU· slightly basic

Alkalinity

▸

361 mg/L

Calcium

▸

17.9 mg/L

Chloride

▸

58 mg/L

(EPA secondary standard: 250 mg/L)

Orthophosphate

▸

1.8 mg/L

Sulfate

▸

7.4 mg/L

(EPA secondary standard: 250 mg/L)

TDS

▸

222 mg/L

(EPA secondary standard: 500 mg/L)

CCR data in early access — values are extracted from utility PDFs and may contain errors. Verify with your utility's 2025 CCR report.

Flagged for review

The following measurements were extracted from this system's Consumer Confidence Report but have been flagged for verification. These values are likely extraction or unit errors and have been removed from the chart above.

Contaminant	Reported Value	Limit	Reason
Lead	0.1 mg/L	0.015 mg/L	Flagged for review

Think this data is correct?

Source: WRIGHT STATE UNIVERSITY Consumer Confidence Report 2025 · Extracted by WaterScore

Measured data

Private Well Risk

Do you have or use a private well? Measured concentrations from nearby private wells sampled within 5 miles.

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8 sites within 10 mi

Nearby Superfund Sites

8 EPA Superfund sites within 10 miles. Proximity does not necessarily mean your water is affected.

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2 wells

Water Sources

Dayton pumps water from two groundwater wells drawing from local groundwater. Emergency backup sources are available if primary supplies are disrupted.

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Spatial context

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