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How many nuclear reactors would it take to power New York?

Scenario estimates of how many reactors of various sizes would be required to cover the New York–Newark–Jersey City, NY-NJ metro's annual electricity demand — and what it would take with other power sources.

Population
20,112,448
Annual electricity demand
144,279,576 MWh
Primary state
NY

Reactors needed to power New York

Switch between reactor sizes. Each tab shows the count, the icon grid scaled to that count, and rough capital cost bands. Default view is large reactors — the fewest, biggest units.

Reactors needed
16
× 1,117 MWe units
93% capacity factor

Conventional gigawatt-scale plants like the AP1000 deliver firm baseload power with the smallest land footprint per MWh of any source. Build times are 7–12 years for first-of-a-kind delivery; the largest tradeoff vs alternatives.

Capital cost (rough)
Mid: NREL ATB 2024 · High: delivered Vogtle/NuScale
$125.1B$178.7B$268.1B
Find out more about large reactorsTry the compare tool

New York's current energy usage

Where the metro's grid actually gets its power today, and how its electricity demand has trended over the last 25 years.

Today's grid mix
eGRID 2023 subregion NYCW — NPCC NYC/Westchester
98% Natural gas
largest source · 2023
Natural gas 98.2%
Other 1.2%
Oil 0.5%
Solar 0.1%

Replacing the fossil portion (99% of generation) with nuclear would avoid roughly 61,554,10469,557,205 tons of CO₂ per year for this metro's share of demand. Range uses EPA eGRID 2023 Total Output rate (low) and Non-baseload rate (high) for NYCW. See methodology.

Annual electricity demand
NY state total — all sectors
-0.5%
20012025
050M100M150M200M200120052010201520202025

What it takes to power New York with alternative energy sources

Same annual MWh as the reactor scenarios — just translated to other source archetypes. Variable sources (solar, wind) include a firm-equivalent figure for storage-backed 24/7 power. Switch tabs to compare.

Utility solar farm (100 MW DC)
659
units · 100 MW each
164.8M panels (≈400W each)
Firm equivalent (with storage)
2,6483,636
Units needed for round-the-clock firm power equivalent to one baseload reactor. Range covers oversizing + storage + curtailment modeling (NREL Standard Scenarios + Lazard LCOE+LCOS).
Land
618 sq mi
Capacity factor
25%
CO₂ (annual)
Zero
Per MWh CO₂
0 lb

Variable output. Raw count assumes same annual MWh; firm equivalent accounts for storage and oversizing needed for 24/7 power.

Find out more about utility solar farmCompare side-by-side

All sources, scaled to New York

Every source overlaid on the metro outline at true scale. The visual gut-check on land use: nuclear's footprint nearly disappears against firm-equivalent renewables.

All sources, scaled to New York-Newark-Jersey City

Each colored square shows the land area a single source would need to cover this metro's entire 144.3 TWh of annual electricity demand — drawn at the same scale as the metro outline below it. Solar and wind use firm-equivalent capacity (with storage) per NREL Standard Scenarios.

Onshore wind
2,860 sq mi · 42.8% of metro
Utility-scale solar PV
736 sq mi · 11.0% of metro
Nuclear · Large Reactor
20.8 sq mi · 0.31% of metro
Coal-fired plant
17.2 sq mi · 0.26% of metro
Natural gas (combined cycle)
2.3 sq mi · 0.04% of metro
Local resource: Modest solar; decent coastal wind; regional hydro from Niagara/St. Lawrence.
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Data provenance

Demand basis
NY state per-capita × metro population (v2 methodology, 2025 basis year)
Demand period
historical state trend: 2001–2025
Population source
U.S. Census Vintage 2025 estimates
Reactor cost basis
NREL ATB 2024, with widened bands for FOAK uncertainty
Grid mix source
EPA eGRID 2023 (subregion NYCW)
Source comparisons
Hardcoded archetypes — see methodology page

These figures are screening-level scenario estimates. They are not forecasts, project proposals, or permitting determinations.