Convert nanometers to micrometers, millimeters, ångströms, inches, and more. Visible light spectrum indicator, scale reference table, and batch mode.
The nanometer (nm) is the standard unit for measurements at the atomic and molecular scale — semiconductor nodes, light wavelengths, nanoparticles, biological structures, and thin-film coatings are all specified in nanometers. Converting between nm and other length units (micrometers, millimeters, ångströms, inches) is essential in nanotechnology, optics, materials science, and semiconductor manufacturing.
One nanometer is 10⁻⁹ meters — one billionth of a meter. That's roughly the width of 10 hydrogen atoms side by side. Modern semiconductor chips have transistor gates as small as 2 nm, while visible light ranges from 380 nm (violet) to 700 nm (red). The ångström (1 Å = 0.1 nm), still used in crystallography and spectroscopy, adds another unit to the mix.
This converter supports eight input units, displays results in six simultaneous outputs, includes a visible-light spectrum color indicator, and provides a scale reference table that contextualizes nanometer values against real-world objects from atoms to human hair.
Working at the nanoscale means juggling units that span enormous orders of magnitude — from ångströms to millimeters. Manually converting while tracking the correct power of ten is error-prone, especially under time pressure in a lab or fab setting.
This converter eliminates that mental overhead with instant multi-unit output, scientific notation, and visual context (the light spectrum indicator). The batch mode is especially useful for processing spectrometer data or dimension lists from AFM/SEM measurements.
1 nm = 10⁻⁹ m = 10⁻⁶ mm = 10⁻³ µm = 10 Å 1 nm = 3.937 × 10⁻⁸ inches General: target = source × (nm per source unit) ÷ (nm per target unit)
Result: 0.55 µm
550 nm ÷ 1,000 = 0.55 µm. This wavelength corresponds to green light, near the peak sensitivity of the human eye.
The nanometer regime (1–1,000 nm) is where quantum effects begin to dominate material behavior. At this scale, gold nanoparticles appear red or purple rather than gold, carbon arranges into nanotubes and graphene with extraordinary strength, and semiconductor devices exploit quantum tunneling. Understanding and converting nanometer measurements accurately is fundamental to modern technology.
| Unit | Symbol | Relation to nm | Typical use | |---|---|---|---| | Picometer | pm | 0.001 nm | Nuclear radii, atomic physics | | Ångström | Å | 0.1 nm | Crystallography, bond lengths | | Nanometer | nm | 1 | Semiconductors, optics, biology | | Micrometer | µm | 1,000 nm | Microfabrication, biology, coatings | | Mil (thou) | mil | 25,400 nm | PCB trace width, paint thickness |
The electromagnetic spectrum extends far beyond visible light (380–700 nm). Ultraviolet light used in photolithography ranges from 13.5 nm (EUV) to 365 nm (i-line). Infrared communication wavelengths are 850–1,550 nm. X-rays are 0.01–10 nm. Each domain has its preferred units — this converter bridges them all from a nanometer baseline.
1 µm = 1,000 nm. The prefix "micro" is 10⁻⁶ and "nano" is 10⁻⁹, so the ratio is 10³.
An ångström (Å) equals 0.1 nm or 10⁻¹⁰ m. It is historically used in crystallography and spectroscopy, though the SI recommends using nm or pm instead.
Visible light ranges from about 380 nm (violet) to 700 nm (red). The converter shows a color indicator when your value falls in this range.
A sheet of paper is about 100,000 nm thick. A human hair is about 80,000–100,000 nm wide. 1 nm is roughly the length of 3–4 water molecules.
It refers to the transistor gate length or node designation. A "5 nm" chip has features approximately 5 nm in critical dimension, though the naming has become more of a marketing term than a literal measurement.
Yes — 1 inch = 25,400,000 nm. The converter handles this and shows results in scientific notation for readability.