Bragg Peak Calculator

Inputs

Choose a beam and medium, then compute the peak location and a relative curve.

Particle

For ions, energy is treated as MeV per nucleon (approximation).

Beam energy

Proton (MeV)

Mode

SOBP blends layers to widen the high-dose region.

Medium density preset

Custom density (g/cm³)

Use bulk density for a first-pass estimate.

Table step size (mm)

Smaller steps create larger tables and smoother exports.

Max depth (cm) (optional)

Leave blank or zero to auto-size around the range.

Entrance dose (%)

Baseline relative level before the peak builds up.

Rise power

Controls how fast dose rises with depth.

Peak width σ (mm)

Approximate range straggling and energy spread.

Peak amplitude

Higher values increase peak-to-entrance ratio.

Distal tail (%)

Small post-range tail fraction of peak amplitude.

SOBP width (cm)

Target width near the distal end of the range.

SOBP layers

More layers can smooth the plateau (slower).

Layer weighting

Least-squares uses a small system solve (approx).

Reset

Example data table

Typical proton energies and approximate ranges in water (ρ=1.00). Values are rounded and meant for quick checks.

Energy (MeV)	Estimated range (cm)	Approx peak depth (cm)	Use case note
70	≈4.06	≈4.00	Shallow targets and small phantoms
100	≈7.63	≈7.51	Head and neck depth checks
150	≈15.64	≈15.41	Mid-depth coverage in water
200	≈26.02	≈25.63	Deeper regions, thicker slabs
250	≈38.62	≈38.04	Near maximum clinical depth

Formula used

This tool estimates the particle CSDA range (distance to near-complete energy loss) using a power-law approximation:

R_w(cm) ≈ a · E^b with a = 0.0022 and b = 1.77 (protons in water)
R(cm in medium) ≈ R_w / ρ where ρ is density in g/cm³

A smooth Bragg curve is then generated as a sum of a baseline entrance term, a gradual rise term, and a Gaussian peak near the end of range. For the spread-out option (SOBP), multiple layers with shorter ranges are blended across a selected width.

Important: this is an educational model. For accurate work, use validated stopping-power tables (e.g., PSTAR/ASTAR or ICRU datasets) and beamline-specific measurements.

How to use this calculator

Select the particle type and enter beam energy.
Choose a medium density preset, or enter a custom density.
Pick Single-energy for one sharp peak, or SOBP for a widened plateau.
Adjust smoothing controls (step size, peak width, amplitude) to match your scenario.
Click Calculate. Results appear above the form.
Use Download CSV or Download PDF for reports.

Bragg peak guide

1) What the Bragg peak shows

Charged particles deposit modest dose at entry, then rise sharply near end of range. That maximum is the Bragg peak, and its depth tracks the initial energy. This tool reports peak depth from the modeled curve and normalizes peak dose to 100%.

2) Proton energy and depth numbers

In water-like tissue, common proton energies span about 70–250 MeV. With the same range law used here, 70 MeV reaches ~4.1 cm, 100 MeV ~7.6 cm, 150 MeV ~15.6 cm, 200 MeV ~26.0 cm, and 250 MeV ~38.6 cm. Use these as quick sanity checks

3) Density changes shift the peak

Range scales roughly with inverse density (R ∝ 1/ρ) in this simplified model. Moving from water (ρ≈1.00) to lung (ρ≈0.30) increases range by ~3.3×, while bone (ρ≈1.85) shortens range to ~0.54×. Presets help compare media quickly

4) Peak width, step size, and smoothing

The σ input (mm) widens or narrows the Gaussian peak term. Smaller σ yields a sharper peak and steeper distal edge, while larger σ mimics energy spread and range straggling for comparison studies. Step size controls sampling: 20 cm depth with 2 mm steps gives ~101 rows, while 1 mm gives ~201.

5) Entrance dose and peak ratio

Dose is normalized so the maximum equals 100%. The entrance value depends on entrance %, σ, and amplitude settings. The peak-to-entrance ratio is a quick contrast indicator between entry and end-of-range dose. Higher amplitude usually increases this ratio.

6) Distal falloff metric (80→20%)

Distal falloff is the distance from 80% to 20% on the post-peak side. Smaller numbers indicate a sharper cutoff. With a 2 mm step, the falloff is effectively quantized in ~2 mm increments, so smaller steps improve the readout resolution.

7) Spread-out Bragg peak (SOBP) layers

A spread-out peak is formed by summing multiple layers with shorter ranges. If you select width 4 cm and 9 layers, layer ranges span that 4 cm window from distal to proximal. Weights are normalized to sum to 100%, and the least-squares option aims to flatten dose across the window.

8) Using the table for quick QA

Exports include depth, normalized dose, and a cumulative relative integral. For QA-style checks, expect a smooth rise, a clear maximum near computed range, and a monotonic decrease beyond range. The cumulative column helps compare overall curve area between two runs, even when peak shapes differ.

FAQs

1) What is “CSDA range”?

It is the approximate depth where the particle has lost nearly all kinetic energy, assuming continuous slowing down. Real beams have spread, so measured range can differ slightly.

2) Is this accurate enough for treatment planning?

No. It is an educational approximation for trends and rough checks. Planning needs validated stopping-power tables, beamline measurements, and a clinically verified dose engine.

3) Why are ions labeled MeV/u?

For heavier ions, energy is often expressed per nucleon. This tool uses a simple A/Z² scaling and treats the input as MeV per nucleon for a first-pass comparison.

4) How do I choose step size?

Use 1–2 mm for smoother curves and better falloff resolution. Use 3–5 mm when you need faster runs and smaller exports. Very small steps create large tables.

5) What does the peak width σ control?

It widens the modeled Bragg peak and softens the distal edge. Larger σ approximates added energy spread and straggling, while smaller σ produces a sharper, narrower peak.

6) How is the SOBP “least-squares” option done?

The tool builds several layer curves, then solves a small linear system over plateau depths to find weights that make the summed dose close to flat. Weights are normalized and clipped nonnegative.

7) What does “cumulative (rel·cm)” mean?

It is a trapezoidal integral of normalized dose versus depth, in relative units. It helps compare overall area under the curve between runs, but it is not an absolute physical dose.