Set particle count and interaction strengths easily. Validate thermostat consistency and estimate key scales fast. Export tables to CSV or PDF for reports today.
F_C(r) = a (1 - r/rc) for r < rc, otherwise zero.γ, with a characteristic time τ = m/γ.σ² = 2 γ kB T. Here kB = 1.V = L³ and ρ = N/V. If you choose density mode, L = (N/ρ)^(1/3).dt_max ≈ min(0.10τ, 0.05 sqrt(m rc / a)) for a conservative safety margin.rc and a to match compressibility targets.γ and T, then enable auto σ for consistency.dt and steps; keep dt below the guideline.| Scenario | N | ρ | rc | a | γ | T | σ (auto) | dt | Guideline dtmax |
|---|---|---|---|---|---|---|---|---|---|
| Typical fluid | 2000 | 3.0 | 1.0 | 25.0 | 4.5 | 1.0 | 3.000 | 0.020 | 0.017 |
| Lower friction | 4000 | 3.0 | 1.0 | 25.0 | 2.0 | 1.0 | 2.000 | 0.020 | 0.025 |
| Softer repulsion | 1500 | 3.0 | 1.0 | 15.0 | 4.5 | 1.0 | 3.000 | 0.030 | 0.022 |
Dissipative particle dynamics models hydrodynamic fluids with soft, short-range interactions and a built-in thermostat. Each bead follows Newton’s law in reduced units, while pair forces exchange momentum so that mesoscale flow and transport emerge without resolving atomistic detail.
This tool assumes kB = 1 and reports dimensionless scales. In many practical setups, densities near ρ ≈ 3 beads per cutoff volume and cutoffs rc = 1 are used. Conservative amplitudes around a = 15–35 often produce liquid-like compressibility, while still allowing large timesteps compared with atomistic methods.
The conservative term F_C(r)=a(1-r/rc) sets how strongly beads repel at short separation. Increasing a typically raises pressure and reduces density fluctuations. When you change a, keep an eye on the conservative timescale estimate tc≈sqrt(m rc / a) and tighten dt if tc becomes small.
DPD uses paired dissipative and random forces to maintain temperature while conserving momentum. For a consistent thermostat, the fluctuation–dissipation relation requires σ² = 2 γ T (with kB=1). The calculator shows the target σ and the temperature implied by your chosen σ, flagging mismatches beyond a small tolerance.
Neighbor statistics control both accuracy and noise. With a fixed cutoff, higher ρ increases the average number of interacting neighbors and typically smooths stress fluctuations. If you choose “Target density,” the tool computes L=(N/ρ)^{1/3} and reports the actual density N/L^3 so you can verify packing consistency.
The calculator provides a conservative maximum timestep using two constraints: a friction time τ=m/γ and a conservative time estimate tc. A safe rule is dt well below both, often in the range 0.005–0.03 for typical reduced parameters. If the check warns, reduce dt before increasing total steps.
Thermal speed is estimated as vth=sqrt(T/m), while an order-of-magnitude diffusion estimate is shown as D≈T/(mγ). The reported Peclet estimate Pe≈vth rc / D helps you gauge whether dynamics are more ballistic-like or diffusion-dominated under your chosen friction.
As a baseline, try N=2000, ρ=3, rc=1, a=25, γ=4.5, and T=1, with auto σ enabled. If the guideline suggests dt<0.02, set dt=0.01–0.015 and run 5000–20000 steps to cover a simulated time of 50–300 in reduced units.
Auto σ guarantees the fluctuation–dissipation relation for your chosen γ and T. Disable it only when you intentionally test nonequilibrium noise levels or match a legacy parameter set.
It indicates your σ is inconsistent with γ and T. In equilibrium DPD, inconsistency can bias the sampled temperature and alter transport. Adjust σ or switch on auto σ.
Higher a shortens the conservative timescale, while higher γ shortens the friction time. Both effects require smaller dt to integrate forces accurately and avoid numerical heating.
Pick N to fit your physical resolution and domain size. With density mode, the calculator sets L from N and ρ, so increasing N increases box size and reduces finite-size artifacts.
No. It is an order-of-magnitude guide based on friction and temperature. Actual diffusion depends on density, conservative interactions, and the chosen weight functions in a full DPD implementation.
Low ρ reduces the number of interacting neighbors inside rc. This can increase noise, weaken hydrodynamic behavior, and make pressure control sensitive. Many fluid setups use ρ near 3.
Yes for parameter checks and reporting. The CSV and PDF summarize inputs and derived scales. For simulation, ensure your integrator and weight functions match the assumptions behind the thermostat relation.
Important Note: All the Calculators listed in this site are for educational purpose only and we do not guarentee the accuracy of results. Please do consult with other sources as well.