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BeNano 180 Zeta Max Nanoparticle Analyzer - Analytical Instruments & Consumables - Bettersize Inc. - MSE Supplies
BeNano 180 Zeta Max Nanoparticle Analyzer - Analytical Instruments & Consumables - Bettersize Inc. - MSE Supplies
BeNano 180 Zeta Max Nanoparticle Analyzer - Analytical Instruments & Consumables - Bettersize Inc. - MSE Supplies
BeNano 180 Zeta Max Nanoparticle Analyzer - Analytical Instruments & Consumables - Bettersize Inc. - MSE Supplies
Bettersize Inc.

BeNano 180 Zeta Max Nanoparticle Analyzer

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BeNano 180 Zeta Max Nanoparticle Analyzer

MSE Supplies is an authorized distributor of Bettersize Instruments. The product is sold for US customers only.

Introduction

BeNano 180 Zeta Max uses Dynamic Light Scattering (DLS), Static Light Scattering (SLS), Electrophoretic Light Scattering (ELS), sedimentation-based sizing, optical refraction, and Light Extinction-Dynamic Light Scattering (LEDLS) to measure particle size, molecular weight, rheological properties, zeta potential and its distribution, particle concentration of nanoparticles, and liquid refractive index. The system is equipped with a 50 mW, 671 nm solid-state laser (10 mW, 633 nm He-Ne laser available upon request) and an APD detector. Scattered light is collected at both 173° and 90° for size and molecular weight measurements. The 173° detection position automatically adjusts according to the sample’s scattering ability to ensure accuracy across a wide concentration range, while the 90° optics allows size measurements with as little as 3 μL of sample. Scattered light is collected at 12° in the forward direction for zeta potential measurements.
The BeNano system applies Phase Analysis Light Scattering (PALS) technology, combining fast-field reverse (FFR) and slow-field reverse (SFR) data to obtain both the average zeta potential and its distribution. Measurements are performed using disposable folded capillary cells to avoid cross-contamination. Optical signals are efficiently collected and transmitted through a single mode fiber-based system.
A 0° module equipped with a PD detector and a CMOS detector enables particle concentration, refractive index, and sedimentation-based size measurements.
Particle size: 0.3 nm - 15 μm
Zeta potential measurement range: No actual limitation
Mobility: > ±20 μm·cm/V·s
Molecular weight: 342 Da – 2 x 10^7 Da
Refractive index: 1.2 - 1.6
Particle concentration: 1x10^8 particles/mL - 1x10^12 particles/mL
Sedimentation-based size: 1 μm - 50 μm

A high-performance Peltier temperature control module precisely regulates the cuvette temperature between -15°C and 120°C. The BeNano research-grade software provides over 100 output parameters, standardized SOP programs, statistical reporting, and an integrated report designer. The software is backward compatible.
The main unit includes 100 PS cuvettes, 50 caps, one glass cuvette,one capillary sizing cell, one RI cuvette, and 10 folded capillary cells.

Key Features

1. Size Measurement 

Dynamic Light Scattering (DLS), also known as Photon Correlation Spectroscopy (PCS) or Quasi-Elastic Light Scattering (QELS), is a technique used to determine particle size by analyzing the Brownian motion of particles in a dispersion.DLS is based on the principle of Brownian motion, which relates particle size to velocity—smaller particles diffuse more rapidly, while larger particles move more slowly. The scattering intensities of the particles are detected by an avalanche photodiode (APD) and then converted into a correlation function. From this correlation function, a mathematical algorithm can be applied to obtain the diffusion coefficient (D). The hydrodynamic diameter (DH) and its distribution can be calculated using the Stokes-Einstein equation, which relates the diffusion coefficient to the particle size.

the Stokes-Einstein equation

Fighure-Intensity Fluctuations-of-Small-Particles-and-Large-Particles

2. Zeta Potential Measurement 

In aqueous systems, charged particles are surrounded by counter-ions that form an inner Stern layer and an outer shear layer. Zeta potential is the electrical potential at the interface of the shear layer. A higher zeta potential indicates greater stability and less aggregation of the suspension system. Electrophoretic light scattering (ELS) measures electrophoretic mobility via Doppler shifts of scattered light, which can be used to determine the zeta potential of a sample by Henry's equation.

Colloidal Stability

Stable particle system Unstable particle system
Stable-particle-system Unstable-particle-system
  • High repulsion force of particles
  • High zeta potential
  • Flocculation, aggregation, sedimentation
  • Low or zero zeta potential

 

3. Molecular Weight Measurement 

Static light scattering (SLS) is a technique that measures scattering intensities to calculate the weight-average molecular weight (Mw) and the second virial coefficient (A2) of a sample using the Rayleigh equation.

the-Rayleigh-equation

where c is the sample concentration, θ is the detection angle, Rθ is the Rayleigh ratio used to characterize the intensity ratio between the scattered light and the incident light at the angle of θMw is the sample’s weight-average molecular weight, A2 is the second virial coefficient, and K is a constant related to (dn/dc)2.

Features & Benefits

  • Non-invasive technique
  • Suitable for particles dissolved in liquid
  • Measures molecular weight of samples smaller than 30 nm
  • Provides second virial coefficient A2, indicating the intermolecular interactions

Debye Plot

4. Microrheology Measurement 

Dynamic Light Scattering Microrheology (DLS Microrheology) is an economical and efficient technique that utilizes dynamic light scattering to determine rheological properties. By analyzing the Brownian motion of colloidal tracer particles, information about the viscoelastic properties of the system, such as viscoelastic modulus, complex viscosity and creep compliance, can be obtained with the generalized Stokes-Einstein equation.

Features & Benefits

  • Investigates rheological behaviors by measuring the thermally-driven motion of tracer particles within a material being studied 
  • Facilitates the measurement of a broad frequency range in a single measurement 
  • Suitable for dilute, weakly structured solutions
  • Delivers fast results in 1–2 minutes with easy operation
  • Offers rheological insights across a wide temperature range from -15°C to 120°C
  • Complements conventional mechanical rheology

5. Flow Mode Measurement 

DLS flow mode provides a high-resolution size result of a complex, polydisperse system. When combined with front-end separation equipment such as GPC/SEC or FFF, particles are separated into monodisperse fractions and flow through the BeNano in sequence by size. The size of each fraction is continuously measured and summed into a high-resolution size distribution. 

BeNano-18BeNano-DLS-flow-mode

BeNano can acquire RI or UV signals, offering a more accurate volume and number distributions independent of algorithm compared to a batch-mode measurement.

Features & Benefits

  • DLS analyzer connecting with GPC/SEC, FFF, etc.
  • Receiving up to 3 signals from RI, UV, or other detectors 
  • 27 μL low-volume flow cell to avoid band broadening
  • Size resolution as high as 1.3:1
  • Size distributions weighted by number and volume, in addition to intensity
  • Suitable for complex, polydisperse systems such as proteins, polymers, etc.

6. Temperature Trend Measurement 

Features & Benefits

  • Programmed temperature trend measurement from -15°C to 120°C 
  • Important for analyzing particle size and zeta potential across varying temperatures
  • Easy examination of protein formulation stability 
  • Accelerates real-time aging through elevated temperature simulation

Size vs. Temperature trend measurement of the BSA proteinSize vs. Temperature trend measurement of the BSA protein

7. Transmittance Measurement 

Features & Benefits

  • Measures transmittance rapidly by detecting the light intensity transmitted through the sample
  • Requires a minimum sample volume of 3 μL
  • Sensitive indicator for evaluating batch consistency in industrial products
  • Quantitative tool for identifying sample instability

Transmittance measurement monitoring sample instability

Transmittance measurement monitoring sample instability

8. Refractive Index Measurement 

The BeNano 180 Zeta Max can determine the refractive index (RI) measurement of liquids with outstanding precision. A patented wedge-shaped cuvette holds the liquid sample while the CMOS detector measures the deflection of the light path after it traverses the liquid to calculate the RI.

Measurement Parameters

  • Positions of the light spot centers
  • Refractive index of the liquid being measured

Potential distribution at particle surfaceFeatures & Benefits

  • Patented technique supports a broad refractive index range from 1.2 to 1.6
  • Requires only two calibration references and utilizes linear calibration suitable for extrapolation
  • No tracer particles or prior knowledge of viscosity are required
  • Enables DLS and ELS measurement for dispersants with unknown refractive indices
  • Suitable for both organic and aqueous solvents

Refractive-Index-Measurement

A calibration curve is established by measuring the light spot position for two references with known refractive indices, then used to determine the refractive index of unknown samples.

9. Concentration Measurement 

The BeNano measures particle volume fraction and number concentrations in particles per milliliter (particles/mL) for each population through the patented LEDLS technique. 

The incident light passes through the sample and reaches a photodiode detector, which records the transmitted intensity. By comparing it with that of a blank solution and combining the data with the particle size distribution from dynamic light scattering, the particle concentration is determined.

Measurement Parameters

  • Volume fraction (%) of each particle population
  • Number concentration (particles/mL) of each particle population

Features & Benefits

  • Enables fast measurement with single-angle Detection
  • Simplifies sample preparation with no need for calibration
  • Ideal for screening-type measurements
  • Suitable for both aqueous and organic samples

Concentration-Measurement

By analyzing individual population concentrations, users can make informed decisions on sample preparation, formulation adjustments, or further analysis.

10. Sedimentation Size Measurement 

The BeNano 180 Zeta Max provides particle size results based on the sedimentation method. The sedimentation rate of particles is directly related to their size, with larger particles settling faster. The PD detector monitors the changes in transmitted intensity over time, enabling the determination of particle size and distribution for particles up to 50 microns.

Schematic-of-sedimentation-methodSchematic of sedimentation method

Measurement Parameters

  • D10, D50, D90
  • Span
  • Volume-weighted Mean Diameter D[4,3]
  • Size Distributions Weighted by Volume

Features & Benefits

  • Expands size measurement range up to 50 μm 
  • Suitable for samples containing both nanoparticles and microparticles, meeting the needs of broad distribution samples
  • Provides volume-based size distributions for micron-sized particles, consistent with laser diffraction results
  • Achieves up to 1.5x size resolution for multiple peaks

11. pH Autotitration Measurement 

The BAT-1 + Degasser units integrate seamlessly with the BeNano 180 Zeta Max for automatic acid-base titration and isoelectric point (IEP) determination. The system automatically enables sample flow during measurement, ensuring high efficiency, consistent, operator-independent results as well as precise titration.

BAT-1 Autotitrator and optional degasser

An optional degasser is available to remove dissolved gases from titrants. Preventing bubbles improves the accuracy of zeta potential measurements.

Measurement Parameters

  • Zeta potential vs. pH 
  • Size vs. pH 
  • Size and Zeta Potential vs. pH 
  • Conductivity vs. pH
  • Isoelectric point

Features & Benefits

  • Accurate size and zeta potential analysis from pH 1 to 13 
  • Enhanced safety with minimal exposure to corrosive liquids 
  • Automated workflow reduces training needs and researcher workload 
  • Fewer manual steps minimize human error
  • Completes each measurement cycle in as little as 30 minutes
  • Smart Titration: Based on the initial pH and the target pH, the required titrants can be chosen automatically via the software

size-and-zeta-potential-vs-pH-curve

The software can automatically generate the size and zeta potential vs. pH curve and identify the isoelectric point (IEP).

Specifications

Functionality Parameter BeNano 180 Zeta Max
Size measurement Size measurement range 0.3 nm – 15 μm*
Sample volume 3 μL – 1 mL*
Detection angle 90° & 173° & 11.2°
Analysis algorithm Cumulants, General Mode, CONTIN, NNLS
Upper limit of concentration range 40% w/v*
Detection position Movable
Zeta potential measurement Detection angle 12°
Zeta potential measurement range No actual limitation
Electrophoretic mobility > ± 20 μm·cm/V·s
Conductivity 0 – ≥270 mS/cm
Sample volume 0.75 – 1 mL
Sample size 1 nm – ≥120 μm*
Other measurements Molecular weight (Mw) measurement 342 Da – 2 × 107  Da*
DLS microrheology measurement MSD, G', G'', η*, J
Refractive index measurement 1.2 – 1.6
Concentration measurement 1 × 108  particles/mL – 1 × 1012 particles/mL*
Sedimentation particle size measurement  1 μm – 50 μm*
System parameter Temperature control range -15 ℃ – 120 ℃ , ± 0.1 ℃
Condensation control Dry air or nitrogen
Laser source 50 mW Solid-state laser, 671 nm†, Class 1
Correlator Up to 4000 channels, 1011 linear dynamic
Detector Avalanche photodiode (APD)
Intensity control 0.0001% – 100%, manual or automatic
Dimensions (L x W x H) 24.61 × 15.75 × 9.65 in (57.32 lb)
Power supply AC 100 – 240 V, 50 – 60 Hz, 4A
Compliance 21 CFR Part 11, ISO 13321, ISO 22412, ISO 13099

 

Download the manual here:

[BeNano] BeNano User Manual.pdf