Cantilevers for Biological Sample Measurements In Water
BioLever
In force curve measurement of biological samples in water, extremely soft and flexible with a small spring constant, delivering a light, soft touch with biological samples.
Measurement Environments Water Mode
Measurement Environments
Usable in varying measurement environments in water.
Measurement Environments Air Mode
Measurement Environments
Usable in varying measurement environments in air.
Measurement Modes Contact Mode
Measurement Modes
Soft cantilever for contact mode.
Measurement Modes AC Mode
Measurement Modes
High resonance frequency cantilever for AC mode.
Detection Signals Electrical Measurement
Detection Signals
Cantilevers for measuring electrical characteristics in addition to surface irregularities.
Detection Signals Friction Measurement
Detection Signals
Cantilevers for measuring friction in addition to surface irregularities.
Detection Signals Force Curve Measurement
Detection Signals
Cantilevers for measuring force curve in addition to surface irregularities.
Mechanical Properties
Mechanical Properties
Range of cantilevers from 0.006-85 N/m and 11-1600 kHz.
New Concept Chip
New Concept Chip
Perpendicular chip sidewalls greatly facilitate tweezer grabbing and handling.
TipView Design
TipView Design
Sharp probe is placed at the very end of the cantilever. TipView design facilitates exact probe positioning.
BioLever mini
Features a shrapened silicon probe and a small silicon nitride cantilever with a high resonance frequency in water, enabling high-resolution measurements of bio samples in water.
Measurement Environments Water Mode
Measurement Environments
Usable in varying measurement environments in water.
Measurement Environments Air Mode
Measurement Environments
Usable in varying measurement environments in air.
Measurement Modes Contact Mode
Measurement Modes
Soft cantilever for contact mode.
Measurement Modes AC Mode
Measurement Modes
High resonance frequency cantilever for AC mode.
Detection Signals Electrical Measurement
Detection Signals
Cantilevers for measuring electrical characteristics in addition to surface irregularities.
Detection Signals Friction Measurement
Detection Signals
Cantilevers for measuring friction in addition to surface irregularities.
Detection Signals Force Curve Measurement
Detection Signals
Cantilevers for measuring force curve in addition to surface irregularities.
Mechanical Properties
Mechanical Properties
Range of cantilevers from 0.006-85 N/m and 11-1600 kHz.
New Concept Chip
New Concept Chip
Perpendicular chip sidewalls greatly facilitate tweezer grabbing and handling.
TipView Design
TipView Design
Sharp probe is placed at the very end of the cantilever. TipView design facilitates exact probe positioning.
BioLever fast
Features an ultra-small cantilever with a high resonance frequency and a small spring constant, enabling high-speed measurement of bio molecular samples in water.
Measurement Environments Water Mode
Measurement Environments
Usable in varying measurement environments in water.
Measurement Environments Air Mode
Measurement Environments
Usable in varying measurement environments in air.
Measurement Modes Contact Mode
Measurement Modes
Soft cantilever for contact mode.
Measurement Modes AC Mode
Measurement Modes
High resonance frequency cantilever for AC mode.
Detection Signals Electrical Measurement
Detection Signals
Cantilevers for measuring electrical characteristics in addition to surface irregularities.
Detection Signals Friction Measurement
Detection Signals
Cantilevers for measuring friction in addition to surface irregularities.
Detection Signals Force Curve Measurement
Detection Signals
Cantilevers for measuring force curve in addition to surface irregularities.
Mechanical Properties
Mechanical Properties
Range of cantilevers from 0.006-85 N/m and 11-1600 kHz.
New Concept Chip
New Concept Chip
Perpendicular chip sidewalls greatly facilitate tweezer grabbing and handling.
TipView Design
TipView Design
Sharp probe is placed at the very end of the cantilever. TipView design facilitates exact probe positioning.
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