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Empty Liquid Crystal Cells


  • Seven Different Cell Gaps
  • Two Liquid Crystal Inject Holes
  • AR Coating (350 - 700 nm) on Both Sides

LCC1312-A

LCC1318-A

Filled Cell with Wires Attached

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Features

  • Models with Seven Different Cell Gaps Available
  • Anti-Reflective Coating (350 - 700 nm) on Both Sides
  • High Resistance Indium Tin Oxide (ITO) Conductive Layer (300 - 350 Ω/sq Resistance)
  • All Models Except 20 µm Cell Feature an Anti-Parallel PI Alignment Layer
  • Custom Cells Available Upon Request to Tech Support

Thorlabs’ empty liquid crystal cells are designed for testing liquid crystal compounds and materials. These cells are coated with an Indium Tin Oxide (ITO) conductive layer and a Polyimide (PI) alignment layer (20 µm version has no PI layer). Seven cells are available with various sized spacers to provide cell gaps from 3 µm to 20 µm, and all are designed for simple filling in the lab (See the Filling and ITO tab).

Our empty cells are optimized for high transmission in the visible range, using UV Fused Silica glass, a broadband anti-reflective coating, and thin film, high resistance ITO. If your application requires liquid crystal cells for other wavelength ranges, please contact us for such a custom cell.

Empty cells with cell gaps from 3 to 10 µm are rubbed and assembled for anti-parallel alignment of the liquid crystal. The LCC1324-A has a 20 µm gap and no polyimide alignment layer. This cell is designed for use with materials that do not require an alignment layer, such as Polymer Dispersed Liquid Crystal (PDLC) materials. Thorlabs can also provide cells with different alignment methods such as 90° twist, parallel alignment, or with custom PI material.

Item # LCC1310-A LCC1312-A LCC1314-A LCC1316-A LCC1318-A LCC1322-A LCC1324-A
Cell Gap 3 ± 0.3 µm 4 ± 0.4 µm 5 ± 0.5 µm 6 ± 0.6 µm 8 ± 0.8 µm 10 ± 1 µm 20 ± 2 µm
Cell Gap Uniformity 5% over the Entire Clear Aperture
ITO Resistance (See Below) 350 - 450 Ω/sq
AR Coating Ravg <0.5%, 350 nm – 700 nm
External Dimensions 17 ± 0.1 mm x 12 ± 0.1 mm x 6 ± 0.2 mm
Clear Aperture 10 mm x 10 mm
Surface Quality 40 -20 Scratch Dig
Surface Flatness λ/10 @ 633 nm
PI Alignment Anti-Parallel N/A
Glass Material UV Grade Fused Silica

Sheet Resistance
The resistance of a thin film is usually described using the sheet resistance (Rs) instead of the resistivity (ρ). Sheet resistance is defined as the ratio between the resistivity (ρ) and the film thickness (t), with units of ohms per square (Ω/sq). It is a more convenient parameter for users because the film thickness has been taken into account and only two dimensions (the length L and the width W) are needed to calculate the resistance of the thin film, which is R = Rs*L/W. Since a square has L = W, the resistance of a square of the thin film is constant and equal to the sheet resistance, regardless of the size of the square. Our liquid crystal cells are 12 mm x 15 mm, so the actual resistance is 15/12 times the sheet resistance.

Sample Liquid Crystal Cell Transmission
Click to Enlarge

Transmission of Unpolarized Light in a Liquid Crystal Cell Filled with a Typical Nematic LC Material

Recommended Filling Procedures

Filling Using the Capillary Effect

  • In a clean environment, remove the cell from the packaging. Place a drop of liquid crystal material on one of the filling ports and wait for the LC material to completely fill the cell. Note: Depending on the LC material and cell gap, this can take anywhere from 10 minutes to several hours.
  • After the cell is completely full, seal the two holes with UV glue (such as the NOA68) and cure the glue. Note: If you are using nematic LC material you will need to bake the filled cell for two hours at a temperature above the clearing temperature (i.e., the temperature at which the liquid crystal becomes isotropic) to get a homogenous alignment of the LC material.

Filling Using a Vacuum Chamber

  • In a clean environment, remove the cell from the package. Using UV glue (such as the NOA68), seal one hole and cure the UV glue.
  • Insert the cell into a vacuum chamber, place the liquid crystal material in a container under the cell (but not touching the cell), and hold the cell with a device that can later be lowered.
  • Evacuate the vacuum chamber to a level of 10 Pa, and heat the chamber to a temperature above the LC clearing point.
  • After the chamber has reached the required vacuum level and temperature, lower the cell so that the filling hole touches the LC.
  • Release the pressure in the chamber and the LC will fill the cell.
  • Slowly reduce the temperature back to room temperature.
  • Remove the cell from the chamber, seal the second hole with UV glue, and cure the glue.

Electrical Connections

After completing the filling using either method, use conductive epoxy such as EG58 to connect wires to the two ITO strips.

LCC25 Specifications
Electrical Specs
Adjustable Output Voltage ± 25 V
External Input Voltage 0 to 5 VDC Square Wave
Voltage Resolution 1.0 mV
Adjustable Internal Modulation Frequency 0.5 to 150 Hz @ 50% Duty Cycle
Switching Frequency 2,000 ± 5 Hz, 50% Duty Cycle
Slew Rate 10 V/µs
DC offset ±10 mV
Max Output Current 15 mA
AC Power 85 – 264 VAC, 47 – 63 Hz, 25 VA
Fuse Rating 125 mA, 5 x 20 mm SLO-BLO
Warm Up Time 30 Minutes
Physical Specs
External Input Connector BNC
External Input Enable Front Panel: INT/EXT enable Key
External Input Indicator Green LED
Output Connector BNC
Output Enable Front Panel: OUTPUT ENABLE Key
Output Indicator Green LED
Rotary Knob Digital Encoder
Display LCD 16 x 2
Power Switch Rocker Switch
USB interface USB Standard B Plug
Dimensions 5.75″ x 3″ x 12.2″
146 mm x 78 mm x 309 mm
Weight 3.6 lbs
Operating Temperature Range 10 to 40 °C
Maximum Relative Humidity 85%
Other Tilting Rubber-Padded Feet

The LCC25 liquid crystal variable retarder and polarization rotator controller produces a 2000 Hz square wave output with an amplitude that can be varied from 0 to 25 Vrms. The output amplitude can be set via the front panel controls, the USB interface, and the external input. Both the front panel and USB interface allow the user to select two voltage levels, Voltage 1 and Voltage 2. When the LCC25 is operated in the constant voltage mode, the output of the controller will be a 2000 Hz square wave with an amplitude equal to either of the two set voltage levels (Figure A). If the LCC25 controller is operating in the modulation mode, the output 2000 Hz square wave will be modulated in amplitude between the two voltage settings with a modulation frequency that can be set by the user to be between 0.5 and 150 Hz (Figure B).

The modulated mode can be used to measure the response time of the LC retarder.

External or remote control of the LCC25 is possible using the external input or the USB interface. The external input accepts a 0 to 5 VDC TTL signal that modulates the 0 to 25 Vrms output of the LCC25 between the two set voltages. The USB interface can be used to send line commands to the controller so that the LCC25 can be used in automated lab sequences.

In order to prevent the separation and build up of charges in the liquid crystal layer, the LCC25 will automatically detect and correct any DC offset in real time to within ±10 mV.

Mode 1
Figure A. A plot of the output voltage of the LCC25 Liquid Crystal Controller when it is being operated in the constant voltage mode.
Mode 2
Figure B. A plot of the output voltage of the LCC25 Liquid Crystal Controller when the ouptput voltage is being modulated between the two set voltages.
Screen Shot of the LCC25 Software
Click to Enlarge

Screen shot of the GUI interface in Modulation Mode.

Software for the LCC25 Controller

Software

Version 3.2.0

GUI Interface for controlling the Liquid Crystal Retarder Controller via a PC. To download, click the button below.

Software Download

GUI Interface
The GUI interface included with the software provides access to all of the settings of the liquid crystal retarder controller. For example, the user can select one of two user-defined voltages or a modulation mode that oscillates between these two voltages at a user-defined frequency. As shown in the above screen shot, the applied voltage is shown in a plot with respect to time. Both the output and external input can be turned on and off via the GUI. In addition, advanced features allow the user to define a custom waveform by specifying the starting voltage, ending voltage, the voltage step size, and the dwell time. The waveform may be previewed on the screen before it is output to the retarder, and it may be saved so that the LCC25 can be restarted quickly in the future. The GUI is available as a stand-alone or LabVIEW based version for flexibility in implementation.

Custom Software Development
Users may also use the provided C/C++ and LabVIEW software development kits for implementing the liquid crystal retarder controller with other instruments. Sample C++ code and LabVIEW programs help to illustrate how the C commands and LabVIEW VIs can be utilized. Full documentation on the available commands is provided with the software.


Posted Comments:
Nils Maasjost  (posted 2019-04-10 03:43:28.04)
Good morning, I've purchased LC-Cells and now trying to connect the cabels with the cell, but the suggested method of using EG58 led to a mess. Additionally I can't see out of the specs sheet, where I should connect the cabels. Could you give me any recommidations in this regard? Best regards Nils Maasjost
nbayconich  (posted 2019-04-12 03:06:27.0)
Thank you for contacting Thorlabs. There is about a 2mm width layer of exposed ITO coating to apply the wire leads to. Please see the example drawing in the link below, the best way to connect your wire leads is to place them as close to the edge of the substrate as possible to avoid contact with the PI layer. https://www.thorlabs.us/images/TabImages/Liquid_Crystal_Cell_D1-780.gif
Maoqi.Lin  (posted 2019-01-22 14:02:09.307)
Hi, I am very interested in purchasing these liquid crystal cells. Are they reusable? Also, in terms of the liquid crystal controller, since it is a little over budget for me, can I simply use any other AC power suppliers which manages the voltage, current and frequency? Many thanks
nbayconich  (posted 2019-01-24 11:22:03.0)
Thank you for contacting Thorlabs. Theoretically the cell can be re-used, however, it's not easy to remove all the liquid crystal material,and we have no suggested method to remove it, so re-use is not recommended. For third party controllers, we recommend using a controller that can supply an AC current similar to our LCC25 controllers specifications. We suggest you use a square wave form driving signal for stable operation. Output Voltage Adjustment Range: ± 25 VAC (f = 2000 ± 5 Hz) Max Output Current: 15 mA Please note that there should not be any DC offset as this can build up charge and damage the liquid crystal device, as stated in LCC25’s description: “The DC offset compensation automatically zeroes the DC bias across the LC device in order to counteract the buildup of charges, and avoid damage to the LC device.”
381529773  (posted 2018-11-16 21:49:19.003)
Dear thorlabs, I want konw the material of the spacers in the cell,does it a thin film and distributes all over the cell?And if it scatter or absorb light?
nbayconich  (posted 2018-11-20 08:29:01.0)
Thank you for contacting Thorlabs. The spacers we use in our LCC products are little balls blended with specific glue which are on the substrates’ edges, which will not interfere with the cell surface as to cause scattering or absorption within the clear aperture.
zhangyongbin2015  (posted 2018-09-29 11:06:24.943)
Dear, we want to know the maximum permitted thickness of the liquid layer with the preferential orientation if customizing a cell. Can you suggest the maximum thickness of the liquid crystal to me? Thank you very much.
YLohia  (posted 2018-10-22 02:37:51.0)
The largest thickness of LC cell we can offer is 50um. Would you be able to explain what you mean by “ensure the preferential orientation”? Please reach out to us at techsupport.cn@thorlabs.com.
zhangyongbin2015  (posted 2018-09-29 10:48:29.8)
Dear, we want to investigate the nonlinear phenomenon of the nematic liquid crystals. In order to have a macroscopic order, the liquid crystals is needed to be integrated into a cell. We want to know the maximum permitted thickness (important) of the liquid layer? Or if you have any method to achieve a test of a thick liquid sample and ensure the preferential orientation? Thank you.
mariachiara.ubaldi  (posted 2018-05-09 15:23:31.75)
Dear Thorlabs I have three of your cells and would like to use one of them for characterization purposes by splitting the glasses+ITO+polymmide apart. Can you suggest me how to do this? Best regards Maria Chiara Ubaldi
nbayconich  (posted 2018-05-14 08:18:52.0)
Thank you for contacting Thorlabs. The coatings cannot be removed from the finished product but we can possibly provide a customized version without the coating layers you do not require. I will reach out to you directly with more information about our custom capabilities.
mariachiara.ubaldi  (posted 2018-02-09 15:45:19.16)
Dear Thorlabs I have one of your cells filled up with liquid crystal and I have to perform ellipsometric measurements. First of all I'd like to know how glass AR coating is made (layers and thickness) in order to insert it in my model. Besides, have you ever performed full ellipsometric characterization of your cell filled with std liquid crystal? Considering AR and ITO and LC birefringence is a har model to build up. Best regards Maria Chiara
llamb  (posted 2018-04-03 03:56:31.0)
Hello Maria, thank you for contacting Thorlabs. Our AR coating information is proprietary and we do not currently have full-scale testing done on the ellipticity of light through the cells. I will contact you directly to discuss typical cases of ellipticity.
mariachiara.ubaldi  (posted 2017-03-20 14:12:15.863)
Dear sirs I encountered issues in filling the cell with a nematic crystal, with low viscosity. I apply a drop onto the filling port, but the gap never fills for capillarity effects, but seems to stay on the top of the port. I cannot use vacuum chamber. Can you suggest me a solution? Best regards Maria Chiara
tfrisch  (posted 2017-03-30 02:03:24.0)
Hello, thank you for contacting Thorlabs. I will reach out to you directly with my inquiries about your setup and what cell you are using.
souravpatranabish  (posted 2016-09-12 15:34:16.847)
Can you please let me know that how many empty liquid crystal cells you provide in each unit of the product? Also kindly inform whether the cells have planar (homogeneous) alignment. Thank you.
tfrisch  (posted 2016-09-15 01:28:37.0)
Hello, thank you for contacting Thorlabs. The cells do have a planar (homogeneous) alignment. Each unit is once empty cell. I have reached out to you directly if you have further questions.
milankie  (posted 2016-03-17 13:00:41.68)
I am also interested in the damage threshold of the liquid crystals.
besembeson  (posted 2016-03-17 02:35:49.0)
Response from Bweh at Thorlabs USA: I will contact you about your laser characteristics, as we have not established these values yet.
patricio_romero  (posted 2016-02-24 14:08:01.227)
The ITO electrodes have a shape? are they a square/rectangle etched electrode? or is deposited all over the glass surface? Is this glass adequate for Raman measurements? from glass fluorescence point of view? Is it possible to get other electrodes materials like gold? (~10 nm sputtered gold is still viewable-through under POM)
besembeson  (posted 2016-03-08 02:15:26.0)
Response from Bweh at Thorlabs USA: The ITO is deposited all over the glass surface. I will contact you regarding your Raman application and the custom cell.
mccamyjw  (posted 2015-09-23 14:02:29.763)
This is potentially a very interesting experiment for the classroom and my kids. Can you recommend a specific LC material (and perhaps a source)? Or is there a source that sells this as a kit? Finally, is there an easy way to remove the LC after the demo to reuse the unit to try others and/or another class? Thanks very much Jim
besembeson  (posted 2015-10-01 03:09:40.0)
Response from Bweh at Thorlabs USA: We can recommend a liquid crystal named 5CB which has a simple molecule structure and low clearing point. It is commonly used for demonstration and educational purpose. You can check with material vendors like HCCH or Merck regarding acquiring these. Our current device structure makes it impossible to remove LC and re-introduce another. Even if we make a customized cell to do it, it will still be a complicated process to draw the LC out, and the result is difficult to predict.
johnnysheng  (posted 2015-01-30 10:46:18.633)
What is the laser damage threshold at, e.g., 450nm? Is the PI layer inorganic?
jlow  (posted 2015-01-30 04:37:50.0)
Response from Jeremy at Thorlabs: The PI layer is polyimide, which is organic. We do not have a damage threshold specification for this at the moment. I will contact you directly to discuss about this further.

Empty Liquid Crystal Cells

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LCC1310-A Support Documentation
LCC1310-A10 mm x 10 mm Empty Liquid Crystal Cell, 3 µm Gap
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LCC1314-A Support Documentation
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LCC1316-A Support Documentation
LCC1316-A10 mm x 10 mm Empty Liquid Crystal Cell, 6 µm Gap
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LCC1318-A Support Documentation
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LCC1322-A Support Documentation
LCC1322-A10 mm x 10 mm Empty Liquid Crystal Cell, 10 µm Gap
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LCC1324-A Support Documentation
LCC1324-A10 mm x 10 mm Empty Liquid Crystal Cell, 20 µm Gap, No PI Layer
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Liquid Crystal Controller

TC200 Heater Controller GUI
Click to Enlarge

Back Panel of the LCC25 Liquid Crystal Controller

  • Output Voltage Adjustment Range: ± 25 VAC (f = 2000 ± 5 Hz)
  • Max Output Current: 15 mA
  • Output Connector: BNC
  • AC Power Requirements: 85 - 264 VAC, 47 - 63 Hz, 25 VA
  • See the LC Controller Tab Above for More Information

The LCC25 is a liquid crystal controller compatible with all Thorlabs LC Variable Retarders and Polarization Rotators, as well as being is ideal for driving most other nematic liquid crystal devices. Nematic LC retarders must be driven with an AC voltage in order to prevent the separation and build up of charge, which can cause the device to burn out. In addition to the 2000 Hz AC drive voltage, the LCC25 controller automatically zeros the DC bias across the LC device in order to counteract the buildup of charges. The AC output voltage of the LCC25 controller can be adjusted using the front panel controls, an external 0 - 5 VDC TTL input, and via the USB interface. For more information about the LCC25 controller and for a complete list of its specifications, please see the LC Controller tab.

Based on your currency / country selection, your order will ship from Newton, New Jersey  
+1 Qty Docs Part Number - Universal Price Available
LCC25 Support Documentation
LCC25Liquid Crystal Controller, 0-25 VAC, Square Wave, 50% Duty Cycle
$1,405.67
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