QS9-IL

P/N 201688

Hybrid pyroelectric sensor with metallic coating. Low noise level.

    • 5 mm Ø
    • 9 mm Ø
    • Low noise
    • Fast response
    • Discrete
    • Hybrid
QS9-IL

Traceable calibration:

Logo nist

Product family key features

Broad Spectral Response

From 0.1 to 1000 µm

3 families of products to choose from:

  • QS-L: discrete pyro detectors, low noise level
  • QS-H: discrete pyro detectors, high average power
  • QS-IL: hybrid pyro detectors, current mode, low noise level

Easy to Integrate Format

TO5 and TO8 packages make the QS-H detectors small and easy to integrate in an existing system.

Large Area Sensors

5 mm and 9 mm diameter pyroelectric sensors make optical alignment easier.

Several IR Windows in Option

  • Quartz: 0.2 – 3.5 µm
  • Barium fluoride: 0.2 – 17.5 µm
  • Sapphire: 0.1 – 7.0 µm
  • Silicon: 1.2 – 9.0 µm and 22 – 100 µm
  • AR germanium: 1.8 – 23 µm (10.6 µm peak)

Measurement capabilities

  • Maximum average power

    50 mW
  • Noise equivalent power1

    6 nW
  • Spectral range

    0.1 - 1000 μm
  • Current responsivity

    0.25 μA/W
  • Thermal frequency

    0.25 Hz
  • Voltage responsivity2

    13 kV/W
  • Feedback resistor

    100 GΩ
  • Supply voltage

    ±5 V
    • 1. 630 nm, 5 Hz, 1 Hz bandwidth
    • 2. 630 nm, 15 Hz

Physical characteristics

  • Aperture diameter

    9 mm
  • Absorber

    MT
  • Dimensions

    15.2Ø x 6.4D mm
  • Weight

    0.0015 kg
  • Package

    TO8

PYROELECTRIC THERMAL DETECTORS

Our pyroelectric detectors are a class of room temperature thermal detectors that produce a current output that is directly proportional to the rate of change of temperature when exposed to a source of radiation. They are best described by an AC current source, capacitor and resistor. Their current output is governed by the equation I = p(T)·A·dT/dt, where I is current, p(T) is the pyro coefficient, A is the area as defined by the front electrode, and dT/dt is the rate of temperature change of the pyro crystal. The advantages of a pyroelectric detector over other IR detectors are: room temperature operation, broad spectral response, high sensitivity (D*) and fast response (sub-nsec into 50 Ω).

QS-L AND QS-H DISCRETE PYROS

Our passive discrete pyroelectric detectors range from 1 to 9 mm in diameter and are provided in two configurations: high sensitivity or high average power. They present a pyroelectric detector element covered with our metallic coating (MT) and are packaged in a miniature TO-5 or TO-8 can. The diagram shown left identifies the pin-out for both types of detectors. Our organic black coating (BL), increases the optical absorption and helps flatten the spectral response. We also offer a number of permanent IR Windows that can be added to the TO can. These discrete pyro detectors are ideal for pulsed laser applications.

 

QS-IF AND QS-IL CURRENT MODE HYBRID PYROS

These detectors offer high gain (>105 V/W) and/or high bandwidth (>10 MHz). In this configuration, the pyroelectric detector element is combined to a low noise operational amplifier. The QS-IL models are designed for high performance at low to medium frequencies, while the QS-IF models offer good performance at medium to high frequencies. These detectors are very easy to use. Simply supply the +/- 10 to 15 V to power the operational amplifier and add an external resistor, if required, to adjust the bandwidth and you are ready to measure pulsed, modulated or chopped sources, from nJ to m J and nW to W. These detectors also make great candidates for any variety of broadband analytical instruments or laser measurement products.

VOLTAGE OUTPUT VS. FREQUENCY

Our QS-VL and QS-IL hybrid detectors are designed to maximize voltage output at low frequencies and therefore include load and feedback resistors in the 100 GΩ to 300 GΩ range. They are also designed into 8-pin TO packages that allow the addition of an “external resistor” to lower the output and increase the bandwidth. The circuit diagram at the left shows a typical hook up for our QS5-IL detector (with our MT coating), using external resistors and capacitors. Our QS-IF series, on the other hand, are designed for high bandwidth applications and therefore include a smaller feedback resistor of 100 MΩ. For expert help on designing a detector circuit please contact us.

OPERATION IN POWER MEASUREMENT MODE

When using our QS-IL hybrid detector to measure the power (in watts) of your CW or high rep rate source (quasi-CW), you will need to employ an optical chopper. The diagram at the left shows the typical voltage output of a QS5-IL when used with our QS-I-TEST evaluation test box. Note that the voltage output is an approximate “square wave” whose rise and fall times are governed by the RC time constant of the circuit. The optical power is directly proportional to the peak voltage minus the baseline voltage. We calibrate these devices when operating in this mode.

OPERATION IN ENERGY MEASUREMENT MODE

Our pyroelectric detectors are an ideal choice when measuring the performance of your pulsed laser in the range of nJ to mJ, across the full spectrum! The scope trace at the left represents the typical output from a QS9-IL, when used with our QS-I-TEST set up as an integrating joulemeter. Note the fast rise to a peak and then slower decay governed by the RC time constant selected for the integrating circuit. In this configuration you can measure absolute pulse energy, rep rate, and pulse-to-pulse stability. The maximum pulse width of your source is determined by the RC time constant you select and there is no limit as to how short the pulse can be!

BROAD SPECTRAL RESPONSE

Unlike photoconductive and photovoltaic detectors, our pyroelectric thermal detectors are not limited to a small part of the electromagnetic spectrum. They are truly broad spectrum detectors, sensitive from 0.1 μm to 3000 μm (EUV, FAR IR, and THz). Any and all radiation absorbed by our coatings or pyro crystal will result in a measurable signal. The two plots at the left show the relative spectral response of detectors with MT and BL coatings. Note that the well documented, NIST traceable calibrated portion of these curves runs from 0.25 μm to 15 μm. There are currently no traceable optical standards for measurements > 15 μm.

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