HAMAMATSU R1527

PHOTOMULTlPLlER TUBES
R1527
R1527P(For Photon Counting)
High Cathode Sensitivity with Low Noise Photocathode
FEATURES
Spectral Response ................................... 185 to 680 nm
Cathode Sensitivity
Luminous ...................................................... 60 A/lm
Radiant at 400nm ............................................ 60 mA/W
Anode Sensitivity (at 1000V)
Luminous ......................................................... 400 A/lm
Radiant at 400nm ..................................... 4.0 105 A/W
Low Dark Current .................................................... 0.1 nA
Low Dark Counts (R1527P) ................................... 10 cps
Hamamatsu R1527 features high cathode sensitivity, high current amplification, and low dark current.
Variant tube (R1527P) specially selected for photon counting
application is also available.
The R1527 is useful for fluorescence, chemiluminescence,
Raman spectroscopy and low light level detection.
Figure 1: Typical Spectral Response
GENERAL
Spectral Response
Wavelength of Maximum Response
Photocathode
MateriaI
Minimum Effective Area
Window Material
Dynode
Secondary Emitting Surface
Structure
Number of Stages
Direct Interelectrode Capacitances
Anode to Last Dynode
Anode to All Other Electrodes
Base
Weight
SuitabIe Socket
SuitabIe Socket Assembly
TPMSB0025EA
Description/Vaiue Unit
185 to 680
nm
400
nm
Low noise bialkali
8 24
mm
UV glass
Low noise bialkali
Circular-cage
9
4
6
11-pin base
JEDEC No. B11-88
pF
pF
45
g
E678–11A (option)
103
PHOTOCATHODE RADIANT SENSITIVITY (mA/W)
QUANTUM EFFICIENCY (%)
Parameter
CATHODE
RADIANT
SENSITIVITY
102
101
QUANTUM
EFFICIENCY
100
10–1
E717–21 (option)
10–2
100
200
300
400
500
600
700
800
WAVELENGTH (nm)
Subject to local technical requirements and regulations, availability of products included in this promotional material may vary. Please consult with our sales office.
lnformation furnished by HAMAMATS U is believed to be reliabIe. However, no responsibility is assumed for possibIe inaccuracies or ommissions. Specifications are
subject to change without notice. No patent right are granted to any of the circuits described herein. © 1994 Hamamatsu Photonics K.K.
PHOTOMULTlPLlER TUBES R1527, R1527P(For Photon Counting)
MAXIMUM RATINGS (Absolute Maximum Values)
Parameter
Value
Unit
Between Anode and Cathode
1250
Vdc
Between Anode and Last Dynode
250
Vdc
0.1
mA
Supply Voltage
Average Anode Current
Ambient Temperature
–80 to +50
CHARACTERISTlCS (at 25
)
Parameter
R1527
for General Purpose
R1527P
for Photon Counting
Min.
Min.
Cathode Sensitivity
Quantum Efficiency at 300nm (Peak)
LuminousB
Radiant at 400nm (Peak)
BlueC
40
Anode Sensitivity
LuminousD
Radiant at 400nm
200
GainE
Typ.
Max.
19
60
60
6.4
200
106
Max.
Unit
19
60
60
6.4
%
A/lm
mA/W
A/lm-b
400
4.0 105
A/lm
A/W
40
400
4.0 105
6.7
Typ.
106
6.7
Current E
Anode Dark
After 30minute Storage in the darkness
Anode Dark CountsF
ENI(Equivalent Noise Input)G
0.1
3.7
0.1
10
2.0
10-17
0.5
50
nA
cps
10-17
3.7
W
ResponseD
Time
Anode Pulse Rise TimeH
Electron Transit TimeJ
Transit Time Spread (TTS)K
2.2
22
1.2
2.2
22
1.2
ns
ns
ns
Anode Current StabilityL
Current Hysteresis
Voltage Hysteresis
0.1
1.0
0.1
1.0
%
%
A: Averaged over any interval of 30 seconds maximum.
B: The light source is a tungsten filament lamp operated at a distribution temperature of 2856K. Supply voltage is 150 volts between the cathode and all
other electrodes connected together as anode.
C: The value is cathode output current when a blue filter(Corning CS-5-58
polished to 1/2 stock thickness) is interposed between the light source and
the tube under the same condition as Note B.
D: Measured with the same light source as Note B and with the anode-tocathode supply voltage and voltage distribution ratio shown in Table 1 below.
E: Measured with the same supply voltage and voltage distribution ratio as
Note D after removal of light.
F: Measured at the voltage producing the gain of 1 106.
G:ENI is an indication of the photon-limited signal-to-noise ratio. It refers to
the amount of light in watts to produce a signal-to-noise ratio of unity in the
output of a photomultiplier tube.
ENI =
where
2q.ldb.G. f
S
q = Electronic charge (1.60 10-19 coulomb).
ldb = Anode dark current(after 30 minute storage) in amperes.
G = Gain.
f = Bandwidth of the system in hertz. 1 hertz is used.
S = Anode radiant sensitivity in amperes per watt at the wavelength of peak response.
H: The rise time is the time for the output pulse to rise from 10% to 90% of the
peak amplitude when the entire photocathode is illuminated by a delta
function light pulse.
J: The electron transit time is the interval between the arrival of delta function
light pulse at the entrance window of the tube and the time when the anode
output reaches the peak amplitube. In measurement, the whole photocathode is illuminated.
K: Also called transit time jitter. This is the fluctuation in electron transit time
between individual pulses in the signal photoelectron mode, and may be
defined as the FWHM of the frequency distribution of electron transit times.
L: Hysteresis is temporary instability in anode current after light and voltage
are applied.
lmax.
Hysteresis =
lmin.
100(%)
li
ANODE
CURRENT
NOTES
l max.
li
l min.
TIME
5
0
6
7 (minutes)
TPMSB0002EA
(1)Current Hysteresis
The tube is operated at 750 volts with an anode current of 1 micro-ampere for
5 minutes. The light is then removed from the tube for a minute. The tube is
then re-illuminated by the previous light level for a minute to measure the
variation.
(2)Voltage Hysteresis
The tube is operated at 300 volts with an anode current of 0.1 micro-ampere
for 5 minutes. The light is then removed from the tube and the supply voltage
is quickly increased to 800 volts. After a minute, the supply voltage is then
reduced to the previous value and the tube is re-illuminated for a minute to
measure the variation.
Table 1:Voltage Distribution Ratio
Electrode
Distribution
Ratio
K
Dy1 Dy2 Dy3 Dy4 Dy5 Dy6 Dy7 Dy8 Dy9
1
1
1
SuppIy Voltage : 1000Vdc
K : Cathode, Dy : Dynode,
1
1
1
P : Anode
1
1
1
P
1
Figure 2: Typical Gain and Anode Dark Current
Figure 3: Typical Time Response
TPMSB0004EB
TPMSB0026EA
108
10–5
100
10–6
107
10–7
106
60
40
TRAN
SIT T
IN
10–9
104
T
EN
TIME (ns)
105
10
8
6
R
10–10
K
AR
E
R
CU
103
4
102
2
101
1500
1
AN
10–12
300
400
500
600
RISE
800
1000
500
300
700
1000
1500
SUPPLY VOLTAGE (V)
SUPPLY VOLTAGE (V)
Figure 4: Typical ENI vs. Wavelength
Figure 5: Typical EADCI (Equivalent Anode Dark Current
Input) vs. Supply Voltage
TPMSB0027EA
10–12
TIME
D
OD
10–11
10–10
TPMSB0028EA
10–13
10–11
10–14
EADCI (lm)
EQUIVALENT NOISE INPUT (W)
IME
20
GA
10–8
GAIN
ANODE DARK CURRENT (A)
80
10–15
10–12
10–13
10–16
10–17
100
200
300
400
500
600
700
10–14
300
800
400
500
WAVELENGTH (nm)
600
800
1000 1200
SUPPLY VOLTAGE (V)
Data shown here, which is given from a relation among supply voltage,
anode sensitivity and dark current, serves as a good reference in order
to determine the most suitable supply voltage or its range.
Figure 6: Typical Single Photon Height Distribution
for R1527P
TPMSB0029EA
104
WAVELENGTH OF INCIDENT LIGHT : 450 (nm)
: 880 (V)
SUPPLY VOLTAGE
: 71 (ch)
LOWER LEVEL DISCRI.
: 5562 (cps)
PHOTON DARK COUNT
: 10 (cps)
DARK COUNT
: 25 (°C)
TEMPERATURE
+
0.8
0.6
0.4
SIGNAL+DARK
TPMSB0030EA
103
DARK COUNT (cps)
1
Figure 7: Typical Temperature Characteristics
of Dark Count for R1527P
102
101
100
0.2
DARK
0
200
400
600
800
1000
10–1
–20
0
+20
TEMPERATURE (°C)
+40
+60
PHOTOMULTlPLlER TUBES R1527, R1527P(For Photon Counting)
Figure 8: Dimensional Outline and Basing Diagram(Unit: mm)
28.5
Figure 10: Socket E678-11A (Optional)
1.5
8MIN.
49
38
PHOTOCATHODE
5
DY6
6
7
DY7
8 DY8
3.5
24MIN.
DY4 4
33
DY5
9 DY9
2
10
29
P
11
K
DY1
4
1
DIRECTION OF LIGHT
18
80MAX.
94MAX.
DY2
49.0
2.5
5
DY3 3
BOTTOM VIEW
(BASING DIAGRAM)
32.2
0.5
TACCA0064EA
11 PIN BASE
JEDEC No. B11-88
TPMSA0001EA
Figure 9: D Type Socket Assembly E717-21 (Optional)
PMT
3.5
33.0 0.3
5
SOCKET
PIN No.
10
P
DY9
38.0 0.3
49.0 0.3
DY8
DY7
R10
C3
R9
C2
R8
C1
SIGNAL GND
SIGNAL OUTPUT RG-174/U
(BLACK)
POWER SUPPLY GND
AWG22 (BLACK)
9
8
7
R7
DY6
6
DY5
5
DY4
4
DY3
3
DY2
2
DY1
K
1
4.8
29
R6 R to R10 : 330k
C1 to C3 : 0.01 F
R5
450 10
41.0 0.5
R4
31.0 0.5
R3
HOUSING
(INSULATOR)
POTTING
COMPOUND
R2
R1
11
–HV
AWG22 (VIOLET)
R1 to R10 : 330k
C1 to C3 : 0.01 F
TACCA0002ED
Hamamatsu also provides C4900 series compact high voltage power supplies and C6270 series DP type socket assemblies which incorporate a
DC to DC converter type high voltage power supply.
Warning–Personal Safety Hazards
Electrical Shock–Operating voltages applied to this
device present a shock hazard.
HAMAMATSU PHOTONICS K.K., Electoron Tube Center
314-5, Shimokanzo, Toyooka-village, Iwata-gun, Shizuoka-ken, 438-0193, Japan, Telephone: (81)539/62-5248, Fax: (81)539/62-2205
U.S.A.: Hamamatsu Corporation: 360 Foothill Road, Bridgewater. N.J. 08807-0910, U.S.A., Telephone: (1)908-231-0960, Fax: (1)908-231-1218
Germany: Hamamatsu Photonics Deutschland GmbH: Arzbergerstr. 10, D-82211 Herrsching am Ammersee, Germany, Telephone: (49)8152-375-0, Fax: (49)8152-2658
France: Hamamatsu Photonics France S.A.R.L.: 8, Rue du Saule Trapu, Parc du Moulin de Massy, 91882 Massy Cedex, France, Telephone: (33)1 69 53 71 00, Fax: (33)1 69 53 71 10
United Kingdom: Hamamatsu Photonics UK Limted: Lough Point, 2 Gladbeck Way, Windmill Hill, Enfield, Middlesex EN2 7JA, United Kingdom, Telephone: (44)181-367-3560, Fax: (44)181-367-6384
North Europe: Hamamatsu Photonics Norden AB: Färögatan 7, S-164-40 Kista Sweden, Telephone: (46)8-703-29-50, Fax: (46)8-750-58-95
Italy: Hamamatsu Photonics Italia: S.R.L.: Via Della Moia, 1/E, 20020 Arese, (Milano), Italy, Telephone: (39)2-935 81 733, Fax: (39)2-935 81 741
TPMS1007E02
OCT. 1994