Apparatus for detecting a photon pulse

Streak camera whereof the pulse converter for converting a photon pulse for detecting into an electron stream comprises a gaseous medium. A streak camera for a photon pulse in the far-infrared region is provided with a laser source to bring particles in the medium into a Rydberg state, in a streak camera for an X-ray pulse the medium contains particles for bringing into an Auger state, and additional deflection plates are provided for separating a primary electron stream from a secondary electron stream.

The invention relates to an apparatus for detecting a photon pulse as a 
function of time, for instance a streak camera, comprising a pulse 
converter for converting a photon pulse for detecting into an electron 
stream, first deflection means for deflecting the electron stream as a 
function of time and a position-sensitive detector for determining the 
deflection of the electron stream. 
Such an invention is known from a publication by R. Yen, P. M. Downey, C. 
V. Shank and D. H. Auston in "Appl. Phys. Lett.", Vol. 44, No. 8, (1984), 
pp. 718-720. In this publication a streak camera is described, the streak 
tube (image-converter tube) of which contains a photocathode, a collimator 
plate provided with micro-channels, deflection plates and a phosphor 
screen. The output image of this streak tube is coupled via a reducing 
bundle of optical fibres to an image amplifier, the output of which is 
coupled using a fibre optic to a silicon image amplifier, the output 
signal of which is displayed on the screen of an optical multi-channel 
analyzer (OMA). 
A photon pulse incident on the photocathode generates an electron beam 
which is deflected by the deflection plates, to which is applied a voltage 
which rapidly increases synchronously with the incidence of the photon 
pulse. The deflected electron beam strikes the phosphor screen, on which 
is displayed a line segment progressing in time, the intensity of which 
corresponds to the intensity of the incident photon pulse. This image is 
further processed by the relevant fibre optics, image amplifiers and OMA, 
whereafter an image of the intensity of the incident photon pulse as a 
function of time is finally obtained. 
The known streak camera has the drawback that the wavelength range of 
photons of which the pulse intensity can be displayed is bounded on the 
long-wave side of the spectrum at a wavelength of approximately 1.5 .mu.m 
(infrared), while on the other side photons from the X-ray region (i.e. 
the part of the spectrum having very short wavelengths) occur in many 
practical applications in non-monochromatic pulses, of which no sharp 
image can be made using an apparatus of the above described type. 
The object of the invention is to provide an apparatus for detecting as a 
function of time a photon pulse which has a wavelength shorter than that 
of visible light or longer than that of infrared light and for making a 
sharp image of such a pulse. 
This object is achieved with an apparatus of the type stated in the 
preamble, wherein according to the invention the pulse converter comprises 
a gaseous medium for absorbing the photon pulse to be detected and for 
emitting the electron stream. 
In an apparatus wherein according to the invention the pulse converter 
comprises a gaseous medium the spectral range of a photon pulse for 
detecting is not limited to the visible light and the infrared region, but 
the spectral range can be extended as required to the wavelength region of 
far-infrared light or the wavelength region of X radiation. 
In an embodiment of an apparatus according to the invention for detecting a 
photon pulse in the far- infrared region the apparatus is provided with 
excitation means for bringing particles into an excited electron state and 
the gaseous medium contains particles for bringing into this excited 
electron state in order in this state to absorb the photon pulse and to 
emit the electron stream. 
The excited electron state is for instance a Rydberg state. 
By bringing particles, for instance atoms, into an excited electron state, 
for instance a Rydberg state, a pulse converter is obtained for converting 
a (far) infrared and therefore low-energy photon pulse into an electron 
stream. An atom in a Rydberg state, referred hereinafter to as Rydberg 
atom, has a high value of the main quantum number n, and therefore a 
relatively low binding energy E (E=-13.6/n.sup.2 eV). As a consequence the 
relatively low energy of a far-infrared photon is sufficiently high to 
cause photo-ionization of an atom in a Rydberg state and to liberate a 
weakly bonded electron from that atom. Moreover, the active cross-section 
for photo-ionization is high for a gas with Rydberg atoms, so that 
relatively few photons are required for this process. 
A gaseous medium comprising particles for bringing into an excited state is 
for instance admitted into the apparatus via a gas supply line. 
In one embodiment the apparatus according to the invention comprises an 
evaporation oven for bringing into a gaseous state the particles for 
bringing into an excited electron state. 
Atoms for bringing into an excited electron state which are suitable for 
use in an apparatus according to the invention are for instance alkali 
atoms, in particular the elements Rb (rubidium) or Cs (caesium). 
The atoms are brought into an excited electron state for instance by 
excitation using a laser light source. 
A laser light source for use in an apparatus according to the invention is 
for instance a dye laser pumped with an Nd:YAG(neodymium:yttrium-aluminium 
garnet) laser. The second harmonic of the light of an Nd:YAG laser is 
particularly suitable for pumping the dye laser in such an apparatus. 
In another embodiment the apparatus comprises a diode laser. 
The invention further provides an apparatus for detecting a photon pulse in 
the infrared region as a function of time, comprising a pulse converter 
for converting a photon pulse for detecting into an electron stream and a 
detector for this electron stream, which apparatus is provided with 
excitation means for bringing particles into an excited electron state, 
wherein the pulse converter comprises a gaseous medium having particles 
for bringing into this excited electron state in order to absorb the 
photon pulse and to emit the electron stream. 
Such an apparatus is particularly suitable for measuring, with a time 
resolution of for instance 1 ns (1 GHz), the time profile, in particular 
the duration of a pulse (expressed in FWHM--full width at values equal to 
half the maximum value), in the infrared region (for which the wavelength 
.lambda. is greater than approximately 1.1 .mu.m). 
In yet another embodiment of an apparatus according to the invention for 
detecting a photon pulse in the X-ray region the gaseous medium contains 
particles for bringing into an Auger state in order to absorb the photon 
pulse and to emit a primary electron stream with a determined primary 
electron energy and to emit, in an Auger state, a secondary electron 
stream with a determined secondary electron energy which differs from the 
primary electron energy, and second deflection means are provided for 
deflecting the primary and secondary electron stream in a direction 
differing from that of the deflection by the first deflection means, in a 
manner such that the primary electron stream is separated from the 
secondary electron stream and substantially only the deflection of the 
second electron stream is determined with the position-sensitive detector. 
During incidence of an X-ray pulse for detecting into such an apparatus, an 
inner shell electron is liberated from the particles, in particular atoms, 
which on the one hand results in a primary stream of electrons with a 
determined primary energy and on the other causes a hole in the relevant 
inner shell of the atoms which are now in an Auger state, which hole is 
filled by a radiation-free transition of an electron from the outer shell. 
The energy released in this latter transition is absorbed by a second 
electron from the outer shell, which electron is liberated and results in 
a secondary stream of electrons with a determined secondary energy which 
in principle differs from the above mentioned primary energy. Because the 
energy of the primary electrons differs in principle from that of the 
secondary electrons, the time during which the primary and secondary 
electrons are subject to the action of the second deflection means also 
differs, whereby it is possible to deflect the primary electrons such that 
they do not reach the position-sensitive detector and to deflect the 
secondary electrons such that they do reach the position-sensitive 
detector. Only in the chance situation where the energy of the primary 
electrons is the same as that of the secondary electrons would primary and 
secondary electrons be deflected to the same degree. However, using 
knowledge of the wavelength(s) of the X-ray pulse for detecting and the 
spectrum of the Auger atom, such a situation can be prevented in practical 
situations in simple manner by choosing a different, suitable Auger atom. 
In an apparatus according to the invention for detecting an X-ray pulse the 
second deflection means are preferably provided to deflect the primary and 
secondary electron stream in a direction substantially perpendicular to 
the direction of the deflection by the first deflection means. In such an 
apparatus the secondary electron stream, which corresponds with the 
intensity of the incident X-ray pulse, is displayed on the 
position-sensitive detector as a function of time in a determined 
direction as a line segment, the intensity of which is a measure for the 
intensity of the X-ray pulse, while the primary electron stream is 
deflected in a direction perpendicular to that of this line segment and 
outside the sensitivity range of the position-sensitive detector. For 
instance a slit in the path of the primary electrons brings about blocking 
of these electrons, i.e. the primary electrons are prevented from reaching 
the position-sensitive detector. When the incident X-ray pulse is not 
monochromatic but comprises a number of wavelengths (for X-rays usually 
designated with the corresponding energies), the primary electrons emitted 
by the atoms have as many different energies as the number of wavelengths 
present in the X-ray pulse, while the secondary electrons are 
mono-energetic. The non-mono-energetic primary electron stream is 
deflected to a location outside the position-sensitive detector, while the 
mono-energetic secondary electron stream produces on the 
position-sensitive detector a sharp image of the intensity of the incident 
X-ray pulse as a function of time, which image is neither widened nor 
otherwise reduced in quality as a result of the distribution in energy of 
the incident X-ray pulse. 
The gaseous medium can in principle contain any atom which can be brought 
into an Auger state by the relevant photon pulse, for instance Ne (neon). 
With a streak camera for the far-infrared region according to the invention 
photon pulses with a wavelength .lambda. up to for instance about 
.lambda.=100 .mu.m can be detected as a function of time with a very high 
resolution (approximately 10.sup.-12 s.). This makes such a streak camera 
particularly suitable for for instance measurements of pulse form and 
pulse duration of ultra-fast lasers, the light emission profile of 
laser-heated plasmas and nuclear fusion fuel tablets as a function of 
time, absorption phenomena in solvents, picosecond fluorescence decay in 
biological preparations, time-dependent medical image signals and 
dispersion of optical pulses in telecommunication fibres. 
A streak camera according to the invention for detecting incident photon 
pulses offers particular advantages when these pulses are not 
monochromatic.

FIG. 1 shows a streak camera 1 for detecting photon pulses in the 
far-infrared region, with streak tube 2, which comprises cathode plate 3 
(connection and supply of which are not shown), collimator plate 4, 
collimator slit 5, deflection plates 6 with terminals 7, channel plates 8, 
phosphor screen 9, oven 10 and windows 11,12. The streak camera 1 further 
comprises a CCD camera 14 coupled to a computer 13 and a diode laser 15. 
The deflection plates 6 are connected in parallel to a capacitor 16 which 
can be charged via a GaAs photo switch 17 by a high-voltage supply 18. 
When the streak camera 1 is in operation a photon pulse 20 (a far-infrared 
pulse) incident via a window 12 in the direction of arrow 19 is absorbed 
by a gas 21, which is excited by laser light (represented by arrow 22) 
from diode laser 15 via window 11 and is in a Rydberg state. The Rydberg 
gas 21 emits photo-electrons which are accelerated in the z-direction of 
the shown coordinate system 23 by the cathode plate 3 with a voltage of -5 
kV relative to the voltage of collimator plate 4. Via the collimator slit 
5 the accelerated photo-electrons move between the deflection plates 6 to 
which a rapidly increasing voltage is applied via terminals 7 using the 
high voltage supply 18 and capacitor 16. The deflection voltage on 
deflection plates 6 is switched using a GaAs photo switch which is 
activated (indicated by arrow 24) by a light pulse 25 derived from the 
photon pulse 20 and running synchronously therewith. The electron stream 
(represented by dashed line 26) is thus deflected in the direction of 
arrow 27 as a function of time, is amplified with a factor 10.sup.7 by the 
channel plates 8 and strikes the phosphor screen 9, where the electrons 
are converted into photons at an amplification factor of 10. It is also 
noted that the rise time of the voltage on deflection plates 6 amounts 
typically to approximately 5 V/ps, in order to ensure a large displacement 
per time unit (typically 0.2 mm/ps) on phosphor screen 9. Thus displayed 
on phosphor screen 9 is a line segment of which the intensity 
(schematically represented by curve 28) corresponds with that of the 
incident photon pulse 20. This image is read using CCD camera 14 and 
processed using computer 13. The sensitivity of the CCD camera is 
sufficiently high to generate a signal in response to a single incident 
photo-electron. It will be apparent from FIG. 1 that photo-electrons 
emitted by Rydberg atoms 21 situated close to the cathode 3 have to cover 
a longer path to deflection plates 6 than photo-electrons which are 
emitted by Rydberg atoms 21 which are further removed from cathode 3. 
However, since the electrons which have to cover a longer path as a 
consequence of the shorter distance to cathode 3 have a higher energy than 
the electrons which have to cover a shorter path, the latter electrons are 
overtaken by the former: there is therefore a point along the path which 
is covered, the so-called time focus, which is precisely determined, where 
all photo-electrons emitted at the same point in time by the Rydberg gas 
arrive simultaneously. In order to obtain a good sharpness of the image on 
phosphor screen 9 the deflection plates 6 are for instance placed at the 
location of this time focus. 
The deflection plates 6 are preferably placed just in front of this time 
focus. Such a placing of deflection plates 6 achieves that the electrons 
with a higher energy arrive between deflection plates 6 slightly later 
than the electrons with a lower energy. At this later time of arrival the 
voltage on deflection plates 6 is higher than at the time of arrival of 
the electrons with lower energy, so that the electrons with higher energy, 
which remain between deflection plates 6 for a short time than the 
electrons with lower energy, undergo a higher deflection voltage than the 
electrons with lower energy. With a suitably chosen combination of 
duration of stay of the electrons between the deflection plates and height 
of the deflection voltage on the plates 6 is achieved that all electrons 
which are generated in the pulse converter at the same time by the 
incident photon pulse 20 are deflected at the same angle by deflection 
plates 6, as a result of which the sharpness of the image on phosphor 
screen 9 is optimized. 
FIG. 2 shows a streak camera 31 for detecting photon pulses in the X-ray 
region. Parts corresponding with the streak camera 1 shown in FIG. 1 are 
designated with the same reference numerals and will not be discussed 
again here. The present streak camera 31 differs from the streak camera 1 
of FIG. 1 in the presence of deflection plates 32 for deflecting in the 
x-direction the primary and secondary electron stream emitted by Auger 
atoms 35. Deflection plates 32 are connected via terminals (not shown) to 
a direct voltage source (not shown). Because the energy of primary and 
secondary electrons differs, the duration of stay of the primary and 
secondary electrons between deflection plates 32 also differs. The 
deflection voltages and positioning and dimensioning of the parts of the 
different components of streak camera 31 are chosen such that, after 
deflection in y-direction (arrow 27) as a function of time, the secondary 
electron stream (represented by dashed line 26) is amplified by the 
channel plates 8 by a factor 10.sup.7 and strikes phosphor screen 9, while 
the primary electron stream (represented by dashed line 33) is deflected 
in x-direction (arrow 34) such that it does not strike phosphor screen 9. 
A line segment is thus displayed in y-direction on phosphor screen 9, 
which line segment is slightly widened in x-direction as a consequence of 
the deflection of the electrons by deflection plates 32, but the intensity 
of which (represented schematically by curve 28) corresponds with the 
incident photon (in this case X-ray) pulse 20. 
FIG. 3 shows a photon detector 51 for detecting photon pulses in the 
wavelength range with a wavelength .lambda. greater than about 1.1 .mu.m. 
Parts corresponding with the streak camera 1 shown in FIG. 1 are 
designated with the same reference numerals and will not be discussed 
again here. The present photon detector 51 differs from streak camera 1 of 
FIG. 1 by the absence of deflection plates and a phosphor screen. In the 
detector 51 electrons (represented by dashed line 36) created by 
photo-ionization of the Rydberg atoms 21 excited by using a laser 15, pass 
directly via collimator slit 5 to an electron detector, which in this 
example comprises a pair of micro-channel plates 8 but which may also 
comprise a so-called channeltron or other suitable electron detector. The 
electron detector 8 generates an electric current 37 which is proportional 
to the number of incoming electrons, which current 37 can also be measured 
as a function of time, for instance using an oscilloscope. To prevent the 
condensation of gas on micro-channel plates 8 these plates are preferably 
heated during use. In addition or by way of alternative the collimator 
slit 5 can be covered with a thin foil, for instance Al foil with a 
thickness of 2 nm, which on the one hand prevents passage of gas particles 
21 through the slit 5 but on the other hand allows through electrons or 
generates secondary electrons which in turn reach the electron detector 8. 
The arrival time of the electrons 36 at the channel plates 8 is determined 
in first order approximation by the shape of the time-dependence of the 
photon pulse 20. This arrival time is focused particularly sharply in time 
when the position of channel plates 8 is chosen such that the distance 
from channel plates 8 to collimator slit 5 is just twice the distance from 
collimator slit 5 to the interaction centre of the Rydberg gas 21. The 
choice of the laser 15 and the Rydberg gas 21 is determined by the 
wavelength of the photon pulse 20 for measuring. A photon pulse 20 with a 
wavelength .lambda.&lt;1635 nm for instance ionizes an Na gas in the Rydberg 
state 5p. The Na gas can be brought into this Rydberg state by excitation 
with a laser having a wavelength of 285 nm. A photon pulse 20 with a 
wavelength .lambda.&lt;35 .mu.m ionizes for instance an Rb gas in the Rydberg 
state 20f. The Rb gas can be brought into the respective Rydberg states 
5p, 5d and 20f by successive excitations with diode lasers at wavelengths 
of respectively 780 nm, 776 nm and 1299 nm. 
FIG. 4 shows an alternative embodiment 71 of the photon detector of FIG. 3, 
in which detection of photo-electrons 36 takes place using a phosphor 
screen 9 which converts the electron stream 36 into a photon stream 38, 
which is measured again outside tube 2 using a photo detector 39 for the 
visible range, for instance a photo-multiplier tube or an image 
intensifier, which again produces a signal 37 representative of the 
incident photon pulse 20.