Fotoenergetikada nanostrukturali yarimo‘tkazgich materiallar II xalqaro ilmiy anjumani

Fotoenergetikada nanostrukturali yarimo‘tkazgich materiallar

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ТГТУ II-межд конф Хайдаров Элтазаров Эргашев Абдукаримов Курбонов Турсунов Гаибназаров Курбонов Алимова

Fotoenergetikada nanostrukturali yarimo‘tkazgich materiallar

II xalqaro ilmiy anjumani

19-20 noyabr 2021 yil
42
then re-crystallized by heating up to the growth temperature. The subsequent
procedure was the growth of a ZnTe epilayer 1.5

3.2

m thick. The growth rate
was about 0.6

m/h. The growth temperatures were ~350

C for ZnTe and ~300

C
for Cd
x
Zn
1-
x
Te layers. Three types of structures with QWs were grown: (i) the
structure consisted of Cd
0.2
Zn
0.8
Te single well of 5 nm width; (ii) three
Cd
0.3
Zn
0.7
Te QWs of 8 nm, 4 nm and 2 nm widths and (iii) three tunnel-coupled
Cd
0.2
Zn
0.8
Te QWs of 2 nm width. All the structures were sandwiched between cap
ZnTe layer 4 nm thick and buffer ZnTe layer 1.5

m thick. Details of the sample
growth were described previously [2]. Photoluminescence (PL) was excited with
the 488.0 nm and 514.5 nm lines of Ar
+
ion laser or the 632.8 nm line of He

Ne
laser. Luminescence was detected with a photomultiplier tube in the current-flow
regime using a grating spectrometer MDR-23. The ZnTe-based structures were
irradiated with 1.8 MeV-energy electrons or X-ray radiation. The electron
irradiation was performed at a beam current density of 1

A·cm
-2
up to a dose of
4·10
16
cm
-3
(the flux was ~6

10
12
cm
-2
·s
-1
) using an electron accelerator. The X-ray
irradiation was performed by means of an X-ray RAP 150/300 apparatus with tube
voltage
U
= 100 kV (continuous spectrum). The former kind of radiation produced
Frenkel defects and e-h pairs in ZnTe [3], and X-ray radiation produced e-h pairs
only. The effect of electron and X-ray irradiation on the low-temperature
luminescence properties of QWs is shown in Figs.1 and 2. They represent PL
spectra from a sample with three tunnel-coupled QWs of both the same width (
L
Z
=
2 nm) and composition. In the excitonic region of the as-grown sample (Fig.1,
curve 1) the following lines that are typical of ZnTe epilayer are present:
I
2
Ga
+
I
FX
lh
at 2.3736 eV (522.4 nm) - the line of an exciton bound to a neutral donor
(probably Ga [4]) that overlaps with the light-hole component of a free exciton
I
FX
;
I
1

at 2.37 eV (523.2 nm) - an exciton bound to a complex of As atoms [4-5] or to
V
Zn
complex [6];
I
1
C
at 2.3568 eV (526.13 nm) is ascribed to dislocation- related
centers.
At lower energies a sharp peak at 2.3275 eV (532.8 nm) from three Cd
x
Zn
1-
x
Te QWs (
I
QW
) is observed (Fig.2a, curve 1).
As Figs.1 and 2 show, PL intensity after irradiation became somewhat
lower. Concurrently the
I
2
Ga
+
I
FX
lh
band in the excitonic region of a ZnTe layer
divided into two components. This was obviously due to a change in the ratio
between intensities of these components (Fig.1, curve 2).
Spectral positions of bands of free excitons and those bound to point defects
shifted to the high-energy region after both types of irradiation.

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