Handbook of Photovoltaic Science and Engineering

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Photovoltaic science and engineering (1)

Figure 8.1
Maximum achievable current density (MACD) from a planar, AR-coated Si solar cell
as a function of cell thickness. These calculations assume an optimized AR coating and AM1.5
incident spectrum. These results are obtained with
PV Optics
performed using
photovoltaic
(
PV
)
Optics
software, which assumes the generation of one
electron-hole pair per photon and a collection efficiency of unity. These assumptions are
tantamount to a zero surface-recombination velocity and absence of other electronic loss
mechanisms. Thus, the photocurrent in Figure 8.1 corresponds to a maximum achievable
current density for the AM1.5 solar spectrum. Figure 8.1 shows that the photocurrent
increases with an increase in thickness and saturates at a thickness of about 700
µ
m.
At a thickness of
∼
300
µ
m, the current density is within 5% of the saturation value,
which implies that a thickness of 300
µ
m is suitable for fabricating high-efficiency solar
cells on planar substrates. This is fortunate because a similar demand on wafer thickness
comes from requirements for maintaining a high yield in handling and processing other
semiconductor devices.
The PV industry has traditionally borrowed technological know-how of device
handling and processing from the semiconductor industry, which traditionally uses thick
wafers to prevent breakage through mechanical handling or generation of thermal stresses
by high-temperature processing. Concomitantly, the PV community found it compelling
to use wafers of similar thickness for Si solar cells. The choice of thick wafers permitted
the PV community to focus on the material and device-processing issues, which helped
develop the science and technology of Si solar cells to the current level.
Recently, however, there have been many advances in wafer handling and in
the development of gentler processing methods to accommodate high throughput. These
advances have sparked interest in using thinner substrates for two reasons: (1) To reduce
the amount of Si for each watt of PV energy generation. Because the PV industry has
gone through periods of Si shortage, an efficient use of Si can minimize such hardships;
and (2) To improve the efficiency of solar cells fabricated on low-cost substrates using
improved cell designs.

INTRODUCTION
309
640
635
630
625
620
615
610
605
600
0
50
100
150
200
Thickness
[
µ
m]
250
300
350
100 cm/s
1000 cm/s
Open circuit v
oltage
[mV]

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