While space-charge-limited current measurements are often used to characterize charge-transport in relatively intrinsic, low-mobility semiconductors, it is currently difficult to characterize lightly or heavily doped semiconductors with this method. By combining the theories describing ohmic and space-charge-limited conduction, we derive a general analytical approach to extract the charge-carrier density, the conduction-band edge, and the drift components of the current density–voltage curves of a single-carrier device when the semiconductor is undoped, lightly doped, or heavily doped. The presented model covers the entire voltage range, i.e., both the low-voltage regime and the Mott–Gurney regime. We demonstrate that there is an upper limit to how doped a device must be before the current density–voltage curves are significantly affected, and we show that the background charge-carrier density must be considered to accurately model the drift component in the low-voltage regime, regardless of whether the device is doped or not. We expect that the final analytical expressions presented herein to be directly useful to experimentalists studying charge-transport in novel materials and devices.

1.
N. F.
Mott
and
R. W.
Gurney
,
Electronic Processes in Ionic Crystals
(
Oxford University Press
,
1940
).
3.
M. A.
Lampert
,
Phys. Rev.
103
,
1648
(
1956
).
4.
M.
Lampert
and
P.
Mark
,
Current Injections in Solids
(
Academic Press
,
1970
).
5.
J. C.
Blakesley
,
F. A.
Castro
,
W.
Kylberg
,
G. F. A.
Dibb
,
C.
Arantes
,
R.
Valaski
,
M.
Cremona
,
J. S.
Kim
, and
J. S.
Kim
,
Org. Electron.
15
,
1263
(
2014
).
6.
S.
Holliday
,
R. S.
Ashraf
,
C. B.
Nielsen
,
M.
Kirkus
,
J. A.
Röhr
,
C. H.
Tan
,
E.
Collado-Fregoso
,
A. C.
Knall
,
J. R.
Durrant
,
J.
Nelson
, and
I.
McCulloch
,
J. Am. Chem. Soc.
137
,
898
(
2015
).
7.
S.
Dahlström
,
C.
Ahläng
,
K.
Björkström
,
S.
Forsblom
,
B.
Granroth
,
K.
Jansson
,
A.
Luukkonen
,
M. T.
Masood
,
J.
Poulizac
,
S.
Qudsia
, and
M.
Nyman
,
AIP Adv.
10
,
065203
(
2020
).
8.
J.
Kwan Kim
,
J.
Hoon Song
,
H.
Choi
,
S.
Jae Baik
,
S.
Jeong
,
J. H.
Song
,
H.
Choi
,
S.
Jae Baik
, and
S.
Jeong
,
J. Appl. Phys.
115
,
054302
(
2014
).
9.
K. D.
Mackenzie
,
P. G.
Le Comber
, and
W. E.
Spear
,
Philos. Mag. B
46
,
377
(
1982
).
10.
M.-H.
Chen
,
J.
Hou
,
Z.
Hong
,
G.
Yang
,
S.
Sista
,
L.-M.
Chen
, and
Y.
Yang
,
Adv. Mater.
21
,
4238
(
2009
).
11.
R.
Steyrleuthner
,
M.
Schubert
,
F.
Jaiser
,
J. C.
Blakesley
,
Z.
Chen
,
A.
Facchetti
, and
D.
Neher
,
Adv. Mater.
22
,
2799
(
2010
).
12.
Z.
He
,
C.
Zhong
,
X.
Huang
,
W.-Y.
Wong
,
H.
Wu
,
L.
Chen
,
S.
Su
, and
Y.
Cao
,
Adv. Mater.
23
,
4636
(
2011
).
13.
V. D.
Mihailetchi
,
J. K. J.
van Durent
,
P. W. M.
Blom
,
J. C.
Hummelen
,
R. A. J.
Janssen
,
J. M.
Kroon
,
M. T.
Rispens
,
W. J. H.
Verhees
, and
M. M.
Wienk
,
Adv. Funct. Mater.
13
,
43
(
2003
).
14.
N. B.
Kotadiya
,
P. W. M.
Blom
, and
G. A. H.
Wetzelaer
,
Phys. Rev. Appl.
11
,
024069
(
2019
).
15.
D.
Shi
,
V.
Adinolfi
,
R.
Comin
,
M.
Yuan
,
E.
Alarousu
,
A.
Buin
,
Y.
Chen
,
S.
Hoogland
,
A.
Rothenberger
,
K.
Katsiev
,
Y.
Losovyj
,
X.
Zhang
,
P.
a Dowben
,
O. F.
Mohammed
,
E. H.
Sargent
, and
O. M.
Bakr
,
Science
347
,
519
(
2015
).
16.
C. H.
Chiang
and
C. G.
Wu
,
Nat. Photonics
10
,
196
(
2016
).
17.
R.
de Levie
,
N. G.
Seidah
, and
H.
Moreia
,
J. Membr. Biol.
10
,
171
(
1972
).
18.
A. A.
Grinberg
and
S.
Luryi
,
J. Appl. Phys.
61
,
1181
(
1987
).
19.
G. A. H.
Wetzelaer
, and
P. W. M.
Blom
,
Phys. Rev. B
89
,
241201
(
2014
).
20.
P.
Mark
and
W.
Helfrich
,
J. Appl. Phys.
33
,
205
(
1962
).
21.
P. N.
Murgatroyd
,
J. Phys. D Appl. Phys.
3
,
151
(
1970
).
22.
J.
Dacuña
and
A.
Salleo
,
Phys. Rev. B
84
,
195209
(
2011
).
23.
J.
Dacuña
,
W.
Xie
, and
A.
Salleo
,
Phys. Rev. B
86
,
115202
(
2012
).
24.
J. A.
Röhr
,
X.
Shi
,
S. A.
Haque
,
T.
Kirchartz
, and
J.
Nelson
,
Phys. Rev. Appl.
9
,
044017
(
2018
).
25.
G. A. H.
Wetzelaer
,
AIP Adv.
8
,
035320
(
2018
).
26.
R. C. I.
MacKenzie
,
T.
Kirchartz
,
G. F. A.
Dibb
, and
J.
Nelson
,
J. Phys. Chem. C
115
,
9806
(
2011
).
27.
M.
Zeman
and
J.
Krc
,
J. Mater. Res.
23
,
889
(
2008
).
28.
D.
Bartesaghi
,
I. D. C.
Pérez
,
J.
Kniepert
,
S.
Roland
,
M.
Turbiez
,
D.
Neher
, and
L. J. A.
Koster
,
Nat. Commun.
6
,
2
(
2015
).
29.
V. S.
Pereira
and
S.
Blawid
,
J. Comput. Electron.
18
,
120
(
2019
).
30.
G.
Bhattarai
,
A. N.
Caruso
, and
M. M.
Paquette
,
J. Appl. Phys.
124
,
045701
(
2018
).
31.
W. F.
Pasveer
,
J.
Cottaar
,
C.
Tanase
,
R.
Coehoorn
,
P. A.
Bobbert
,
P. W. M.
Blom
,
M.
De Leeuw
, and
M. A. J.
Michels
,
Phys. Rev. Lett.
94
(
4
),
206601
(
2005
).
32.
J. A.
Röhr
,
T.
Kirchartz
, and
J.
Nelson
,
J. Phys. Condens. Matter
29
,
205901
(
2017
).
33.
J. A.
Röhr
,
D.
Moia
,
S. A.
Haque
,
T.
Kirchartz
, and
J.
Nelson
,
J. Phys. Condens. Matter
30
,
105901
(
2018
).
34.
P. E.
Schmidt
and
H. E.
Henisch
,
Solid State Electron.
25
,
1129
(
1982
).
35.
H. J.
Snaith
and
M.
Grätzel
,
Appl. Phys. Lett.
89
(
3
),
262114
(
2006
).
36.
W.
Chandra
,
L. K.
Ang
,
K. L.
Pey
, and
C. M.
Ng
,
Appl. Phys. Lett.
90
,
153505
(
2007
).
37.
J. A.
Röhr
,
Phys. Rev. Appl.
11
,
054079
(
2019
).
38.
G. A. H.
Wetzelaer
,
Phys. Rev. Appl.
13
,
034069
(
2020
).
39.
T.
Kirchartz
,
B. E.
Pieters
,
J.
Kirkpatrick
,
U.
Rau
, and
J.
Nelson
,
Phys. Rev. B
83
,
115209
(
2011
).
40.
X.
Shi
,
V.
Nádaždy
,
A.
Perevedentsev
,
J. M.
Frost
,
X.
Wang
,
E.
von Hauff
,
R. C. I.
MacKenzie
, and
J.
Nelson
,
Phys. Rev.
9
,
021038
(
2019
).
41.
N.
Majeed
,
M.
Saladina
,
M.
Krompiec
,
S.
Greedy
,
C.
Deibel
, and
R. C. I.
MacKenzie
,
Adv. Funct. Mater.
30
,
1907259
(
2020
).
42.
T.
Dylla
,
S.
Reynolds
,
R.
Carius
, and
F.
Finger
,
J. Non-Cryst. Solids
352
,
1093
(
2006
).
43.
D. B.
Mitzi
,
J. Mater. Chem.
14
,
2355
(
2004
).
44.
J. G.
Simmons
,
J. Phys. Chem. Solids
32
,
1987
(
1971
).
45.
S. L. M.
van Mensfoort
and
R.
Coehoorn
,
Phys. Rev. B
78
,
085207
(
2008
).
46.
R. S.
Crandall
,
J.
Yang
, and
S.
Guha
,
MRS Proc.
664
,
A19.2
(
2001
).
47.
T.
Eisenbarth
,
T.
Unold
,
R.
Caballero
,
C. A.
Kaufmann
, and
H. W.
Schock
,
J. Appl. Phys.
107
,
034509
(
2010
).
48.
L. M.
Mansfield
,
R. L.
Garris
,
K. D.
Counts
,
J. R.
Sites
,
C. P.
Thompson
,
W. N.
Shafarman
, and
K.
Ramanathan
,
IEEE J. Photovolt.
7
,
286
(
2017
).
49.
D.
Menossi
,
E.
Artegiani
,
A.
Salavei
,
S.
Di Mare
, and
A.
Romeo
,
Thin Solid Films
633
,
97
(
2017
).
50.
Z.
Ni
,
C.
Bao
,
Y.
Liu
,
Q.
Jiang
,
W. Q.
Wu
,
S.
Chen
,
X.
Dai
,
B.
Chen
,
B.
Hartweg
,
Z.
Yu
,
Z.
Holman
, and
J.
Huang
,
Science
367
(
80
),
1352
(
2020
).
51.
S.
Ravishankar
,
T.
Unold
, and
T.
Kirchartz
, arXiv:2008.02892.

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