Production of biochar from biomass
2
Page 43 / WISEST Special Issue / Volume 2 / DOI: 10.29173/aar50 albertaacademicreview.com Production of biochar from biomass Iqmat Iyiola 1 , Deepak Pudasainee 1 , Md Khan 1 , Rajender Gupta 1 1 Department Chemical and Materials Engineering, University of Alberta Key words: biomass, biochar, TGA, proximate analysis, elemental analysis, chemical engineering Abstract Biochar is a kind of charcoal that’s produced from biomass using pyrolysis technology. As climate change continues to be a growing concern, biochar has been sought for its environmental applications. It is both cost effective and environmentally sound in terms of being a soil additive and renewable fuel. When used as a soil amendment, biochar has been shown to improve water holding capacity and absorb more nutrients. Biochar also sequesters carbon dioxide when applied to soil, and can also be used as a replacement for activated carbon that is prepared from coal. The objectives of this research was to produce biochar from biomass and study biochar’s properties. A thermogravimetric analysis (TGA) was used to measure the weight loss behavior of the wood sample (biomass) as the temperature increased. The biomass was heated to 500 °C in a nitrogen atmosphere and then cooled in nitrogen to prevent combustion of biochar. The overall yield of biochar was 15%. Elemental analysis of biomass shows the composition of the sample to be mostly carbon and oxygen with fewer amounts of hydrogen and nitrogen. Surface area of the prepared biochar was 305 m2/g, which is approximately 100 times the surface area of raw biomass. Biochar’s higher porosity will allow for greater absorption of nutrients when applied to soil. Cite as: Iyiola I., Pudasainee D., Khan M., and Gupta R. 2019. Production of biochar from biomass. Alberta Academic Review, Vol 2 (2) 43-44, WISEST Special Issue (not peer- reviewed), DOI 10.29173/aar50. ISSN 2561-5327 (print) ISSN 2561-5335 (online)
Transcript of Production of biochar from biomass
Page
43
/ WIS
EST
Spec
ial I
ssue
/ Vo
lum
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/ DO
I: 10
.291
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ar50
albertaacademicreview.com
Production of biochar from biomass Iqmat Iyiola1, Deepak Pudasainee1, Md Khan1, Rajender Gupta1
1Department Chemical and Materials Engineering, University of Alberta
Key words:biomass, biochar, TGA, proximate analysis, elemental analysis, chemical engineering
Abstract
Biochar is a kind of charcoal that’s produced from biomass using pyrolysis technology. As climate change continues to be a growing concern, biochar has been sought for its environmental applications. It is both cost effective and environmentally sound in terms of being a soil additive and renewable fuel. When used as a soil amendment, biochar has been shown to improve water holding capacity and absorb more nutrients. Biochar also sequesters carbon dioxide when applied to soil, and can also be used as a replacement for activated carbon that is prepared from coal. The objectives of this research was to produce biochar from biomass and study biochar’s properties. A thermogravimetric analysis (TGA) was used to measure the weight loss behavior of the wood sample (biomass) as the temperature increased. The biomass was heated to 500 °C in a nitrogen atmosphere and then cooled in nitrogen to prevent combustion of biochar. The overall yield of biochar was 15%. Elemental analysis of biomass shows the composition of the sample to be mostly carbon and oxygen with fewer amounts of hydrogen and nitrogen. Surface area of the prepared biochar was 305 m2/g, which is approximately 100 times the surface area of raw biomass. Biochar’s higher porosity will allow for greater absorption of nutrients when applied to soil.
Cite as: Iyiola I., Pudasainee D., Khan M., and Gupta R. 2019. Production of biochar from biomass. Alberta Academic Review, Vol 2 (2) 43-44, WISEST Special Issue (not peer-reviewed), DOI 10.29173/aar50.
ISSN 2561-5327 (print)ISSN 2561-5335 (online)
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albertaacademicreview.com
Iyiola et al., 2019
Intr
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rom
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Iqm
at Iy
iola
,Md
Kh
an, D
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end
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erta
Lite
ratu
re C
ited
1.La
ird, D
. A.,
Bro
wn,
R. C
., A
mon
ette
, J. E
. and
Leh
man
n, J
. (20
09),
Rev
iew
of t
he p
yrol
ysis
plat
form
for c
opro
duci
ng b
io-o
il an
d bi
ocha
r. B
iofu
els,
Bio
prod
.Bio
ref.,
3: 5
47-5
62.
doi:1
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bb.1
69
2.G
urw
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re L
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A S
yste
mat
ic R
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w o
f Bio
char
Res
earc
h, w
itha
Focu
s on
Its
Sta
bilit
y in
situ
and
Its
Pro
mis
e as
a C
limat
e M
itiga
tion
Stra
tegy
. PLo
S O
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8(9)
: e75
932.
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2
Figu
re4:
TGA
curv
eto
show
wei
ghtl
oss
atdi
ffere
ntte
mpe
ratu
res
Figu
re5:
Cha
ryi
eld
atdi
ffere
ntte
mpe
ratu
res.
Par
ticle
size
ofth
ebi
omas
sus
edw
as42
5mic
ron
to2m
m
•B
ioch
ar w
as p
repa
red
in la
bora
tory
usi
ng T
GA
.
•Th
ebi
omas
sw
eigh
tlo
ssw
asap
prox
imat
ely
80%
.Fi
nal
bioc
hary
ield
was
abou
t15%
.
•P
roxi
mat
e an
alys
is o
f bio
mas
s sh
ows
that
the
sam
ple
cont
ains
6.5%
moi
stur
e, 7
6% v
olat
ile, 1
6%fix
edca
rbon
, and
1.5
%as
h.
•E
lem
enta
l ana
lysi
s of
bio
mas
s sh
ows
the
com
posi
tion
of th
esa
mpl
e to
be
mos
tly c
arbo
n an
d ox
ygen
with
less
am
ount
s of
hydr
ogen
and
nitr
ogen
.
•S
urfa
ce a
rea
of th
e pr
epar
ed b
ioch
ar w
as 3
05m
2 /g,
whi
chis
appr
oxim
atel
y 10
0 tim
es th
e su
rface
area
of r
aw b
iom
ass.
Tabl
e 1:
Pro
xim
ate
Ana
lysi
s (w
eigh
t per
cent
age)
Con
clus
ions
Sam
ple
Mo
istu
re
Vo
lati
leA
sh
Fix
ed
Carb
on
Wo
od
6.5
76
1.5
16
•B
iom
ass
isa
rene
wab
leso
urce
ofen
ergy
that
com
esfro
man
imal
and
plan
tmat
eria
ls.[
1 ]
•B
ioch
aris
aki
ndof
char
coal
that
ispr
oduc
edfro
mbi
omas
sus
ing
pyro
lysi
ste
chno
logy
.
•Th
ere
are
mul
tiple
envi
ronm
enta
land
agro
nom
icbe
nefit
sw
hen
bioc
hari
sus
edas
aso
ilam
endm
ent.
[2]
•R
epor
tson
the
impa
ctof
bioc
har
onso
ilin
dica
teth
atbi
ocha
rqu
ality
isim
porta
ntfo
rcro
pyi
elds
.
•Th
eob
ject
ive
ofth
isre
sear
chis
topr
oduc
ebi
ocha
rfro
mbi
omas
san
dto
stud
yits
prop
ertie
s.
Figu
re1:
TG
A Le
co
Su
pp
ort
edB
y:
Sam
ple
Carb
on
Hy
dro
gen
Nit
ro
gen
Su
lfu
rO
xy
gen
*
Wo
od
46
6.2
0.2
04
7.6
Tabl
e3:
Sur
face
Are
a &
Por
e Vo
lum
eS
am
ple
Su
rface A
rea
m2/g
To
tal
po
re v
olu
me
cc/g
Wo
od
Ch
ar 5
00
30
52
.00
E-0
1
Tabl
e2:
Ele
men
tal A
naly
sis
(wei
ght p
erce
ntag
e)
Ther
mog
ravi
met
ricA
naly
sis
(TG
A)
was
used
tom
easu
reth
ew
eigh
tlo
ssbe
havi
our
ofth
ebi
omas
sas
tem
pera
ture
incr
ease
s.
Pla
ce ~
4 gr
ams
of b
iom
ass
into
empt
y cr
ucib
le
Figu
re3:
Woo
dis
shre
dded
to1-
2mm
sam
ples
and
then
char
red
inth
eTG
A
Figu
re6:
Bio
mas
saf
ter
shre
ddin
g(4
25m
icro
nto
2mm
)
Figu
re2:
Cha
r pre
para
tion
met
hod
inTG
A
Figu
re7:
Bio
char
obta
ined
at50
0°C
*Cal
cula
ted
from
diff
eren
ce
App
licat
ions
•B
ioch
arha
sbe
ensh
own
toim
prov
ew
ater
hold
ing
capa
city
asit
effe
ctiv
ely
abso
rbs
both
nutri
ents
.
•B
ioch
arca
nbe
used
asa
repl
acem
entf
orth
eac
tivat
edca
rbon
that
ispr
epar
edfro
mco
al(n
on-r
enew
able
reso
urce
)
Hea
ted
at 1
0°C
/min
with
ani
troge
n flo
w o
f 7L/
min
Hea
t to
500°
C
Coo
l usi
ng n
itrog
en
