Post on 27-Jul-2020
Bio-renewables:
A Sustainable Source of Chemicals
and Materials
James Clark
Green Chemistry Centre of Excellence
Chemistry Department
University of York, UK
www.greenchemistry.net
Petroleum
feedstock
Fuels
Solvent
Bulk chemicals
Plastics
Fibres
Fine chemicals
Petroleum Refinery
We know that our current fossil resources are not a
sustainable source of carbon
But its not only our carbon consumption
patterns that are not sustainable...
Fuels
Solvent
Bulk chemicals
Plastics
Fibres
Fine chemicals
Oils
Bio-refinery
Biomass
Don’t use food quality feedstocks!!
Our major challenge continues to be Carbon
Whats available from our existing food supply chains?
• • •
• •
• WORLD
• Rice husks 110 million T/yr
• Citrus peel residue 15.6 million T/yr
• Apple pomace 3-4.2 million T/yr
• Grape pomace 5-9 million T/yr
• Banana peels 9 million T/yr
• Kiwi residue 0.3 million T/yr
AFRICA
• Citrus waste 139,724 T/yr (South Africa)
• Cocoa pods 20 million T/yr (Ivory Coast)
• Cashew Shell Nut Liquid 20,000 T/yr (Tanzania)
U.S.A.
•Whey 43,091,275 T/yr
• Corn stover 80–100 million T/yr (dry basis)
California:
• Vegetable crop residue 1 million T/yr (dry basis)
• Tomato pomace 60,000 T/yr (dry basis)
• Nut shells & pits 40,000 T/yr
• Meat processing waste 65,000 T/yr (dry basis)
• Food scraps in MSW 1.6-2 million T/yr (dry basis)
E.U.
• Starch 8 million T/yr
• Tomato pomace 4 million T/yr
• Post manufacturing food waste 34 million T/yr
• Used cooking oil 0.7-1 million T/yr
• Surplus whey 13,462 T/yr
• Surplus wheat straw 5.7 million T/yr (UK)
• Bread surplus 680,000 T/yr (UK)
• Citrus waste 0.6 million T/yr (Spain)
ASIA
• Palm oil 15.8 million T/yr (Indonesia)
• Food waste 1.2 million T/yr (Hong Kong)
•-25MMT rice straw burned in open fields
(Vietnam)
•India??
MEDITERRANEAN BASIN
• Olive mill residue 30 million T/yr
BRAZIL
• Sugar cane bagasse 376.5
million T/yr
• Corn residue 41.7 million T/yr
• Cassava residue 51.6 million T/yr
• Rice straw 4.5 million T/yr
• Wheat straw 5.4 million T/yr
• Citrus residues 9.4 million T/yr
Food supply
chain residues
sugars phenols
collagen
starch
natural dyes
chitosan
cellulose
pectin
hemicellulose
waxes
films bio-adhesives
hydrogels
natural chelants
bio-solvents
chemical
monomers
nanocomposites
bio-surfactants
PVC replacements
Chemicals from food waste
Liquid fuels
cosmetic waxes
solid fuels
hydrophobes
lignin
Benign extraction
Extractables
Materials Chemicals
AD
DIN
G V
AL
UE
Biomass
Green, eg
supercritical
extraction
technologies
Green biochemical (eg fermentation)
and chemical (eg microwave)
Processing technologies
plus
Pre-processing
Eg pelletising
Fuels
Renewable Resources
and Materials
Microwave Chemistry
and Processing
Natural and Bio-derived
Solvents
Clean Synthesis and
Platform Molecules
Fro
m w
aste to w
ealth u
sing
Green
Chem
istry
Creating value from
waste polysaccharides
pyrolysis hydrolysis
chemical products
syngas bio-oil char sugars
fermentation
platform molecules
fuels
+ platform molecules
polysaccharides direct use
Surface Area < 1 m2g-1
Pore Volume < 0.002 cm3g-1
Food waste….
Porous polysaccharide-derived materials
Native Starch Expanded Starch
10 µm 2 µm
Surface Area > 180 m2g-1
Pore Volume > 0.5 cm3g-1
STARBONS®
An exciting new class of carbonaceous materials
Adjustable surface
energies and polarities
High mesoporocity and
surface areas
Readily functionalisable
with acid/base/metal
functionality
Excellent solvent stability
Good chemical and heat
resistance
Controllable electrical
conductivity
Formation of composites
and blends
Particulate/ monolithic
forms
Properties
Separation media
Catalysis
Absorbency
Water purification
Fuel cells
Applications
0.07 g/cm3
200C-0.12g/cm3 550C - 0.29 g/cm3
Now Starbon-technologies.ltd
Extraordinary range of properties
Heterogeneous Catalysis Applications
STARBON® C SERIES
• Works in aqueous and non aqueous systems and including fermentation broths
• Stable up to 260°C
• Make active and selective solid acids
• Make active solid bases
• Group loading 0.3 - 1.0 mmol/g
• Bind and stabilise nanometals
©2012 STARBON® TECHNOLOGIES LIMITED
Major platform molecules via fermentation
OHOH
O
O
OHOH
O
O
OHOH
O
O
OH
O
O
OOH
OO
OH
OHOH
O
ONH2
OH
O
NH2
O
OH
OOH
OH
OH
OH
OH
OH
O
OH OH
OHOH
OH
OH
OH
OH
OH OH
OH
OH
OH
OH
OH OH
O
OHOH
O
OOH
O O
OH
A very wide range of useful products
Clean
Synthesis
methods
Chromatographic Applications STARBON® S SERIES
• Separations that are difficult or impossible any other way
• High mesopore volume 0.48 to 0.60 cm3g-1
• High mesopore proportion 80%
• Average pore diameter 11 to 12 nm
• Hydrophilic or Hydrophobic options
• Available as small, regular <5 micron beads
©2012 STARBON® TECHNOLOGIES LIMITED
And also for separations…
STARBONS® for adsorbing small
organics Phenols:
OH OH
CH3
OH
F
OH
OMeOH
NH2
Phenol
o-Cresol
2-Fluorophenol
4-Methoxy
phenol
3-Aminophenol
Rate of adsorption:
Starbon® is sustainable, reusable and environmentally benign.
Extracting chemicals from
the surface of biomass
Extractables…….…Eco-waxes (Croda)
Biomass (agro/food/ forestry waste)
ScCO2 extraction Wax products
Cosmetic Products
Lignocellulose
- Strawboard
- Garden Mulch - Pulp & Paper
-Bioethanol -Electricity
Health Products
Semiochemicals
Renewable resource+CO2 extraction = EU “natural”
Plant waxes (surface chemicals)
Sterols/ Steryl esters OH
O
O
Esters
Resin acids
OH
O
Fatty acids
Glycerides
O
O
O
O
O
OCOOH
Chemicals from Agro residues using CO2
Extracted and fractionated using supercritical and liquid CO2
Cosmetics, surface coatings, health supplements…
But very limited as a reaction solvent
A Hunt et al, ChemSusChem, 2010, 306
Inorganic
Petroleum Biomass
Conventional
+
Neoteric
(e.g. Ionic
Liquids)
‘Natural’ solvents
CO2 + Water
Bio-solvents eg
Ethanol
Ethyl acetate
Ethyl lactate
2-MeTHF
limonene
Solvents
Greener Solvents the greatest process challenge?
2-Methyltetrahydrofuran- a case study
THF 2-MeTHF
Water miscible Immiscible
Higher peroxide formation Lower peroxide formation
Can be bio-derived Bio-derived
Solvent for organometallics Replacement for THF and DCM
‘Natural’ solvent
O O O O
D-Limonene p-Cymene
Amidation and Esterification in Bio-Solvents Using Silica as a “green Catalyst”
100 °C R
O
OH
Ph NH2
R
O
NH
Ph
R = 4-Phenylbutyl
50 °C
Pr
O
O
O
Pr
OHBu
Pr
O
OBu
R = 4-Phenylpropyl
Orange peel
J Sherwood et al, Green Chemistry 2012
Solvent Polarity Map (Aprotic)
1 2
9 8
4
7
5 6
3
The challenge is enormous!
Sustainable Solvent Polarity Map (Aprotic)
1 2
9 8
4
7
5 6
3
EtOAc
2-MeTHF
p-Cymene
Glutamic acid
derivatives
Limonene
Acetone
NEt3 ?
Bio-nitro ?
New from the GCCE:
Sustainable Solvents Selection Service- S4 In collaboration with Rafiq Gani and colleagues at DTU
Current solutions are limited
Thermochemical extraction from
and conversion of bulk biomass
Alternative methodologies…….
Biomass
Microwave
processor
Energy
Extracted
oil
Pyrolysis
Oil
Char
Wide range of feedstock
+ = Wide range of products
Flexibility of Microwave Parameters
(time, temperature, power)
Low Temperature
Microwave Treatment of Biomass
“The preparation of high-grade bio-oils through the controlled, low temperature microwave activation of wheat straw”. Bioresource
Technology (2009) 100(23),6064-6068..
Temperature of decomposition comparison
There is a correlation between temperature of phase transition in biopolymers
and temperature of MW pyrolysis
Torrefaction/biochar production by microwave and conventional slow pyrolysis – comparison of energy
Properties. GCB Bioenergy (2012), doi: 10.1111/gcbb.12021
Microwave Assisted Cellulose Hydrolysis
Sugars yield increases substantially in the
presence of microwave irradiation
Case studies and future biorefineries
60% of Orange Peel was transformed to valuable products
CHEMSUSCHEM, 2012, 5 (9), 1694-1697
A new OPEC-
Orange Peel Exploitation Company
Solid char 35 % of total mass
58% of total energy
Biomass
Microwave Processing
Aqueous fraction 31% of total mass
5% of total energy
Market:
Bio-alcohol
Transport fuel
Gas fraction 14% of total energy
Market:
PowerStation
Co-firing
Power generation 10% of total energy
Microwave Biorefinery Flow Chart
Sugars and Bio-oil 22 % of total mass
23% of total energy
Market:
Chemicals
Green and Sustainable furniture Bio-based composite materials for structural and furniture applications
Overall good metrics for sustainability, greener products,
waste avoidance and low environmental impact manufacturing
Never accept waste, e.g. using the bottom ashes….
Now on a slow
Boat from China!
J Dodson et al, RSC Advances, 2011, 523
Using the bottom ashes to make catalysts
MCM 41
Surface area 1043 m2/g
pore volume 1.12 cm3/g
J Dodson et al, J Mat Chem in the press
We burn an increasing amount of biomass
and other biomass in our power stations
and its rich in metals and silica
We need to think about more than Carbon…..
Elemental unsustainability
H. L Parker, et al, Nano-palladium catalysts directly from plants, Submitted
The Phytocat Project
A G8-Funded collaboration between York, Yale and UBC
• Research
• Industry collaboration
• Education, including
development of teaching and
promotional materials
• Networking with all chemical
stakeholders
Activity Areas
The Centre’s Activities can be groups into 4 areas:
Green Chemistry at York
We are interested in all things chemical
A collaboration between the Green Chemistry Centre and
the Centre for Novel Agricultural Products
www.biorenewables.org
Continuous microwave processor. 30 kg/h
Green Chemistry at York is growing fast!
Food waste valorisation for sustainable
chemicals, materials and fuels (EUBIS)
TD1203
Working Group 1:
Pre-treatment and extraction
Working Group 2:
Bioprocessing
Working Group 3:
Chemical processing
Working Group 4:
Technical and sustainability (policy) analysis
Research
Industry
Networking
Education
www.greenchemistry.net