Phytoremediation PDF

Summary

This presentation discusses phytoremediation, a plant-based approach to cleaning up contaminated sites. The approach uses plants to remove pollutants, potentially offering an environmentally-friendly and cost-effective alternative to traditional methods. It covers different types of phytoremediation and its applications, with a focus on the role of plants in stabilizing and removing contaminants from the soil and water.

Full Transcript

Phytoremediation

M.K. Beals
 Phytoremediation
– “ Phyton” = Plant (in greek)
– “ Remediare” = To remedy (in latin).
– Phytoremediation can be defined as the use of
green plants to remove the pollutants from the
environment or to render them harmless.
– An innovative clean-up technology by use of
various plants for treatment of contaminated
soils and water.
– The Basic Principle behind Phytoremediation is
that, plant roots either break the contaminant
down in the soil, or suck the contaminant up,
 Phytoremediation
Phytoremediation can occur through
a series of complex interactions
between plants, microbes, and the
soil, including accumulation,
hyperaccumulation, exclusion,
volatilization, and degradation.
Plants also stabilize mobile
contaminated sediments by forming
dense root mats under the surface.
Phytoremediation
 What is
– the use Phytoremediation?
of green plants to clean-up
contaminated hazardous waste sites.
– The idea of using metal-accumulating
plants to remove heavy metals and other
compounds
– first introduced in 1983, but the concept
has actually been implemented for the past
300 years on wastewater discharges.
– A general, visual reference concerning
plant-based mechanisms used to
remediate the environment
 What is Phytoremeditaion?

– has the potential to clean an estimated
30,000 contaminated waste sites throughout
the US according to the EPA’s Comprehensive
Environmental Response Compensation
Liability Information System (CERCLIS).
– Sites included in this estimate are those that
have either been owned or contaminated by:
battery manufacturers, electroplating, metal
finishing, and mining companies. Also
included are producers of solvents, coated
glass, paints, leather, and chemicals.
What is Phytoremediation?
– Phytoremediation is aimed at providing an
innovative, economical, and environmentally-friendly
approach to removing toxic metals from hazardous
waste sites.
– The foundation of phytoremediation is built upon the
microbial community, and the contaminated
soil/water environment.
– Plants exudate from their roots a variety of organic
compounds that support the microbial community
and facilitate the uptake of some metals.
– The complex interactions among the roots, microbes,
metals, and soil make phytoremediation a highly site-
specific technology.
 Why phytoremediation ?
– Various Remediation procedures
– Conventional measures
– Land filling and leaching
– Excavation
– Burial or soil washing
– Soil flushing
– However these approaches are cost intensive,
not economically viable, intrusive in nature
and cause soil degradation, not bonafide
decontamination measures but a temporary
evasion of problem, destabilize natural
 Why phytoremediation? Cont’d
– Microbial measures
– Decontamination of polluted land through
– application of immobilized microbial enzymes
– Use of resistant micro organisms like fungi, bacteria
– vesicular arbuscular mycorrhizae
– These microbial approaches are ecological and
economically sound but physical removal / cleaning up
of the contaminants does not occur as contaminants
remain in the soil system.
- Chemical extraction procedures have been
suggested but they are not cost effective.
– So these constraints have forced the researchers to
think of using plants for cleaning up their own support
 Pollution
Classification
A major distinction
– Heavy metals between elemental and
organic pollutants: Most
– Phosphate organic pollutants can be
mineralized, while
– Arsenate elements cannot.
– Nitrogen
Source
– Insecticides Agriculture (pesticides,
– Herbicides herbicides, irrigation
water), mining, transport,
– PCBs, TCE,... spills (fuel, solvents),
military activities
– Radionuclides (explosives, chemical
weapons), industry
Because biological processes are ultimately
solar-driven, phytoremediation is on average
tenfold cheaper than engineering-based
remediation methods such as soil excavation,
soil washing or burning, or pump-and-treat
systems.
Phytoremediation is usually carried out in situ
contributes to its cost-effectiveness and may
reduce exposure
Examples of the polluted substrate to
in detail
humans, wildlife, and the environment.

 Phytoextraction (As/ H3PO4/
metals)
 Phytodegradation/
Phytotransformation
 Phytodegradation of explosives

 Application of
Phytoremediation
It can be effectively carried out for
remediation of
– Heavy metals
– Petroleum hydrocarbons
– Chlorinated solvents
– Pesticides
– Radio nuclides
– Explosives
– Excess nutrients
Phytoremediation
 Phytostabilizati
Phytoextraction
on

Phytodegredati Rhizodegredati
on on

Phytovolatilizat
Rhizofiltration
ion
 Types of Phytoremediation
Phytotransformation – uptake of contaminants from soil &
groundwater by plants and their subsequent transformation in roots,
stems, and leaves.
Rhizosphere Bioremediation – occurs in the root-zone; also known
as phytostimulation or plant-assisted bioremediation; results in
increase of soil organic carbon, and bacterial and fungal
populations.
Phytostabilization – refers to holding of contaminated soils in place
by vegetation, and immobilization (physically or chemically) of
contaminants.
Phytoextraction – use of metal-accumulating plants that translocate
metals from the soil to their roots and concentrate the metals to
aboveground stems and leaves.
Rhizofiltration – use of plants to absorb, concentrate, and/or
precipitate metal contaminants from surface waters(treatment
wetlands) or groundwater
 Types of Phytoremediation for Inorganic
Compounds
Type of Phytoremediation Process Involved Contaminant Treated*
Phytostabilization Plants control pH, soil gases, Proven for heavy metals in
and redox conditions in soil mine tailing ponds
to immobilize contaminants.
Humification of some
organic compounds is
expected.

Rhizofiltration or Compounds are taken up or Heavy metals and
contaminant uptake sorbed by roots (or sorbed to radionuclides
algae and bacteria).

Phytoaccumulation, Metals and organic Nickel, zinc, lead,
phytoextraction, or chemicals are taken up by chromium,
hyperaccumulation the plant with water, or cadmium, selenium, other
by cation pumps, sorption, heavy metals; radionuclides
and other mechanisms.

Phytovolatilization Volatile metals are taken up, Mercury and selenium
changed in species, and
transpired.
Phytoremediation Mechanics
 Plant response to heavy
metals
–Metal excluders: prevent metal
from entering their aerial parts.
–Metal indicators: actively
accumulate metal in their aerial
tissues and reflect metal level in
soil.
–Metal accumulator plant species:
–concentrate metal in their aerial
Phytoremediation Mechanics
 Hyper-accumulators Plants
so called hyperaccumulators are usually used, they
take up 100 times the concentration of metals over
other plants
Hyper-accumulators
– A plant is classified hyper accumulators when it takes
heavy metals against their conc. Gradient between the
soil solution and cell cytoplasm.
– Acquiring capacity of accumulating a very high metal
conc. In tissues without much difficulty in carrying out
growth and metabolic functions.
– A hyperaccumulator will concentrate more than:
– - 100 ppm for Cd
– -1,000 ppm for Co and Pb
 Heavy metal hyperaccumulators

Thlaspi montanum var. montanum, a Ni-hyperaccumulator plant that grows on Serpentine soils,
research of Martha Palamino, IB graduate student (UC Berkeley).
 Hyperaccumulator
Alyssum serpyllifolium
plants
Brassica juncea

Thlaspi caerulescens

Pteris
vittata
 Genetic Engineering to
improve phytoremediation
– To breed plants having superior
phytoremediation potential with high biomass
production can be an alternative to improve
phytoremediation.
– To implant more efficient accumulator gene
– into other plants.
– E.g. The γ-ECS transgenic seedlings showed
increasedtolerance to cadmium and had higher
concentrations of Phytochelatins, γ-
GluCys,glutathione, and total nonprotein thiols
compared to wild type seedlings.
 Advantages of
– WorksPhytoremediation
on a variety of organic & inorganic
compounds.
– Can be either In situ/ Exsitu
– Easy to implement & maintain.
– Low cost compared to other treatment
methods.
– Environmental friendly & aesthetically
pleasing to the public.
– Reduces the amount wastes to be landfilled
– High efficiency
– Easy operation ( large scale suitability )
 Disadvantages of
Phytoremediation
– Long length of time required for
remediation.
– Depends on climatic condition.
– Restricted to sites with shallow
contamination within rooting zone.
– Possible effect on the food chain.
– Consumption of contaminated plant
tissue is also a concern.
– Possible uptake of contaminants into
Future Research needs
– Government and industry
commitment to a multiyear field
program.
– Develop research strategies to
address concerns with mixed
contaminant systems.(petroleum
hydrocarbons-salts-heavy metals)
– Support for establishment of multiple
use, controlled, field-scale
phytoremediation research facility.
 SUMMARY
–Research and development of
phytoremediation are just beginning.
–Advances in phytoremediation
appear in several aspects: Theory,
Research and Practice.
–Using natural green resources to
tackle natural environment pollution
will be encouraged.
 Conclusion
It is a fast developing field, since last
10 yrs lots of field application were
initiated all over the world.
Sustainable and inexpensive process is
available alternative to conventional
remediation method.
Man has thus sought the aid of nature’s
own siblings (plants) by exploring the
extrovert relationship between the
roots and the Environment, aided by his
Scientific Outlook to create economical