Sections
- Alternative Therapies
- Blood, Heart and Circulation
- Bones and Muscles
- Brain and Nerves
- Cancers
- Child health
- Cosmetic Surgery
- Digestive System
- Disorders and Conditions
- Drugs Approvals and Trials
- Environmental Health
- Ear, Nose and Throat
- Eyes and Vision
- Female Reproductive
- Genetics and Birth Defects
- Geriatrics and Aging
- Immune System
- Infections
- Kidneys and Urinary System
- Life style and Fitness
- Lungs and Breathing
- Male Reproductive
- Medical Breakthroughs
- Mental Health and Behavior
- Metabolic Problems
- Oral and Dental Health
- Pregnancy and Childbirth
- Public Health and Safety
- Skin, Hair and Nails
- Substance Abuse
- Surgery and Rehabilitation
Nanosponge filters out herbicide poisons
A new metal organic framework can effectively filter toxins from water.
New research has demonstrated the potential of a new kind of nanomaterial to filter out environmental toxins in water.
A team of researchers led by Dr Mainak Majumder and Phillip Sheath from Monash University's Department of Mechanical Engineering and Dr Matthew Hill from CSIRO have developed a highly-porous Metal Organic Framework (MOF) that, almost uniquely, is stable and able to filter substances in water.
MOFs are clusters of metal atoms connected by organic molecules and known for their exceptional abilities to store or separate gases such as carbon dioxide. This is one of the first studies to demonstrate their separation applications in an aqueous environment.
Dr Majumder said the uniform structure of MOFs made them very efficient filters.
"These are crystalline materials with a difference - they have pores that are all exactly the same size. So while one substance can fit in the pores and be captured, another, just one tenth of a nanometre bigger, can’t fit," Dr Majumder said.
"As a result you can detect and capture substances that are present in low concentrations, or in a mixture with other materials."
The researchers demonstrated the filtering ability of the new MOF by sieving paraquat - a herbicide that has been linked with the onset of Parkinson's Disease. The MOF was a very precise filter, removing paraquat, but leaving other contaminants.
"Because MOFs are flexible, we found that their structure changed when they absorbed the paraquat. This means that our MOF could form the basis of a device for quickly and easily testing for the contaminant in water," Dr Hill said.
"Due to its very precise filtering properties, this testing application could deliver very accurate contamination readings in the field."
Only one contaminant, paraquat, was tested in this study; however, the MOF could be altered to filter out other contaminants.
The research was published in the journal Chemistry of Materials and highlighted in the prestigious journal, Science.
Monash University'
Email to a friend
Print version
Plain text
Post your comment