New Catalyst for Paper Making - Greener Paper is Not Pulp Fiction

Description and Advantage

Pollution from paper production could be cut, say US chemists, with a new way of refining wood pulp1. But the process must go through the mill before it can convert industry.

During paper production, gluey wood component lignin is stripped out to leave stringy cellulose. The harsh chemicals used create environmental pollutants, such as toxic and long-lasting chlorinated compounds.

A new chemical catalyst makes harmless gas oxygen do the same job, Craig Hill of Emory University in Atlanta, Georgia and his colleagues have shown. "It's set up for being green chemistry," says joint team leader Ira Weinstock of the US Department of Agriculture Forest Service in Madison, Wisconsin.

"It's a noble effort," says industrial chemist William Kruper of the Dow Chemical Company in Midland, Michigan. But unless the catalyst's efficiency is improved, "the industry isn't going to adopt this technology tomorrow", he warns.

Waste paper

Paper manufacturing is one of the world's largest industries. It generates 100 million tonnes of wood pulp a year. Using strong chemicals and high temperatures, pulping digests up to 90% of the lignin from wood chips. The resulting slurry is made into low-quality paper such as brown grocery bags.

For premium white paper, pulp is bleached and the remaining lignin is degraded using chlorine or the more environmentally friendly substitute, chlorine dioxide. These chemicals selectively break down lignin rather than cellulose by stealing its electrons, in an 'oxidation' reaction. The new catalyst replaces this step.

The catalyst - called a polyoxometalate (POM) - was inspired by a protein in wood-digesting fungi. First, POM oxidizes lignin. Then oxygen re-oxidizes POM. This second step converts lignin to harmless carbon dioxide and water and recycles the catalyst.

At the end of the process, the catalyst must be carefully removed to avoid traces ending up in the paper. POM contains the heavy metals tungsten and molybdenum, also of concern to environmentalists.

Although this is "clever chemistry", says Terry Collins of Carnegie Mellon University in Pittsburgh, Pennsylvania, "it's important that people keep experimenting with alternative technologies".

The inefficiency of the reaction means that 170 tonnes of catalyst are needed for every tonne of wood pulp, points out Collins, who works on green chemistry. This ratio would make working with the catalyst an expensive operation. He feels that new processes should aim to be cheap, efficient and non-toxic.

Weinstock argues that these criteria can be met and that the process can be made economically competitive.

References

1. Weinstock, I. A. et al. Equilibriating metal-oxide cluster ensembles for oxidation reactions using oxygen in water. Nature, 414, 191 - 195, (2001).

Source: Nature Science Update, November 2001