Solar Energy Takes on a Third Dimension

The biggest boosts in power were seen in the sit­u­a­tions where improve­ments are most needed: in loca­tions far from the equa­tor, in win­ter months and on cloudier days. The new find­ings, based on both com­puter mod­el­ing and out­door test­ing of real mod­ules, have been pub­lished in the jour­nal Energy and Environmental Science.

“I think this con­cept could become an impor­tant part of the future of pho­to­voltaics,” says the paper’s senior author, Jeffrey Grossman, the Carl Richard Soderberg Career Development Associate Professor of Power Engineering at MIT.

The MIT team ini­tially used a com­puter algo­rithm to explore an enor­mous vari­ety of pos­si­ble con­fig­u­ra­tions, and devel­oped ana­lytic soft­ware that can test any given con­fig­u­ra­tion under a whole range of lat­i­tudes, sea­sons and weather.

Then, to con­firm their model’s pre­dic­tions, they built and tested three dif­fer­ent arrange­ments of solar cells on the roof of an MIT lab­o­ra­tory build­ing for sev­eral weeks.

While the cost of a given amount of energy gen­er­ated by such 3-D mod­ules exceeds that of ordi­nary flat pan­els, the expense is par­tially bal­anced by a much higher energy out­put for a given foot­print, as well as much more uni­form power out­put over the course of a day, over the sea­sons of the year, and in the face of block­age from clouds or shad­ows. These improve­ments make power out­put more pre­dictable and uni­form, which could make inte­gra­tion with the power grid eas­ier than with con­ven­tional sys­tems, the authors say.

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