Low-dimensional materials are essential in optoelectronic, electrical, and contemporary photonics areas because of their specific properties with decreased dimensions. Low-dimensional materials are those with dimensions in the nanoscale range that are between 1 and 100 nm. Halide perovskites of low dimension can be produced inexpensively using solution-processable procedures, unlike usual semiconductor nanomaterials. Since halide perovskite in thin layers may be produced utilizing a variety of solution-based techniques like simple spin coating. It is possible to produce it with a variety of compositions using low-cost, simple, and large-scale procedures. Quantum dots, perovskite nanoplatelets, nanosheets, perovskite nanorods or nanowires, and other low-dimensional perovskites are all examples of such small-dimensional devices that have been created in a range of morphologies (two-dimensional). In this work, a 1D array of perovskite solar cells (methyl ammonium lead halide) is modeled, and a performance study is done using the Finite Element method. It is observed that the proposed 1D array of methyl ammonium lead halide perovskite solar cells gains in recombination rate from 10-2 to 108, compared to 10-11 to 10-6 for the Si array. In addition, other core parameters, like the open circuit voltage Voc, the short-circuit current density Jsc, and peak power Pmax, are included. In this paper, 1-D nano technology is proposed for electric vehicles as coating material on the roofs or doors. Because of their surface to volume ratio, the throughput will serve the vehicle for its purpose.