Styles
About Berling Nova Sans
The Berling typeface, designed by Karl-Erik Forsberg in 1951 for Berlingska in Lund, inspired us to create a completely new sans-serif typeface called Berling Nova Sans. This new typeface was based on the skeletal forms found in Berling Nova. Berling Nova Sans was introduced in 2007 and is marketed and sold by the typeface company Monotype/Linotype.
- Design team
-
Fredrik Andersson, Örjan Nordling, Göran Söderström, and Ylva Lipkin
- Client
-
Geith Forsberg, Gunnar Göranzon, Pia Skantz Larsson (Verbum), and Anna-Maria Högberg (Government Offices).
Opentype features
Regular
Scutellaria
Regular Italic
Helleborus
Bold
Artemisia
Bold italic
Echinacea
Regular
Microscopy has revolutionized the field of botany by enabling scientists to delve deeper into the intricate world of plants. Before the advent of microscopy, botanists relied primarily on observational studies and crude dissections to understand plant structures and functions. However, the invention and refinement of microscopes have provided unprecedented insights into the cellular and molecular realms of plant biology. With the ability to magnify specimens hundreds or even thousands of times their original size, microscopes have unveiled the hidden intricacies of plant tissues, revealing cellular structures such as chloroplasts, vacuoles, and cell walls. This newfound understanding of plant anatomy has paved the way for significant discoveries in areas like photosynthesis, nutrient uptake, and plant development. Moreover, microscopy has facilitated the study of plant pathogens and symbiotic relationships at a microscopic level, aiding in the development of strategies for disease management and crop improvement.
Regular italic
Microscopy has revolutionized the field of botany by enabling scientists to delve deeper into the intricate world of plants. Before the advent of microscopy, botanists relied primarily on observational studies and crude dissections to understand plant structures and functions. However, the invention and refinement of microscopes have provided unprecedented insights into the cellular and molecular realms of plant biology. With the ability to magnify specimens hundreds or even thousands of times their original size, microscopes have unveiled the hidden intricacies of plant tissues, revealing cellular structures such as chloroplasts, vacuoles, and cell walls. This newfound understanding of plant anatomy has paved the way for significant discoveries in areas like photosynthesis, nutrient uptake, and plant development. Moreover, microscopy has facilitated the study of plant pathogens and symbiotic relationships at a microscopic level, aiding in the development of strategies for disease management and crop improvement.
Bold
Microscopy has revolutionized the field of botany by enabling scientists to delve deeper into the intricate world of plants. Before the advent of microscopy, botanists relied primarily on observational studies and crude dissections to understand plant structures and functions. However, the invention and refinement of microscopes have provided unprecedented insights into the cellular and molecular realms of plant biology. With the ability to magnify specimens hundreds or even thousands of times their original size, microscopes have unveiled the hidden intricacies of plant tissues, revealing cellular structures such as chloroplasts, vacuoles, and cell walls. This newfound understanding of plant anatomy has paved the way for significant discoveries in areas like photosynthesis, nutrient uptake, and plant development. Moreover, microscopy has facilitated the study of plant pathogens and symbiotic relationships at a microscopic level, aiding in the development of strategies for disease management and crop improvement.
Bold italic
Microscopy has revolutionized the field of botany by enabling scientists to delve deeper into the intricate world of plants. Before the advent of microscopy, botanists relied primarily on observational studies and crude dissections to understand plant structures and functions. However, the invention and refinement of microscopes have provided unprecedented insights into the cellular and molecular realms of plant biology. With the ability to magnify specimens hundreds or even thousands of times their original size, microscopes have unveiled the hidden intricacies of plant tissues, revealing cellular structures such as chloroplasts, vacuoles, and cell walls. This newfound understanding of plant anatomy has paved the way for significant discoveries in areas like photosynthesis, nutrient uptake, and plant development. Moreover, microscopy has facilitated the study of plant pathogens and symbiotic relationships at a microscopic level, aiding in the development of strategies for disease management and crop improvement.
Extra bold
Microscopy has revolutionized the field of botany by enabling scientists to delve deeper into the intricate world of plants. Before the advent of microscopy, botanists relied primarily on observational studies and crude dissections to understand plant structures and functions. However, the invention and refinement of microscopes have provided unprecedented insights into the cellular and molecular realms of plant biology. With the ability to magnify specimens hundreds or even thousands of times their original size, microscopes have unveiled the hidden intricacies of plant tissues, revealing cellular structures such as chloroplasts, vacuoles, and cell walls. This newfound understanding of plant anatomy has paved the way for significant discoveries in areas like photosynthesis, nutrient uptake, and plant development. Moreover, microscopy has facilitated the study of plant pathogens and symbiotic relationships at a microscopic level, aiding in the development of strategies for disease management and crop improvement.
