Frankland, “How Fillers Impact Extrusion Processing,” Plastics Technology (Nov. 2011), www.ptonline.com/columns/how-fillers-impact-extrusion-processing Biobased fibers and fillers come from renewable resources, such as the waste from harvesting and processing agricultural products or sometimes from nonfood crops, such as hemp, grown specifically for industrial use. These oxides have high thermal and electrical conductivity (although hematite can conduct more heat), can block radiation, and can dampen sound.

Frankland, “How Fillers Impact Extrusion Processing,” Plastics Technology (Nov. 2011), www.ptonline.com/columns/how-fillers-impact-extrusion-processing Biobased fibers and fillers come from renewable resources, such as the waste from harvesting and processing agricultural products or sometimes from nonfood crops, such as hemp, grown specifically for industrial use. These oxides have high thermal and electrical conductivity (although hematite can conduct more heat), can block radiation, and can dampen sound.

Frankland, “How Fillers Impact Extrusion Processing,” Plastics Technology (Nov. 2011), www.ptonline.com/columns/how-fillers-impact-extrusion-processing Biobased fibers and fillers come from renewable resources, such as the waste from harvesting and processing agricultural products or sometimes from nonfood crops, such as hemp, grown specifically for industrial use. These oxides have high thermal and electrical conductivity (although hematite can conduct more heat), can block radiation, and can dampen sound.

Frankland, “How Fillers Impact Extrusion Processing,” Plastics Technology (Nov. 2011), www.ptonline.com/columns/how-fillers-impact-extrusion-processing Biobased fibers and fillers come from renewable resources, such as the waste from harvesting and processing agricultural products or sometimes from nonfood crops, such as hemp, grown specifically for industrial use. These oxides have high thermal and electrical conductivity (although hematite can conduct more heat), can block radiation, and can dampen sound.

Frankland, “How Fillers Impact Extrusion Processing,” Plastics Technology (Nov. 2011), www.ptonline.com/columns/how-fillers-impact-extrusion-processing Biobased fibers and fillers come from renewable resources, such as the waste from harvesting and processing agricultural products or sometimes from nonfood crops, such as hemp, grown specifically for industrial use. These oxides have high thermal and electrical conductivity (although hematite can conduct more heat), can block radiation, and can dampen sound.

Frankland, “How Fillers Impact Extrusion Processing,” Plastics Technology (Nov. 2011), www.ptonline.com/columns/how-fillers-impact-extrusion-processing Biobased fibers and fillers come from renewable resources, such as the waste from harvesting and processing agricultural products or sometimes from nonfood crops, such as hemp, grown specifically for industrial use. These oxides have high thermal and electrical conductivity (although hematite can conduct more heat), can block radiation, and can dampen sound.

Frankland, “How Fillers Impact Extrusion Processing,” Plastics Technology (Nov. 2011), www.ptonline.com/columns/how-fillers-impact-extrusion-processing Biobased fibers and fillers come from renewable resources, such as the waste from harvesting and processing agricultural products or sometimes from nonfood crops, such as hemp, grown specifically for industrial use. These oxides have high thermal and electrical conductivity (although hematite can conduct more heat), can block radiation, and can dampen sound.

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Patterson Page 46 United States 67% Europe 17% Canada 11% Asia 5% United States 60% Europe 19% Canada 9% Asia 7% Latin America 5% Customer-Driven Globalization 2006 2011* *Pro forma for the acquisition of ColorMatrix • Differentiated by our consistent service and quality offerings globally • Invested in global account management organization to serve over 100 multinational key accounts Page 47 • Leverage technology development and best practices to better serve global customers • Drive global marketing strategies for growth with target customers & markets Formation of Global Segments in 2010 • Accelerate decision making and assure consistent execution of four pillar strategy for growth with target customers & markets Page 48 Recent Investment Activity • 67% of recent commercial additions are outside the U.S �Focus areas of expansion in Eastern Europe, Russia, Asia, and South Africa �Megatrend toward lighter-weight packaging supports accelerated growth in barrier supports accelerated growth in barrier additive technologies • Gained foothold in Brazil through Specialty platform with acquisitions Page 50 Critical Imperatives • Focus on global key accounts, and continue investment in commercial resources supporting multinational accounts • Strengthen our presence in emerging markets• Strengthen our presence in emerging markets • Accelerate growth in Asia • Pursue appropriate acquisition opportunities Page 51 Page 52