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How to Commercialize Chemical Technologies for a Sustainable Future -

How to Commercialize Chemical Technologies for a Sustainable Future

Buch | Hardcover
304 Seiten
2021
John Wiley & Sons Inc (Verlag)
978-1-119-60484-6 (ISBN)
CHF 185,65 inkl. MwSt
The definitive guide for scientific entrepreneurs commercializing sustainable technologies in the chemical sector

Lacking the considerable resources of multinational chemical companies, entrepreneurs face a unique set of risks and challenges. How to Commercialize Chemical Technologies for a Sustainable Future is targeted at innovators who are embarking on the entrepreneurial path with their sustainable chemical technology but are unsure of what steps to take. This first-of-its-kind resource features contributions from a diverse team of expert authors, including engineers, venture capitalists, marketing specialists, intellectual property professionals, regulatory experts, industry practitioners, and many others.

Accessible and highly practical, this real-world guide covers each step of the technology commercialization process, from market landscape analysis and financing to scale-up and strategic partnering. Throughout the book, effective tactics and strategies for growing a new venture are supported by case studies highlighting the economic and environmental impact of successful commercialization, and identifying the common mistakes that lead to lost opportunities. Filled with invaluable advice and actionable steps, this book:



Uses valuation concepts, tools, and examples to demonstrate that for a chemical technology to be sustainable it must not only have market value but also confer benefits to human well-being and the environment
Offers templates and tools for understanding what customers need, who the competition is and how to successfully differentiate your product to those customers
Describes how to practically advance your technology from conception all the way to commercial demonstration
Presents advantages and disadvantages of strategic partnering from the perspective of the start-up and the larger industrial partner, along with strategies to mitigate risks within a partnership
Provides an overview of the legal regulatory requirements for bringing new chemicals to market in several key geographic regions, as well as the impact of public policy on commercialization
Offers insights and practical strategies on intellectual property management, raising investment, and operationalizing a startup company

How to Commercialize Chemical Technologies for a Sustainable Future is essential reading for budding entrepreneurs in chemistry, materials science, and chemical engineering looking to bring their sustainable technologies to market. It is also a valuable reference for investors, policymakers, regulators, and other professionals.

Timothy J. Clark, PhD, is the Technology Leader at GreenCentre Canada. Dr. Clark has held a variety of positions in technology commercialization and business development. He plays a key role in developing and executing integrated technology plans serving both start-up and multinational clients. Dr. Clark is an experienced organometallic and polymer chemist who has published extensively in the open and patent literature. Andrew S. Pasternak, PhD, MBA, is Director of Commercialization and Business Development at GreenCentre Canada. He has over 20 years’ experience managing technical and commercial teams in both large and start-up company environments. A certified Professional Board Director, Dr. Pasternak has successfully established numerous strategic partnerships, high-margin service contracts, and licensing agreements.

List of Contributors xvii

1 Introduction 1
Timothy J. Clark and Andrew S. Pasternak

1.1 What Is This Book About? 1

1.2 What Is a Sustainable Chemical Technology? 3

1.3 Commercializing Sustainable Chemical Technologies Is Challenging 4

1.4 Who Should Read This Book? 5

1.5 Structure of This Book 6

1.6 Using This Book 9

Acknowledgments 9

References 9

Part I Laying the Foundation 11

2 Marketing and Landscape Analysis 13
Tess Fennelly

2.1 Introduction: Think Marketing 13

2.2 Creating a Marketing Plan: The Application Framework 15

2.3 Customer Needs and Mapping 15

2.4 Customer Analysis: How to Gather Customer Needs Data 16

2.4.1 Finding the Right Contacts 18

2.4.2 The Interview Form 18

2.5 Customer Needs Mapping 21

2.6 Market Segmentation 22

2.7 Market Segment Evaluation 25

2.8 Competitive Landscape and Competencies 25

2.9 Conclusion and Next Steps 27

3 Determining the True Value of a Sustainable Chemical Technology 31
Lauren Heine and Margaret H. Whittaker

3.1 Introduction 31

3.2 Sustainable Value and the United Nations Sustainable Development Goals 32

3.2.1 Embracing SDGs at the Business Level: United Nations Global Compact Participation 34

3.3 Life-Cycle Thinking and Life-Cycle Assessment 34

3.4 Attributes and Impacts: Check Your Assumptions 35

3.5 Business Risk and Sustainable Design – Or How to Turn an Externality into a Selling Point 37

3.6 Guiding Principles for Sustainable Chemical Technology Innovations: Chemistry, Carbon, and Circularity 39

3.6.1 Sustainable Materials Management 39

3.6.2 Alternatives Assessment 40

3.7 Chemical and Material Considerations that Impact Sustainable Value 42

3.7.1 Chemistry 42

3.7.2 Carbon 46

3.7.3 Circularity 46

3.8 Introducing Your Sustainable Chemical Technology into the Marketplace 47

3.8.1 Communicating Cost Versus Life-Cycle Benefits 47

3.8.2 Benefiting from a “Green Premium” 47

3.8.3 Avoid Greenwashing 48

3.9 Conclusions 49

References 49

4 Intellectual Property Management and Strategy 55
Nick Sutcliffe

4.1 Intellectual Property 55

4.2 What Is an Intellectual Property Right? 56

4.3 The Value of Intellectual Property Rights to a Sustainable Chemical Technology Company 56

4.4 Patents Explained 58

4.4.1 What Sort of Technology Can Be Patented? 58

4.4.2 What Is a Patent? 58

4.4.3 The Patent Bargain 58

4.4.4 Territorial 58

4.4.5 Time Limitation 59

4.4.6 Property 59

4.4.7 Exclusionary Right 59

4.4.8 Criteria for Patentability 59

4.4.9 Preparing and Filing a Patent Application 61

4.4.10 12-Month Anniversary 62

4.4.11 PCT Applications 63

4.4.12 Patent Examiners 63

4.4.13 Patent Examination 63

4.4.14 Grant 64

4.4.15 Renewal Fees 64

4.4.16 Costs 64

4.5 Building an IP Portfolio 65

4.5.1 Invention Management 65

4.5.2 Deciding Whether to File a Patent Application 66

4.5.3 Inventions Not Patentable or Worth Patenting 67

4.5.4 Patent Attorneys/Agents 67

4.5.5 Ownership 68

4.5.6 When to File a Patent Application 68

4.5.7 Where to File a Patent Application? 69

4.5.8 Controlling the Speed of the Process 70

4.5.9 Managing the Patent Application Process 70

4.6 Avoiding Other People’s IPRs 71

4.6.1 Freedom to Operate 71

4.6.2 Clearing Obstructions 72

4.6.3 Litigation 73

References 76

Part II Political and Environmental Considerations 79

5 Navigating and Leveraging Government Entrepreneurial Ecosystems for Support 81
Janine Elliott and Rohit Sood

5.1 What Is an Entrepreneurial Ecosystem? 81

5.2 Types of Resources Available 82

5.2.1 Financial Resources 82

5.2.2 Nonmonetary Resources 83

5.3 Ecosystems in the United States and Canada 84

5.3.1 Government Agencies 84

5.3.2 Non-profit Organizations 87

5.3.3 Incubators and Accelerators 88

5.3.4 Academic Research Institutions 89

5.3.5 Investors 90

5.3.6 Hybrids of Resources and Players 90

5.4 Ecosystems in the European Union 91

5.4.1 SusChem: A European Technology Platform of Sustainable Chemistry 92

5.4.2 Entrepreneurial Ecosystem Resources 92

5.4.3 Competitiveness of Enterprises and SMEs (COSME) 93

5.4.4 InnovFin – Financing for Innovators 94

5.4.5 European Innovation Council (EIC) Accelerator 94

5.4.6 Other EU Programs for the Entrepreneur 95

5.4.7 Prizes 96

5.5 Setting Priorities When Pursuing Resources 96

5.6 Conclusion: Engage with Your Ecosystem 98

References 101

6 Factoring in Public Policy and Perception 103
Kira Matus

6.1 Introduction 103

6.2 Chemicals and Policy 104

6.2.1 International Policies 105

6.2.2 Regional Policy – The European Union 106

6.2.3 National-Level Policies 107

6.2.4 Policies Beneath the National Level (US) 109

6.3 New Trends and Approaches 110

6.3.1 The Precautionary Shift 110

6.3.2 Attention to Vulnerable Populations 111

6.3.3 Industry, NGOs, the Public, and Other “Governance” Actors 112

6.3.4 Public Perceptions 113

6.4 Conclusion: Policy as Strategic Advantage for the Sustainable Chemistry Innovator 114

6.4.1 Perceptions and Opportunities 114

6.4.2 Practical Actions 115

Acknowledgments 115

References 115

7 Pre-market Approval of Chemical Substances: How New Chemical Products Are Regulated 119
Richard E. Engler

7.1 Introduction 119

7.2 Overview 120

7.3 United States 121

7.3.1 Federal Food Drug and Cosmetic Act (FFDCA) 121

7.3.2 Federal Insecticide, Fungicide, and Rodenticide Act (FIFRA) 124

7.3.3 Toxic Substances Control Act (TSCA) 125

7.4 European Union (EU) 128

7.4.1 Registration 129

7.4.2 Exemptions to REACH Registration 130

7.5 China 131

7.5.1 Registration 131

7.6 Canada 132

7.7 Developing a Global Strategy 134

7.8 Summary 134

References 135

Part III Springing into Action 137

8 Navigating Supply Chains 139
Tess Fennelly

8.1 Introduction 139

8.2 Supply Chain Complexity 139

8.3 Recognizing Points of View 141

8.4 Supply Chain Hurdles and Strategies to Overcome Them 143

8.4.1 Incumbency: Incumbents and Legacy Suppliers Own the Supply Chain, Market Access, and Global Supply 143

8.4.2 Roadblock: Adoption Must Occur at all Points in the Supply Chain in Order to Be Successful 144

8.4.3 Confusion: “Green Washing,” Perceptions, and Misinformation Confuses the Industry and Consumers on What Is Truly More Sustainable, Which Impacts Demand 145

8.4.4 Risk Aversion: Worries of Failure Due to Poor Performance, Brand Tarnishing, Hidden Costs, and Stagnant Product Sales 147

8.4.5 Decision-Makers: Sustainable Corporate Objectives vs. Operations May Not Align 148

8.4.6 Supply and Demand: Concern in Committing to a Single Sourced New Technology 149

8.4.7 Transparency: How to Satisfy Customer and Regulatory Demands While Protecting Intellectual Property and Trade Secrets 149

8.4.8 Price/Performance: It’s More Than Price per Pound; Total Cost Savings Need to Be Communicated 151

8.5 Lessons Learned 152

References 152

9 Strategic Partnering 153
Jason Clark and Shawn Jones

9.1 Introduction 153

9.1.1 Partnerships as a Change Driver 153

9.1.2 Partnerships for Sustainable Chemical Technologies 154

9.1.3 Chapter Structure 155

9.2 Advantages and Disadvantages of Strategic Partnering 155

9.3 The Start-Up Perspective: Partnership Advantages and Disadvantages 155

9.3.1 Partnership Advantages for the Start-Up 155

9.3.2 Partnership Disadvantages for the Start-Up 158

9.4 The Industrial Partner Perspective: Partnership Advantages and Disadvantages 159

9.4.1 Partnership Advantages for the Industrial Partner 159

9.4.2 Partnership Disadvantages for the Industrial Partner 161

9.5 Mitigation of the Disadvantages and Risks 163

9.5.1 For the Start-Up 163

9.5.2 For the Industrial Partner 163

9.6 Evaluating a Potential Partnership 164

9.6.1 Start-Up Perspective 164

9.6.2 Industrial Perspective 165

9.7 Establishing the Partnership 166

9.8 Executing the Partnership 167

9.9 Closing the Partnership 168

9.10 Case Studies 169

References 171

10 Bridging the Gap 1: From Eureka Moment to Validation 175
Peiman Hosseini and Harish Bhaskaran

10.1 Introduction 175

10.2 Fundamental Research Leading to an Invention 176

10.3 Proving the Concept 178

10.4 The Tech Team: Moving Beyond an Academic Group 179

10.5 Developing the Road Map 180

10.6 Defining Your Technology Development Requirements 182

10.7 The Innovation Cycle: Design, Simulate, Fabricate, Test, Iterate 184

10.8 Accelerating the Process 186

10.8.1 An Example in Workflow Management 186

10.9 Growing and Evolving the Team 188

10.10 Summary 189

References 190

11 Bridging the Gap 2: From Validation to Pilot Scale-Up 191

11.1 Part 1: Setting the Groundwork 191
James Lockhart and Andrew Ellis

11.1.1 Introduction 191

11.1.2 Letting Go and Obtaining External Expertise 192

11.1.3 Safety Considerations 193

11.1.4 Commercial Considerations 195

11.1.5 Techno-Economic Assessment 197

11.1.6 Conclusion 203

11.2 Part 2: Building the Pilot Unit 205
James Lockhart and Andrew Ellis

11.2.1 Introduction 205

11.2.2 Piloting and Scale-Up Basics 205

11.2.3 Process and Equipment Considerations 210

11.2.4 Pilot Plant Operation and Location 215

11.2.5 Conclusion 218

12 Raising Investment/Financing 219
Matthew L. Cohen

12.1 Introduction 219

12.2 Main Investment Sources 220

12.2.1 Grants 220

12.2.2 Strategic Partnerships 220

12.2.3 Equity Investment 221

12.2.4 Debt 222

12.2.5 Bootstrapping (Using Your Own Money) 223

12.2.6 Summary 224

12.3 Unique Considerations for Investing in Sustainable Chemistry 224

12.3.1 Investment Drivers 225

12.3.2 Investment Impediments 227

12.3.3 Comparison to More Heavily Funded Areas 229

12.4 Financing Considerations 231

12.4.1 Trade-Offs Between Investment Types 232

12.5 Best Practices to Present Your Company to an Investor 235

12.5.1 Summary 236

12.6 Financing Case Study: Cnano Technology 237

Reference 238

13 Operationalizing a Start-Up Company 239
Andrew White

13.1 Introduction 239

13.2 Oversight Boards 240

13.2.1 Advisory Board 240

13.2.2 Board of Directors 241

13.2.3 Building an Advisory Board 242

13.2.4 Building a Board of Directors 242

13.2.5 Managing the Board 243

13.2.6 Compensating Boards 243

13.3 Systems 245

13.3.1 Human Resources Management 245

13.3.2 Health and Safety Systems 247

13.3.3 Financial Systems 248

13.3.4 Financial Projections 250

13.4 Conclusion 253

Part IV Success Stories 255

14 Making an Impact: Sustainable Success Stories 257

14.1 CarbonCure 257
Jennifer Wagner and Sean Monkman

14.1.1 The Vision 257

14.1.2 The Core of the Technologies 257

14.1.3 Determining the Value Proposition 258

14.1.4 The Commercialization Pathway 258

14.1.5 Financing 259

14.1.6 Development and Validation 260

14.1.7 Successes 261

14.1.8 Lessons Learned 262

References 262

14.2 Avantium 263
Gert-Jan M. Gruter and Thomas B. van Aken

14.2.1 Initial Technology and Business Model 263

14.2.2 Change in Direction 264

14.2.3 Exploring and Validating a New Opportunity 265

14.2.4 Huge Challenges and Huge Advances 266

14.2.5 Expanding Our Technology Portfolio 267

14.2.6 Additional Strategies and Lessons Learned 268

14.2.7 Summary 270

References 270

14.3 Hazel Technologies 271
Aidan R. Mouat

14.3.1 Blind Luck or Preparation? 271

14.3.2 Hazel Technologies: How It Started and Where We Are Today 272

14.3.3 Understanding What Our Business Really Is 273

14.3.4 Targeting Value Through the Supply Chain 274

14.3.5 Final Thoughts 276

Index 277

Erscheinungsdatum
Verlagsort New York
Sprache englisch
Maße 170 x 244 mm
Gewicht 737 g
Themenwelt Naturwissenschaften Chemie Technische Chemie
Technik
ISBN-10 1-119-60484-2 / 1119604842
ISBN-13 978-1-119-60484-6 / 9781119604846
Zustand Neuware
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