Biomass Model Tool Marche

Source Partner

ITABIA

Source of Information

EU Project

RuralBioUp

Biomass Residues from Agriculture and Forestry Sectors

Biomass Residues from Agro - Industrial Sector

Biomass Residues from Agriculture and Forestry Sectors

SNo	Biomass Category	Biomass	Theoretical availability (t/year)	Traditional uses	Main utilization as BBPs	Possible future innovative utilization	Available amount of Biomass for BBPs (t/year)	Notes
1	Agriculture and forestry	Durum wheat (straw)	219570.00	Cattle breeding	-	Advanced bioethanol; biopackaging; biomaterials	26348.4	-
2	Agriculture and forestry	Soft wheat (straw)	27919.50	Cattle breeding	-	Advanced bioethanol; biopackaging; biomaterials	3350.34	-
3	Agriculture and forestry	Barley (straw)	37872.00	Cattle breeding	-	Advanced bioethanol; biopackaging; biomaterials	7574.4	-
4	Agriculture and forestry	Oat (straw)	7230.60	Cattle breeding	-	Advanced bioethanol; biopackaging; biomaterials	1446.12	-
5	Agriculture and forestry	Rice (straw)	0.00	Cattle breeding	-	-	0	-
6	Agriculture and forestry	Corn (corn stalk)	49134.00	Silage	-	-	2948.04	-
7	Agriculture and forestry	Waxy Corn	0.00	Silage	-	-	0	-
8	Agriculture and forestry	Grass (ryegrass)	0.00	Cattle breeding	-	-	0	-
9	Agriculture and forestry	Sorghum	24216.00	Feed	-	-	1452.96	-
10	Agriculture and forestry	Other cereal (straw)	0.00	Cattle breeding	-	-	0	-
11	Agriculture and forestry	Rape (Brassica napus+ B.rapa subsp. Oleifera)	0.00	Burying in land/not used	-	-	0	-
12	Agriculture and forestry	Soy	1720.80	Burying in land/not used	-	-	206.5	-
13	Agriculture and forestry	sesame	0.00	Burying in land/not used	-	-	0	-
14	Agriculture and forestry	peanut	0.00	Burying in land/not used	-	-	0	-
15	Agriculture and forestry	sunflower	174616.00	Burying in land/not used	-	Advanced bioethanol; biopackaging; biomaterials	97784.96	-
16	Agriculture and forestry	Sugarbeet	0.00	-	-	-	0	-
17	Agriculture and forestry	Tobacco	0.00	-	-	-	0	-
18	Agriculture and forestry	Cotton	0.00	-	-	-	0	-
19	Agriculture and forestry	Linen	0.00	-	-	Cosmetic, textile,	0	-
20	Agriculture and forestry	Hemp	0.00	-	-	Cosmetic, Textile, Biomateterial, nustraceutical	0	-
21	Agriculture and forestry	Potato	939.40	Burying in land/not used	-	Biopackaging, Biomaterials	187.88	-
22	Agriculture and forestry	Pea	6794.20	Burying in land/not used	-	Biopackaging, Biomaterials; Cosmetic	1358.84	-
23	Agriculture and forestry	Chickpea	7484.20	Burying in land/not used	-	Biopackaging, Biomaterials; Cosmetic	1496.84	-
24	Agriculture and forestry	Lentil	2076.90	Burying in land/not used	-	Biopackaging, Biomaterials; Cosmetic	415.38	-
25	Agriculture and forestry	Bean	64.40	Burying in land/not used	-	Biopackaging, Biomaterials; Cosmetic	12.88	-
26	Agriculture and forestry	Broad bean	11902.50	Burying in land/not used	-	Biopackaging, Biomaterials; Cosmetic	2380.5	-
27	Agriculture and forestry	Olive (pruning)	21562.20	Burning out /energy	-	2nd gen. bioethanol; Biomaterials, Agri-pellet	12074.83	-
28	Agriculture and forestry	Vineyard	43870.40	Burning out /energy	-	2nd gen. bioethanol; Biomaterials, Agri-pellet	24567.42	-
29	Agriculture and forestry	Prickly pears	0.00	Burning out	-	Cosmetics/Nutraceutical	0	-
30	Agriculture and forestry	Medlar	0.00	Burning out	-	Cosmetics/Nutraceutical	0	-
31	Agriculture and forestry	Peach	2012.40	Burning out	-	Cosmetic, 2nd gen. bioethanol + Biomaterials	1126.94	-
32	Agriculture and forestry	Cherry Tree	160.00	Burning out	-	Cosmetic, 2nd gen. bioethanol + Biomaterials+Agripellet	89.6	-
33	Agriculture and forestry	Plum Tree	436.00	Burning out	-	Cosmetic, 2nd gen. bioethanol + Biomaterials+Agripellet	244.16	-
34	Agriculture and forestry	Apricot tree	342.00	Burning out	-	Cosmetic, 2nd gen. bioethanol + Biomaterials+Agripellet	191.52	-
35	Agriculture and forestry	Kiwi	124.00	Burning out	-	Cosmetic, 2nd gen. bioethanol + Biomaterials+Agripellet	69.44	-
36	Agriculture and forestry	Apple Tree	308.80	Burning out	-	Cosmetic, 2nd gen. bioethanol + Biomaterials+Agripellet	172.93	-
37	Agriculture and forestry	Pear Tree	87.00	Burning out	-	Cosmetic, 2nd gen. bioethanol + Biomaterials+Agripellet	48.72	-
38	Agriculture and forestry	Hazelnut	58.00	-	-	Cosmetic, 2nd gen. bioethanol + Biomaterials+Agripellet	41.76	-
39	Agriculture and forestry	Almond	16.50	-	-	Cosmetic, 2nd gen. bioethanol + Biomaterials+Agripellet	11.88	-
40	Agriculture and forestry	Grape Fruit	0.00	-	-	Cosmetic, 2nd gen. bioethanol + Biomaterials+Agripellet	0	-
41	Agriculture and forestry	Bergamot	0.00	-	-	Cosmetic, 2nd gen. bioethanol + Biomaterials+Agripellet	0	-
42	Agriculture and forestry	Cedar	0.00	-	-	Cosmetic, 2nd gen. bioethanol + Biomaterials+Agripellet	0	-
43	Agriculture and forestry	Chinotto	0.00	-	-	Cosmetic, 2nd gen. bioethanol + Biomaterials+Agripellet	0	-
44	Agriculture and forestry	Orange	0.00	-	-	Cosmetic, 2nd gen. bioethanol + Biomaterials+Agripellet	0	-
45	Agriculture and forestry	Tangerine	0.00	-	-	Cosmetic, 2nd gen. bioethanol + Biomaterials+Agripellet	0	-
46	Agriculture and forestry	Clementin	0.00	Burning out	-	Cosmetic, 2nd gen. bioethanol + Biomaterials+Agripellet	0	-
47	Agriculture and forestry	Lemon	0.00	-	-	Cosmetic, 2nd gen. bioethanol + Biomaterials+Agripellet	0	-
48	Agriculture and forestry	Fig	72.00	Disposal	-	Cosmetic, 2nd gen. bioethanol + Biomaterials+Agripellet	51.84	-
49	Agriculture and forestry	Pistachios	0.00		-	Cosmetic, 2nd gen. bioethanol + Biomaterials+Agripellet	0	-
50	Zootechnical	Waste wool	354.00		Insulation materials for green building	Insulation materials for green building	354	-

Biomass Residues from Agro - Industrial Sector

SNo	Biomass Category	Biomass	Theoretical availability (t/year)	Traditional uses	Main utilization as BBPs	Possible future innovative utilization	Available amount of Biomass for BBPs (t/year)	Notes
1	Agro-industry	Rice (husk, bran, broken rice)	0.00	feed	Feed	Biofertilizer from digestate; Biopackaging, biomaterials, cosmetic	0	-
2	Agro-industry	Legumes (vegetable residues)	1783.92	unused/biogas	-	Cosmetic, Biofertilizers from digestate; Biomaterials	535.17	-
3	Agro-industry	Tomato (skins, processing wastes)	52.36	unused/biogas	-	Cosmetic, Biofertilizers from digestate; Biomaterials	15.71	-
4	Agro-industry	Potato (skins, selection)	166.06	feed/biogas	Feed	Cosmetic, Biofertilizers from digestate; Biomaterials	49.82	-
5	Agro-industry	Olive oil (exhausted olive cake)	3949.10	Fertilization	Biofertilizer	Cosmetic, Biofertilizer from digestate	3554.19	-
6	Agro-industry	Wine dregs (skins, grape sones and stalks)	24112.98	Distillation for ethanol production, CHP, Biogas	Bioethanol/bioenergy	Nutraceutical, Cosmetic, 2nd gen. Bioethanol, Bifertilizer	7233.89	-
7	Agro-industry	Drupaceae	177.00	unused/biogas	-	Cosmetic, biomaterials, biofertlizer from digestate	159.3	-
8	Agro-industry	Kiwi	45931.00	unused/biogas	-	Cosmetic, biomaterials, biofertlizer from digestate	9	-
9	Agro-industry	Apple	33.80	unused/biogas	-	Cosmetic, nutraceutical, biomaterials (vegetable leather), biofertlizer from digestate	30.42	-
10	Agro-industry	Pear	7.46	unused/biogas	-	Cosmetic, biomaterials, biofertlizer from digestate	6.71	-
11	Agro-industry	Citrus fruits (pulp, peel)	0.00	unused/biogas	-	Nutraceutical, Cosmetics, fertilizer from digestate	0	-
12	Agro-industry	Fruit shells	1.66	unused/biogas	-	Agri-pellet, Biomaterials, 2nd gen. Bioethanol	1.5	-

Glossary

Bio-based carbon

Carbon derived from biomass

Biodegradability

Biodegradability refers to a process in which microorganisms convert the material into substances such as compost, carbon dioxide, methane or water through metabolic or enzymatic processes. The ultimate condition is the complete transformation of organic compounds into reduced simple molecules (such as carbon dioxide/methane, nitrate/ammonium, and water) and new biomass. Under aerobic conditions, carbon dioxide is the primary gas emitted while in the case of anaerobic conditions it is methane. The term “biodegradable” should always be associated with the type of medium (e.g. soil, water, in vitro medium), the conditions (e.g. temperature and humidity) and the duration of the biodegradation. For instance, among currently marketed bioplastics, PLA is always claimed as “biodegradable” while in reality, PLA is only industrially compostable (e.g. at 58°C and controlled conditions of humidity). Without this, PLA packaging, despite being made from renewable resources, is a plastic that will persist in our environment for a hundred years.

Biodegradable plastics

Biodegradable plastic means a plastic capable of undergoing physical, biological decomposition, such that it ultimately decomposes into carbon dioxide, biomass and water, without leaving behind any residue, and in accordance with European standards for packaging recoverable through composting and anaerobic digestion. Biodegradable plastics are designed to biodegrade in a specific medium (water, soil, compost) under certain conditions and in varying periods of time. (EEA, 2020) Therefore the label “biodegradable” must always have a clear sign of the environment in which the test was performed.

Bioeconomy

The bioeconomy covers all sectors and systems that rely on biological resources (animals, plants, micro-organisms and derived biomass, including organic waste), their functions and principles. It includes and interlinks: land and marine ecosystems and the services they provide; all primary production sectors that use and produce biological resources (agriculture, forestry, fisheries and aquaculture); and all economic and industrial sectors that use biological resources and processes to produce food, feed, bio-based products, energy and services. / * Biomedicines and health biotechnology are excluded

Biofertiliser

A substance which contains living micro-organisms which, when applied to seeds, plant surfaces, or soil, colonise the rhizosphere or the interior of the plant and promotes growth by increasing the supply or availability of primary nutrients to the host plant. Note to entry: Biofertilisers add nutrients through the natural processes of nitrogen fixation, solubilizing phosphorus, and stimulating plant growth through the synthesis of growth-promoting substances. The micro-organisms in biofertilisers restore the soil's natural nutrient cycle and build soil organic matter. Through the use of biofertilisers, healthy plants can be grown, while enhancing the sustainability and the health of the soil. Biofertilisers can be expected to reduce the use of synthetic fertilizers and pesticides, but they are not yet able to replace their use.

Biorefinery

Biorefining is the sustainable processing of biomass into a spectrum of bio-based products (food, feed, chemicals, materials) and bioenergy (biofuels, power and/or heat) (De Jong et al, 2020). This concept is analogous to today's petroleum refinery, which produces multiple fuels and products from petroleum.

Carbon capture and sequestration (CCS)

The process of capturing carbon dioxide before it enters the atmosphere, transporting it, and storing it for centuries or millennia.

Carbon capture and use (CCU)

The process of capturing carbon dioxide to be recycled for further usage. CCU is a broad term that covers all established and innovative industrial processes that aim at capturing carbon dioxide– either from industrial point sources or directly from the air – and at transforming the captured carbon dioxide into a variety of value-added products such as chemical building blocks, food/feed, synthetic fuels or materials.

Carbon capture, utilisation and storage (CCUS)

Technologies that involve the capture of carbon dioxide from fuel combustion or industrial processes, the transport of this carbon dioxide via ship or pipeline, and either its use as a resource to create valuable products or services or its permanent storage deep underground in geological formations. CCUS technologies also provide the foundation for carbon removal or "negative emissions" when the carbon dioxide comes from bio-based processes or directly from the atmosphere.

Carbon debt

The initial emission of biogenic-CO2 from forest bioenergy when it is higher than the emissions from a reference fossil system. It is called debt because the forest re-growth combined with the continuous substitution of fossil fuels may, in time, repay the “debt”.

Carbon footprint

The full quantity of greenhouse gases that can be attributed to an individual, a plant, a company, a product or a whole economy.

Carbon-neutral

Balancing the amount of carbon released – by burning fossil fuels or biomass, or the decomposition of plant biomass, for example – with an equivalent amount put into and stored in soils, plant and animal tissues, or other material such as the ocean floor.

Cascading

Cascading use is the efficient utilization of resources by using residues and recycled materials for material use to extend total biomass availability within a given system. In a single-stage cascade, the wood is processed into a product and this product is used once more for energy purposes. In a multistage cascade, the wood is processed into a product and this product is used at least once more in material form before disposal or recovery for energy purposes.

Composting

Treatment process that decomposes organic matter in an oxygenated environment. The result is nutrient-rich fertilizer or soil amendment.. Common types of composting include industrial composting (also known as ‘commercial composting’) and home composting.

Fertiliser

A chemical or natural substance added to soil or land to increase its fertility.

Life cycle assessment (LCA)

Life cycle assessment (previously also known as life cycle analysis) is defined as a systematic analysis of environmental impacts of a product or service throughout its entire life cycle. For this analysis, the material and energy inputs and outputs along all steps of the life cycle (this includes raw material extraction, production, distribution, use and disposal at end-of-life) are collected and then assessed in terms of potential environmental impacts of a product system. LCA is accepted as one of the main methods to identify environmental impacts and is standardised on the widely accepted standards ISO 14040 and ISO 14044. Life cycle inventory and life cycle impact assessment are consecutive parts of a life cycle assessment.Comparative life cycle assessment refers to a life cycle assessment. in which two or more products or systems are compared. Streamlined life cycle assessment refers to a simplified version of a life cycle assessment. that focuses on the most significant environmental impacts of a product or system.

Natural capital

The stock of renewable and non-renewable resources (e.g. plants, animals, air, water, soils, minerals) that combine to yield a flow of benefits to people.

Refinery

A refinery is a technical plant for the purification and refinement of raw materials (e.g. fractionation of crude oils via distillation which is based on the different boiling points of the respective fractions). Often, it refers to a petroleum oil refinery, which consists of a group of chemical engineering processing and refining units to convert crude oil into basic chemicals for further utilisation. This is usually done via cracking (steam cracking or catalytic cracking), a process in which large hydrocarbon molecules are broken down into smaller and more useful ones. A key product of a refinery is fossil-based petroleum naphtha, an intermediate liquid hydrocarbon stream, which serves as a raw material for the production of many other chemicals. Petroleum naphtha can be replaced with naphtha derived from renewable carbon alternatives (either bio-based, CO2 -based or chemical recycling). Different refineries also exist for other raw materials, e.g. sugar, salt, natural gas, edible oils, metals etc.

Value chains

A value chain describes the flow of value between different actors in a supply chain and may include a broader set of actors than in supply chains. Value can be reflected by a range of terms: • Economic – where value chains describe the flow of profit or income between actors in the supply chain. For example, the flow of income to different actors based on the input and output costs. • Environmental/climatic – where value chains describe the flow of benefits to given environmental or climate objectives. For example, the greenhouse gas emissions avoided as a result of a bioeconomy value chain. • Social – where value chains describe the flow of benefits to people and communities. For example, the jobs created in rural areas as a result of new value chains. These are distinct from supply chains, which describe the flow of goods and services between different actors, such as the production of wheat, its collection, processing, the manufacturing of pasta and eventual sale.

Waste streams

Waste streams are flows of specific waste, from its source through to recovery, recycling or disposal. Waste streams can be divided into two main categories: material-related streams (including metals; glass; paper and cardboard; plastics; wood; rubber; textiles; bio-waste) and product-related streams (including packaging; electronic waste; batteries and accumulators; end-of-life vehicles; mining, construction and demolition waste). Each waste stream has its specific characteristics and applicable legislation, including in terms of treatment method, hazardousness, practical recovery and recycling possibilities.

The glossary contains terms and definitions sourced from the BIOSWITCH Glossary of terms and definitions. Access the glossary provided by the Bioswitch EU project here.

Biomass Model Tool Marche

Summary / Description

Biomass Residues from Agriculture and Forestry Sectors

Biomass Residues from Agro - Industrial Sector

Biomass Residues from Agriculture and Forestry Sectors

Biomass Residues from Agro - Industrial Sector

Glossary