Anaerobic Digesters

Anaer­o­bic digesters com­post (or “digest”) organ­ic waste in a machine that lim­its access to oxy­gen (hence the “anaer­o­bic” part), encour­ag­ing the gen­er­a­tion of methane and car­bon diox­ide by microbes in the waste. This digester gas (which also comes con­t­a­m­i­nat­ed with hydro­gen sul­fide) is then burned as fuel to make elec­tric­i­ty. Digesters aren’t wide­ly used yet, but tend to be used for sewage sludge at sewage treat­ment plants and for ani­mal waste on farms. Digest­ing organ­ic waste does­n’t avoid the need to han­dle the digest­ed mate­r­i­al (a most­ly sol­id, but wet, byprod­uct known as “diges­tate”).

There are many prob­lems with ani­mal waste digesters, includ­ing air pol­lu­tion, methane leak­age, and leach­ing of nutri­ents from diges­tate. Digesters should not be sup­port­ed with renew­able ener­gy sub­si­dies, as they com­pete with solar and wind pow­er, and could sup­port inap­pro­pri­ate waste man­age­ment prac­tices, depend­ing on the feed­stock and use of the digestate.

With regard to methane leak­age, methane is a seri­ous glob­al warm­ing prob­lem, since methane is 86 times worse than CO2 for the cli­mate over a 20-year time frame. If just 2.8% of methane from a nat­ur­al gas sys­tem leaks out, it’s under­stood to be worse for the cli­mate than coal. Anaer­o­bic digesters are known to leak about 2–3% of the methane cre­at­ed by their process. (more below)

There are four main feed­stocks often con­sid­ered for anaer­o­bic diges­tion. Here’s is what they are and what we believe is the most appro­pri­ate role for them:

  • Ani­mal waste: For wet ani­mal wastes (cow and pig manure), diges­tion can be one of the bet­ter waste man­age­ment options (com­pared to lagoons). For poul­try lit­ter, it makes no sense, because water needs to be added to make it wet enough (some­times, they pro­pose sewage efflu­ent). These are often on larg­er (fac­to­ry) farms (a.k.a. Con­fined Ani­mal Feed­ing Oper­a­tions, or CAFOs) since they’re expen­sive and require “renew­able” ener­gy sub­si­dies (like being in a state Renew­able Port­fo­lio Stan­dard). Large digesters are used to make fac­to­ry farms more viable. Con­se­quent­ly, advo­cates of small fam­i­ly farms and of sus­tain­able agri­cul­ture see digesters as a Tro­jan horse that pre­tends to solve a waste man­age­ment prob­lem while enabling fac­to­ry farms to invade the com­mu­ni­ty. Nonethe­less, if the digest­ed waste is not con­t­a­m­i­nat­ed with tox­ins (such as arsenic if it’s used in poul­try feed), then the diges­tate might be accept­able for use as fer­til­iz­er or soil amend­ment. Read the Food and Water Watch fact­sheet for a strong cri­tique of manure digesters: Hard to Digest: Green­wash­ing Manure into Renew­able Energy
  • Sewage sludge: Many sewage treat­ment plants digest their sewage sludge, then rename it “biosolids” and call it “Class A” if it pass­es a pathogen test, as if that makes it safe for use in gar­dens, soil amend­ment, etc. Pathogens can regrow in this heat-treat­ed sludge, and the tox­ic met­als and oth­er chem­i­cals don’t van­ish in the diges­tion process. This digest­ed sludge does not belong being exempt­ed from waste reg­u­la­tion and ought to be placed in monofills (ded­i­cat­ed cells at land­fills), not “ben­e­fi­cial­ly used” in agri­cul­ture (or in land­scap­ing, fill­ing strip mines, bagged and sold as fer­til­iz­er, etc.).
  • Source sep­a­rat­ed organ­ics (SSO) [food scraps and yard waste]: These mate­ri­als ought to be aer­o­bi­cal­ly com­post­ed, but anaer­o­bic diges­tion could make sense in urban areas where land for aer­o­bic com­post­ing is not avail­able. Digest­ed SSO could be appro­pri­ate for com­post uses, but needs to be aer­o­bi­cal­ly com­post­ed after diges­tion to con­di­tion it. Food scraps and yard waste should nev­er be mixed with sewage sludge (“biosolids”), since they’re much clean­er and should­n’t be blend­ed with more tox­ic sludges. Doing so also makes it inel­i­gi­ble as com­post under organ­ic cer­ti­fi­ca­tion stan­dards, which bars sewage sludge as fertilizer.
  • Munic­i­pal sol­id waste (MSW), or the “organ­ic frac­tion” of MSW left over after efforts to remove recy­clables: The most respon­si­ble way to man­age MSW is with a zero waste hier­ar­chy that leaves lit­tle waste in the “black bin,” research­es what is in that waste stream, then mechan­i­cal­ly pulls out addi­tion­al recy­clables before digest­ing and aer­o­bi­cal­ly com­post­ing the remain­ing resid­ual frac­tion pri­or to land­fill­ing. This ensures that we won’t have gassy, stinky land­fills. How­ev­er, plans for any mechan­i­cal sep­a­ra­tion and/or bio­log­i­cal sta­bi­liza­tion (com­post­ing or diges­tion) process­es usu­al­ly result in the diges­tate being burned or mar­ket­ed as fuel pel­lets or as fer­til­iz­er. Some com­mu­ni­ties have made the mis­take of try­ing to end source sep­a­ra­tion and have all trash, recy­clables, and com­postable thrown into the same bin, with the idea that machines and work­ers at con­vey­or belts will sort it all out. This idea is a ter­ri­ble fail­ure. Source sep­a­ra­tion is vital, and diges­tion of MSW should only be a pro­cess­ing step to sta­bi­lize waste before land­fill­ing. For more info, read the reports under the “Get­ting the back end of the zero waste hier­ar­chy right” sec­tion of our zero waste page and explore the detailed zero waste hier­ar­chy we developed.

Digesters are only mar­gin­al­ly effec­tive at reduc­ing prob­lems with odors, pathogens and green­house gas emis­sions from ani­mal waste or sewage sludge, but they are inca­pable of mak­ing any chem­i­cal con­t­a­m­i­nants in the wastes go away. Digesters aren’t emis­sions-free. They are known to emit nitro­gen and sul­fur oxides, par­tic­u­late mat­ter, car­bon monox­ide and ammonia.

Liv­ing next to a digester could be unpleas­ant, par­tic­u­lar­ly if locat­ed in a res­i­den­tial neigh­bor­hood or if the facil­i­ty would be large — attract­ing manure-haul­ing trucks from around the region. Some pro­pos­als for digesters have been fought off by com­mu­ni­ty opposition. 

Esti­mat­ed air emis­sions data on digesters can be found here on page 3–12:
Lusk, P. (1998). Methane Recov­ery from Ani­mal Manures: A Cur­rent Oppor­tu­ni­ties Case­book. (3rd Edi­tion. NREL/SR-25145. Gold­en, CO: Nation­al Renew­able Ener­gy Lab­o­ra­to­ry. Work per­formed by Resource Devel­op­ment Asso­ciates, Wash­ing­ton, DC.

Critiques of Anaerobic Digesters:


GRACE Fac­to­ry Farm Pro­jec­t’s posi­tion on methane digesters (2003)

The GRACE view­point on methane digesters. The US gov­ern­ment has start­ed to hand out sub­si­dies to farm­ers to install methane digesters–which extract methane from ani­mal manure to cre­ate energy–as a way to deal with prob­lems asso­ci­at­ed with fac­to­ry farm waste. Digesters have great­ly vary­ing effi­cien­cies, some­times using all of the methane pro­duced to sus­tain the pro­duc­tion of more methane. The process is pro­hib­i­tive­ly expen­sive unless sub­si­dized by tax­pay­er mon­ey and requires a con­stant sup­ply of manure, but does not dimin­ish the amount of manure present after methane has been extract­ed. Thus, methane digesters should not be viewed as a sus­tain­able solu­tion for fac­to­ry farm waste, but rather a mech­a­nism for per­pet­u­at­ing the pro­duc­tion of excess manure…

The US Depart­ment of Agri­cul­ture (USDA) esti­mates ani­mals in the US meat indus­try pro­duced 1.4 bil­lion tons of waste in 1997 — 130 times the nation’s vol­ume of human waste and five tons of ani­mal waste for every US cit­i­zen. The use of manure for fer­til­iz­er occurs nat­u­ral­ly on tra­di­tion­al live­stock farms and, assum­ing the manure is applied at the appro­pri­ate agro­nom­ic rates, this is good man­age­ment. Pro­duc­tion of more manure than the land on which the ani­mals are housed can absorb is unsus­tain­able, unless a large amount of addi­tion­al land can be found for manure spreading.

The num­ber of ani­mals on fac­to­ry farms often exceeds the abil­i­ty of the fac­to­ry farm oper­a­tor to find enough crop­land to respon­si­bly spread the manure. This invari­ably leads to attempts to increase the quan­ti­ty of manure spread on each plot of land by cal­cu­lat­ing the nutri­ent require­ments using only the most gen­er­ous assump­tions — or by spread­ing manure in excess of the legal require­ments. When these prac­tices are com­bined with the fact that vir­tu­al­ly all manure spread­ing is cal­cu­lat­ed on nitro­gen con­tent only, even though many manures are enriched in phos­pho­rus, the result is pol­lu­tion of ground water from over appli­ca­tion, run-off of nutri­ents into streams and lakes, and eutroph­i­ca­tion of water ways.

Today’s con­fined ani­mal feed­ing oper­a­tions (CAFOs) use var­i­ous meth­ods of waste dis­pos­al and stor­age: giant cesspools, known as lagoons; waste dis­per­sion through injec­tion of liq­uid manure into the soil; spray­ing the liq­ue­fied manure over the sur­round­ing fields; or dis­pos­al of sol­id waste in land­fills after liq­uid waste has evap­o­rat­ed from the lagoon. These prac­tices cre­ate odor nui­sances and health haz­ards for the neigh­bors of the CAFO. Pol­lu­tion from ani­mal waste can cause res­pi­ra­to­ry prob­lems, skin infec­tions, nau­sea, depres­sion and oth­er seri­ous ill­ness­es for peo­ple who live near fac­to­ry farms.

Giv­en these poten­tial prob­lems and the com­mu­ni­ty resis­tance to CAFOs they have spawned, mit­i­gat­ing the envi­ron­men­tal impacts of this mas­sive amount of manure has become a major con­cern for CAFOs, agribusi­ness and the USDA. Sev­er­al com­pa­nies claim to have invent­ed sys­tems that con­sume parts of the manure and cre­ate valu­able byprod­ucts such as methane gas and fer­til­iz­er. One of the more pop­u­lar ideas is a very old con­cept: the methane digester. The methane giv­en off dur­ing the decom­po­si­tion of the manure is cap­tured and burned, pro­vid­ing either heat or pow­er for elec­tri­cal gen­er­a­tion. Pro­po­nents of digesters claim they remove offen­sive odors from manure, while pro­duc­ing low-cost energy.

While the act of cov­er­ing the manure used by the digester to cap­ture the methane will reduce odors, it has no effect on the odors from manure kept in addi­tion­al lagoons or on the major source of CAFO odors—the exhaust fans from the CAFO barns (these fans account for about 60% of all odors ema­nat­ing from a CAFO). Fur­ther, because methane burns at such a low tem­per­a­ture, the digester con­tin­u­al­ly emits ammo­nia in excess of air pol­lu­tion stan­dards unless a sep­a­rate ammo­nia strip­per is employed.

Costs such as those asso­ci­at­ed with ammo­nia strip­ping when cou­pled with the short life-span of digesters (usu­al­ly 10 years or less) are two of the rea­sons that even though methane digester tech­nol­o­gy has been avail­able for many years, it has nev­er been shown to be an eco­nom­i­cal way to gen­er­ate pow­er. Stud­ies show that the instal­la­tion and oper­at­ing costs invari­ably exceed the sav­ings the digester pro­duces by replac­ing oth­er ener­gy sources. The cost/savings dif­fer­en­tial is bet­ter for large oper­a­tions, but it can nev­er over­come the require­ment that methane pow­er must be a sec­ondary pow­er sys­tem. Build­ing reg­u­la­tions usu­al­ly require that farm-oper­at­ed sys­tems like methane digesters have a back-up sys­tem which is nor­mal­ly the stan­dard elec­tri­cal grid con­nec­tion that the farm would use if it was not gen­er­at­ing methane. Fur­ther, because the gasses giv­en off by manure in the barns are so lethal, no large CAFO can allow barn ven­ti­la­tion sys­tems to fail for even lim­it­ed peri­ods. As a result, the instal­la­tion costs for both the elec­tri­cal sys­tem and the digester must be absorbed by the own­er. For these rea­sons, no methane digester in the Unit­ed States has been an accept­able invest­ment unless it was par­tial­ly sup­port­ed by a gov­ern­ment subsidy.

Even when sup­port­ed by sub­si­dies, digesters have a high ini­tial cost and a long pay­back peri­od. They also require the waste of at least 150–200 ani­mals to main­tain effi­cient oper­a­tion. Digester oper­a­tion is labor inten­sive and expen­sive, and in the end analy­sis, farm­ers have lit­tle eco­nom­ic need to pro­duce their own ener­gy. Ener­gy expen­di­tures amount to only about 3–5% of total oper­a­tional costs on many farms. Accord­ing to Cal­i­for­nia Poly­tech­nic Uni­ver­si­ty, sub­si­dies are not the make-or-break fac­tor in the use of bio­mass as long as the envi­ron­men­tal advan­tages can be shown to be greater than the ben­e­fit of ener­gy pro­duc­tion. But are the envi­ron­men­tal ben­e­fits of digesters real?

Digesters have great­ly vary­ing effi­cien­cies. They are unre­li­able and inef­fi­cient when oper­at­ed at ambi­ent tem­per­a­tures. Heat­ing the manure improves the gen­er­a­tion of methane, but even small amounts of manure heat­ing will con­sume approx­i­mate­ly 35% of the bio­gas pro­duced by the digester tem­per­a­ture . Heat­ing the manure enough to speed decom­po­si­tion sig­nif­i­cant­ly takes far more ener­gy. For exam­ple, Big Sky Farms pro­posed an oper­a­tion using 6 digesters in Ida­ho, each accom­mo­dat­ing a 330,000-pound oper­at­ing load of manure. In order to get the digesters to con­sume this amount of manure (from a 50,000 sow far­row-to-fin­ish oper­a­tion) as rapid­ly as it was pro­duced, all the heat from the methane gen­er­at­ed by the digesters was need­ed to heat the manure for diges­tion — in oth­er words, all the digester methane was used to cre­ate more digester methane. These digesters still required a huge sup­ply of manure to be retained in the sur­round­ing lagoons, and it did not reduce fos­sil fuel use at the CAFO.

Because of their exces­sive ammo­nia emis­sions, digesters are not like­ly to solve any green­house gas prob­lems. A recent Nation­al Acad­e­my of Sci­ences report on air qual­i­ty sur­round­ing fac­to­ry farms shows that ammo­nia released into the atmos­phere, and the “nitro­gen cas­cade” that fol­lows this release, is the major con­cern for green house gasses. Air pol­lu­tants with a nitro­gen base (NOx) released by a digester are sim­i­lar to those from an inter­nal com­bus­tion engine. Fur­ther, since the burn­ing tem­per­a­tures of methane are so low, the ammo­nia in the gasses com­ing from the manure will not be oxi­dized and will be released from the digester stacks direct­ly into the atmos­phere. In the case of Big Sky, ammo­nia emis­sions from the digesters vast­ly exceed­ed those allowed at indus­tri­al sites in Ida­ho. Even if the ammo­nia was oxi­dized this would sim­ply add oth­er Nitrogen/oxygen com­pounds to the waste gasses that have worse green­house effects than the ammonia.

Pro­po­nents of methane digesters orig­i­nal­ly tout­ed these sys­tems as an alter­na­tive source of ener­gy. When it became obvi­ous this was not the case, many pro­po­nents began to claim that the ben­e­fit of diges­tion was actu­al­ly the reduc­tion of odor from CAFO manure. How­ev­er, while digesters mit­i­gate some of the odor from manure, they do not make CAFOs good neigh­bors. In order to use a digester manure must be stored in anaer­o­bic lagoons, which emit foul odors unless cov­ered. Fur­ther, a study report­ed by the Nation­al Pork Board found that lagoon cov­ers only reduce odor by about 45 per­cent. And final­ly, CAFO barns pro­duce the major­i­ty of the odors at the site and this is unchanged when digesters are used.

After the methane has been pro­duced there is still the issue of the waste that remains behind. The quan­ti­ty of manure is not reduced by diges­tion. It still must be put some­where, and all the chem­i­cals and heavy met­als that were in the manure pri­or to diges­tion remain after the digester has oper­at­ed must be dis­posed of. As the Nation­al Acad­e­my of Sci­ences report empha­sizes, the only reli­able way to lim­it emis­sions to the atmos­phere is to incor­po­rate the manure into the land as rapid­ly as pos­si­ble and to keep it cov­ered and con­tained until that time. This is only pos­si­ble if suf­fi­cient spread­able acreage is locat­ed adja­cent to the CAFO. Obvi­ous­ly, to real­ly solve the prob­lems of odor and waste there is only one answer—never keep more ani­mals than the avail­able land will accommodate.

Anaer­o­bic digesters do almost noth­ing to make a very seri­ous prob­lem less seri­ous. Anaer­o­bic digesters oper­ate at tem­per­a­tures too low to destroy pathogens. The con­cen­tra­tion of oxy­gen-demand­ing car­bon com­pounds exceeds con­cen­tra­tions in untreat­ed munic­i­pal waters. Diges­tion con­verts organ­ic forms of nitro­gen to ammo­nia nitro­gen, but it does not reduce phos­pho­rus. And final­ly, the lagoons them­selves con­tin­ue to pose dan­gers to sur­round­ing residents–leaking, emit­ting dan­ger­ous gas­es, and threat­en­ing to overflow.

Less Manure is the Solution

Manure accu­mu­la­tion is not the prob­lem, it is a symp­tom of the real prob­lem: CAFOs con­cen­trate so much manure in such a small area that it can­not be real­is­ti­cal­ly used for fer­til­iz­er. The GRACE Fac­to­ry Farm Project does not endorse any manure treat­ment, recy­cling, or uti­liza­tion tech­nol­o­gy. In our view, the solu­tion is to allow uncon­fined ani­mals to spread their own manure and to employ sus­tain­able farm­ing prac­tices, not to rely on the appli­ca­tion of end­less and increas­ing­ly expen­sive tech­no­log­i­cal fixes.

Fur­ther reading 

Test and Qual­i­ty Assur­ance Plan: Swine Waste Elec­tric Pow­er and Heat Pro­duc­tion Sys­tems: Cap­stone Micro­Tur­bine and Mar­tin Machin­ery Inter­nal Com­bus­tion Engine (Pre­pared by Green­house Gas Tech­nol­o­gy Cen­ter, in coop­er­a­tion with EPA. Novem­ber 2002. 166pp.)


Methane Leakage from Anaerobic Digesters

Excerpt­ed from Life­cy­cle Green­house Gas Analy­sis of an Anaer­o­bic Codi­ges­tion Facil­i­ty Pro­cess­ing Dairy Manure and Indus­tri­al Food Waste, Envi­ron­men­tal Sci­ence & Tech­nol­o­gy, 2015, 49 (18), pp 11199–11208. DOI: 10.1021/acs.est.5b01331

Digester Oper­a­tion. Digester emis­sions con­sist of direct emis­sions due to leaks or incom­plete com­bus­tion as well as indi­rect emis­sions off­set by elec­tric­i­ty gen­er­at­ed. Cana­di­an and Ger­man stud­ies report­ed fugi­tive emis­sions rang­ing from 2.1% to 3.1% of CH4 utilized.[45,46] The nom­i­nal val­ue of 3% of gas uti­lized was used. How­ev­er, Liebe­trau et al.[46] not­ed that when leaks and mal­func­tions were elim­i­nat­ed, near zero fugi­tive emis­sions were mea­sured. Con­verse­ly, releas­es of bio­gas were observed through emer­gency vents due to over­pres­sure con­di­tions in the reac­tor or when flar­ing was not pos­si­ble. There­fore, a sen­si­tiv­i­ty analy­sis was per­formed using the IPCC default uncer­tain­ty range of 0–10%.[18] This range also allows for con­sid­er­a­tion of emis­sions due to flar­ing of bio­gas, which were min­i­mal dur­ing the peri­od of study due to issues relat­ed to flare oper­a­tion but were report­ed to be on aver­age 21% of gas pro­duced in a study of sev­en NYS AD plants.[47] Site sup­plied mea­sure­ments of gen-set exhaust report­ed 1314 ppmv dry CH4, which equat­ed to 2.5% of the CH4 uti­lized. This was con­sis­tent with report­ed val­ues for incom­plete com­bus­tion, which ranged from 0.4% to 3.28%.[45, 46] N2O exhaust emis­sions were a small­er con­tri­bu­tion at 0.03gN2O/m3CH4 uti­lized, which is also con­sis­tent with the range report­ed in the lit­er­a­ture (0.02–1.75g N2O/m3 CH4 utilized).[46, 48]

Ref­er­ences:

[18] Envi­ron­men­tal Pro­tec­tion Agency (EPA). Inven­to­ry of U.S. green­house gas emis­sions and sinks: 1990−2012. In Annex 3: Method­olog­i­cal descrip­tions for addi­tion­al source or sink cat­e­gories; https://www3.epa.gov/climatechange/Downloads/ghgemissions/US-GHG-Inventory-2014-Annex-3-Additional-Source-or-Sink-Categories.pdf.

[45] Flesch, T.; Des­jardins, R.; Worth, D. Fugi­tive methane emis­sions from an agri­cul­tur­al biodi­gester. Bio­mass Bioen­er­gy 2011, 35, 3927–3935. http://www.sciencedirect.com/science/article/pii/S0961953411003333

[46] Liebe­trau, J.; Reinelt, T.; Clemens, J.; Hafer­mann, C.; Friehe, J.; Wei­land, P. Analy­sis of green­house gas emis­sions from 10 bio­gas plants with­in the agri­cul­tur­al sec­tor. Water Sci. Tech­nol. 2013, 67 (6), 1370–1379. https://www.ncbi.nlm.nih.gov/pubmed/23508164

[47] Gooch, C. A.; Pron­to, J.; Labatut, R. New York State Ener­gy Research and Devel­op­ment Author­i­ty (NYSERDA), Bio­gas Dis­trib­uted Gen­er­a­tion Sys­tems Eval­u­a­tion and Tech­nol­o­gy Trans­fer, NYSERDA Project No. 6597; Eval­u­a­tion of sev­en on-farm anaer­o­bic diges­tion sys­tems based on the ASERTTI mon­i­tor­ing pro­to­col: Con­sol­i­dat­ed report and find­ings, PRO-DAIRY Pro­gram; Depart­ment of Bio­log­i­cal and Envi­ron­men­tal Engi­neer­ing, Cor­nell Uni­ver­si­ty: Itha­ca, NY, 2011; http://nmsp.cals.cornell.edu/publications/extension/Ndoc2003.pdf.

[48] Nielsen, O. K.; Lyck, E.; Mikkelsen, M. H.; Hoff­mann, L.; Gyldenkærne, S.; Winther, M.; Nielsen, M.; Fauser, P.; Thom­sen, M.; Ple­j­drup, M. S.; Illerup, J. B.; Sørensen, P. B.; Ves­terdal, L. Denmark’s nation­al inven­to­ry report 2008 − Emis­sion inven­to­ries 1990−2006; Sub­mit­ted under the Unit­ed Nations Frame­work Con­ven­tion on Cli­mate Change; NERI Tech­ni­cal Report no. 667; Nation­al Envi­ron­men­tal Research Insti­tute, Uni­ver­si­ty of Aarhus: Den­mark, 2008; http://www.dmu.dk/Pub/FR667.pdf.


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