What are the other frequencies beside 22 GHz which have bright masers open to amateurs to observe, and what bandwidth is required to observe them?

There are several maser transitions accessible to amateur radio astronomers, although 22.235 GHz water (H₂O) is by far the most popular because the sources are strong and the equipment is relatively achievable.

The main amateur-accessible maser frequencies are:

Maser moleculeFrequencyWavelengthComments
Water (H₂O)22.23508 GHz1.35 cmThe strongest and most commonly observed amateur masers. Star-forming regions, evolved stars, W49, W3, Orion KL, etc.
Methanol (CH₃OH)6.66852 GHz4.5 cmVery strong Class II methanol masers. Excellent amateur target. Associated with high-mass star formation.
Methanol (CH₃OH)12.1786 GHz2.46 cmAnother strong Class II transition, but equipment becomes more challenging.
Hydroxyl (OH)1.612 GHz18.6 cmStrong OH masers, especially evolved stars (OH/IR stars). Easy frequency for SDRs.
Hydroxyl (OH)1.665/1.667 GHz18 cmThe famous OH main lines. Strong in star-forming regions and late-type stars.
Silicon monoxide (SiO)43.122 GHz7 mmVery strong in evolved stars (Mira variables), but much harder technically.
Silicon monoxide (SiO)86.243 GHz3.5 mmPossible with specialist equipment, beyond most amateurs.

Best targets for amateurs

1. 22 GHz Water

Probably the best first maser project:

  • W49
  • W3(OH)
  • Orion KL
  • Sgr B2
  • W51
  • Cepheus A
  • NGC 7538

A 1–2 m dish can detect the strongest sources with a good LNA and SDR.

2. 6.7 GHz Methanol

This is arguably the second-best amateur maser band.

Advantages:

  • Lower frequency than 22 GHz (easier feeds and lower losses)
  • Many very strong sources
  • Commercial LNAs and filters are available

Examples:

  • G9.62+0.19
  • W3(OH)
  • G35.20-0.74
  • Cepheus A

A small dish can work well because methanol masers can be very bright.

3. 1.6 GHz OH

This is attractive because:

  • Your existing hydrogen-line experience is relevant
  • SDRs cover this frequency easily
  • Coax losses are much lower
  • Filters and LNAs are inexpensive

Targets:

  • OH/IR stars such as:
    • OH 26.5+0.6
    • NML Cyg
    • VX Sgr

The challenge is that many OH masers are weaker than the famous water masers.


For your Lichfield Radio Observatory setup, I would rank them:

  1. 22.235 GHz H₂O – most exciting, but technically demanding
  2. 6.668 GHz CH₃OH – probably the easiest “next step” after hydrogen line
  3. 1.667 GHz OH – easiest hardware-wise and fits well with SDR techniques
  4. 43 GHz SiO – a future advanced project

A particularly interesting progression would be:

  • keep your 1.5–2 m dish for 22 GHz water
  • build a separate 6.7 GHz methanol feed/LNA chain
  • use the same SDR backend and spectroscopy software

The observing techniques are very similar to your hydrogen-line work: stable frequency reference, narrowband FFT spectroscopy, calibration, and Doppler correction.

The required bandwidth depends on whether you want to observe one known maser source or any bright maser anywhere in the Galaxy. The numbers below are for a general-purpose amateur survey receiver, allowing for Galactic velocities plus the Earth’s orbital Doppler shift.

The conversion is:

Frequency shift = observing frequency × velocity / speed of light

so the higher the frequency, the more MHz of bandwidth are needed for the same velocity range.

Approximate bandwidth required for Galactic maser surveys

MaserFrequency1 km/s equalsTypical Galactic velocity coveragePractical filter bandwidth
OH1.612 GHz5.4 kHz~400 km/s2-3 MHz
OH1.665/1.667 GHz5.6 kHz~400 km/s2-3 MHz
Methanol6.668 GHz22.2 kHz~400 km/s10-15 MHz
Methanol12.179 GHz40.6 kHz~400 km/s20-25 MHz
Water22.235 GHz74.2 kHz~400 km/s30-40 MHz
SiO43.122 GHz143.8 kHz~400 km/s60-70 MHz

The velocity range includes roughly:

-200 km/s to +200 km/s LSR
+
Earth orbital correction of +/-30 km/s

For individual famous sources

If you are targeting a known source, the requirements are much smaller.

Examples:

W49 water maser

velocity range: about -20 to +30 km/s
bandwidth needed:
~3.7 MHz
plus Doppler allowance
≈ 8-10 MHz

W3 IRS5 water maser

velocity range: -70 to -20 km/s

≈ 3.7 MHz
plus Doppler allowance
≈ 8 MHz

6.7 GHz methanol sources Most maser features are within a few tens of km/s, so:

5 MHz can be enough for a known source
10-15 MHz is comfortable

Practical recommendations for amateur equipment

If buying cavity filters:

  • 1.6 GHz OH: 5 MHz filter is ample
  • 6.7 GHz methanol: 10 MHz filter is a good choice
  • 12 GHz methanol: 20 MHz filter
  • 22 GHz water: 30-40 MHz if you want a MaserDB-style survey capability
  • 43 GHz SiO: usually no cavity filter; use a wideband front end and SDR filtering

For your planned 22 GHz water maser system, I would lean towards a 30 MHz filter rather than 20 MHz if you want to explore many MaserDB targets rather than just W49/W3/Orion. The SDR can then provide the fine spectral resolution (for example, kHz or sub-kHz channels).

By Admin

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